tm0012-QCB/QCoderBenchmark · Datasets at Hugging Face

problem stringclasses 67 values	user stringlengths 13 13	submission_order int64 1 57	result stringclasses 10 values	execution_time stringlengths 0 8	memory stringclasses 88 values	code stringlengths 47 7.62k
QPC003_A3	AFADD5DA171D1	2	WA	1459 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: # 量子ビット0を\|1⟩にするためにXゲートを適用 qc.x(0) # 量子ビット0にアダマールゲートを適用 qc.h(0) # 量子ビット1にHゲートを適用 qc.h(1) # 量子ビット2にHゲートを適用 qc.h(2) # 各状態の位相を調整 pi = 3.14159 qc.rz(pi / 3, 0) # \|100⟩ qc.rz(pi / 3, 1) # \|010⟩ qc.rz(pi / 3, 2) # \|001⟩ return qc '''
QPC003_A3	AFDE7D6BFE13A	1	WA	1535 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.h(0) qc.cx(0,1) qc.cx(0,2) return qc '''
QPC003_A3	AFDE7D6BFE13A	2	RE	1436 ms	153 MiB	'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) qc.cx(0,1) qc.cx(0,2) return qc '''
QPC003_A3	AFDE7D6BFE13A	3	RE	1396 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0) qc.cx(0,1) qc.cx(0,2) return qc '''
QPC003_A3	AFDE7D6BFE13A	4	RE	1403 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.ry(2 * math.atan(pow(2,0.5), 1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''
QPC003_A3	AFDE7D6BFE13A	5	RE	1513 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(pow(2,0.5), 0,1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''
QPC003_A3	AFDE7D6BFE13A	6	RE	1484 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(math.sqrt(2), 0,1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''
QPC003_A3	AFDE7D6BFE13A	7	AC	1581 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(math.sqrt(2)), 0,1) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''
QPC003_A3	AFF1911F70140	1	WA	1507 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.h(0) qc.h(1) qc.h(2) qc.x(0) return qc '''
QPC003_A3	AFFAE60BB63F2	1	RE	1510 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.cx(0,1) qc.ry(theta,1) qc.cx(1,2) return qc '''
QPC003_A3	AFFAE60BB63F2	2	RE	1154 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.ch(0,1) qc.cx(1,0) qc.ry(theta,1) qc.ch(1,2) qc.cx(2,1) return qc '''
QPC003_A3	AFFAE60BB63F2	3	RE	1168 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.cx(0, 1) qc.cx(0, 2) return qc '''
QPC003_A4	A003A4C8324EB	1	AC	1929 ms	156 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) theta = math.asin(1.0 / math.sqrt(n)) qc.ry(2.0 * theta, 0) qc.x(0) qc.cx(0, 1) qc.x(0) for i in range(1, n - 1): theta = math.asin(1.0 / math.sqrt(n-i)) qc.cry(2.0*theta, i, i+1) qc.cx(i, i+1) qc.cx(i+1, i) return qc '''
QPC003_A4	A03D81149875C	1	RE	1209 ms	153 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(n-i)) qc.cry(theta,i-1,i) qc.cx(i,i-1) return qc '''
QPC003_A4	A03D81149875C	2	RE			'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(math.sqrt(n-i))) qc.cry(theta,i-1,i) qc.cx(i,i-) return qc '''
QPC003_A4	A03D81149875C	3	RE	1338 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(math.sqrt(n-i))) qc.cry(theta,i-1,i) qc.cx(i,i-1) return qc '''
QPC003_A4	A03D81149875C	4	RE	1638 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)] qc.x(0) for i in range(n-1): qc.cry(theta[i],i,i+1) qc.cx(i+1,i) return qc '''
QPC003_A4	A03D81149875C	5	AC	1852 ms	157 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)] qc.x(0) for i in range(n-1): qc.cry(theta[i],i,i+1) qc.cx(i+1,i) return qc '''
QPC003_A4	A03DE0435906C	1	WA	2022 ms	160 MiB	'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(acos(1-2/n), 0) qc.x(0) for i in range(1, n-1): qc.cry(acos(1 - 2 / (n-i)), i-1, i) qc.x(i) for i in range(n-1): qc.x(i) return qc '''
QPC003_A4	A03DE0435906C	2	WA	1921 ms	161 MiB	'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(acos(1-2/n), 0) qc.x(0) for i in range(1, n): qc.cry(acos(1 - 2 / (n-i)), i-1, i) qc.x(i) for i in range(n): qc.x(i) return qc '''
QPC003_A4	A0460F58C5610	1	WA	1456 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(range(n)) return qc '''
QPC003_A4	A0460F58C5610	2	WA	1671 ms	156 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Define angles for controlled-Ry gates theta = [2 * math.atan(math.sqrt(i)) for i in range(1, n)] # Generate angles for controlled-Ry gates # Start with the initial state by flipping the first qubit to \|1⟩ qc.x(0) # Apply controlled-Ry rotations and CNOT gates for i in range(n - 1): qc.cry(theta[i], i, i + 1) # Apply controlled-Ry on qubits i and i+1 qc.cx(i + 1, i) # Apply CNOT between qubits i+1 (control) and i (target) return qc '''
QPC003_A4	A0460F58C5610	3	AC	2006 ms	157 MiB	'''python import math from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)] qc.x(0) for i in range(n - 1): qc.cry(theta[i], i, i + 1) qc.cx(i + 1, i) return qc '''
QPC003_A4	A069404B4EC84	1	RE	2123 ms	156 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n-1): qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1) qc.cx(i+1, i) return qc '''
QPC003_A4	A069404B4EC84	2	AC	2551 ms	161 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n-1): qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1) qc.cx(i+1, i) return qc '''
QPC003_A4	A099B65030BFB	1	AC	1906 ms	158 MiB	'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = acos((2 - n)/n) qc.u(theta, 0 , 0, 0) for m in range(0, n - 2): theta = acos((3 + m - n)/(n - m - 1)) qc.cu(theta, 0, 0, 0, m, m+1) for m in range(n - 1): qc.mcx(list(range(n - m - 1)), n - m - 1) qc.x(0) return qc '''
QPC003_A4	A09FA2083D8C4	1	RE	1588 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2acos(1/sqrt(n-i)),0); for i in range(1,n-1): qc.cry(2acos(1/sqrt(n-i)),i-1,i) for i in range(n-1,0,-1): qc.cx(i-1,i) qc.x(0) return qc '''
QPC003_A4	A09FA2083D8C4	2	AC	1838 ms	158 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2math.acos(1/math.sqrt(n)),0) for i in range(1,n-1): qc.cry(2math.acos(1/math.sqrt(n-i)),i-1,i) for i in range(n-1,0,-1): qc.cx(i-1,i) qc.x(0) return qc '''
QPC003_A4	A109C204DF7C1	1	AC	1662 ms	158 MiB	'''python from qiskit import QuantumCircuit from math import pi, acos, sqrt def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) for i in range(n): if i: qc.cry(acos(sqrt(1/(n-i))) * 2, i-1, i) else: qc.ry(acos(sqrt(1/(n-i))) * 2, i) for i in range(n-1, 0, -1): qc.cx(i-1, i) qc.x(0) return qc '''
QPC003_A4	A10CA3439EADE	1	WA	1349 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(0) return qc '''
QPC003_A4	A10CA3439EADE	2	WA	1316 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) return qc '''
QPC003_A4	A10CA3439EADE	3	RE	1436 ms	153 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) for i in range(n): qc.ry(2 * amplitude, i) return qc '''
QPC003_A4	A10CA3439EADE	4	WA	1742 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) for i in range(n): qc.ry(2 * amplitude, i) return qc '''
QPC003_A4	A10CA3439EADE	5	UGE	1433 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) state = [0] * (2n) for i in range(n): state[2i] = amplitude qc.initialize(state) return qc '''
QPC003_A4	A10CA3439EADE	6	RE	1191 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) for i in range(1,n): qc.append(CXGate(),[0,i]) return qc '''
QPC003_A4	A10CA3439EADE	7	RE	1457 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) for i in range(1,n): qc.append(CXGate(), [0, i]) return qc '''
QPC003_A4	A10CA3439EADE	8	RE			'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) # H on the first qubit for i in range(1, n): qc.append(CXGate(), [0, i]) return qc '''
QPC003_A4	A10CA3439EADE	9	WA	1343 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here for i in range(n): qc.h(i) qc.measure_all() return qc '''
QPC003_A4	A10CA3439EADE	10	WA	1368 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here qc.h(0) for i in range(1,n): qc.cx(0,i) qc.measure_all() return qc '''
QPC003_A4	A10CA3439EADE	11	WA	1272 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here qc.h(0) for i in range(1,n): qc.cx(0,i) return qc '''
QPC003_A4	A1AF2CAFE30A4	1	AC	3000 ms	162 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: prob_amp = np.sqrt(1 / n) rot_ang = 2 * np.arccos(prob_amp) qc.x(0) for i in range(n - 1): comp_amp = np.sqrt(1 - i / n) rot_ang = 2 * np.arccos(prob_amp / (comp_amp)) qc.cry(rot_ang, i, i + 1) qc.cx(i + 1, i) return qc '''
QPC003_A4	A1C5F56E70050	1	RE	1284 ms	154 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	2	RE	1178 ms	153 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	3	RE	1179 ms	154 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): angle[i+1]=np.arccos(1/np.sqrt(i+1)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	4	RE	1402 ms	153 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): angle[i+1]=np.arccos(1/np.sqrt(i+1)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	5	RE	1223 ms	153 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	6	RE	1503 ms	153 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	7	RE	1703 ms	154 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	8	RE	1620 ms	154 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	9	WA	1841 ms	157 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	10	RE	1243 ms	153 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	11	WA	1793 ms	158 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	12	WA	1681 ms	158 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-i+1+j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	13	WA	1311 ms	158 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-i+1+j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	14	WA	2002 ms	158 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''
QPC003_A4	A1C5F56E70050	15	AC	1724 ms	157 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) if n==2: qc.h(0) qc.x(0) qc.cx(0,1) qc.x(0) return qc else: qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''
QPC003_A4	A1CADEC397BB8	1	WA	1318 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range (1, n): qc.cx(0, 1) return qc '''
QPC003_A4	A1CADEC397BB8	2	WA	1390 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(1, n): qc.h(i) qc.x(0) for i in range(1, n): qc.cx(i, 0) for i in range(1, n): qc.h(i) return qc '''
QPC003_A4	A1CADEC397BB8	3	RE	1132 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) return qc '''
QPC003_A4	A1CADEC397BB8	4	WA	1302 ms	155 MiB	'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) return qc '''
QPC003_A4	A1CADEC397BB8	5	WA	1393 ms	157 MiB	'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) qc.x(0) return qc '''
QPC003_A4	A1CADEC397BB8	6	AC	1536 ms	158 MiB	'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n-1): theta = 2 * atan(sqrt(n - i - 1)) qc.cry(theta, i - 1, i) for i in range(0, n-1): qc.cx(n-2-i, n-i -1) qc.x(0) return qc '''
QPC003_A4	A21EA979689C7	1	RE	1579 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(2 * math.acos(math.sqrt(2/3) ), 0) for i in range(1, n): qc.cry(2 * math.acos(math.sqrt((n-(i+1)) / (n-(i+1)+1)) ), 0,i) return qc '''
QPC003_A4	A21EA979689C7	2	RE	1214 ms	153 MiB	'''python def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(2 * math.acos(math.sqrt((n - 1) / n)), 0) for i in range(1, n): qc.cry(2 * math.acos(math.sqrt((n - i) / (n - i + 1))), 0, i) return qc '''
QPC003_A4	A2448A6945483	1	WA	1299 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): theta = math.acos(1 / math.sqrt(n - i)) qc.ry(2 * theta, i) # Apply controlled NOTs to ensure only one qubit is in the \|1⟩ state per state if i < n - 1: qc.cx(i, i + 1) return qc '''
QPC003_A4	A24E591CC238C	1	WA	1575 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(1,n): qc.cx(0,i) return qc '''
QPC003_A4	A24E591CC238C	2	WA	1264 ms	155 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(1,n): qc.cx(0,i) return qc '''
QPC003_A4	A24E591CC238C	3	WA	1366 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range(1,n): qc.cx(0,i) return qc '''
QPC003_A4	A24E591CC238C	4	RE	1308 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする return qc '''
QPC003_A4	A24E591CC238C	5	RE	1531 ms	154 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする return qc '''
QPC003_A4	A24E591CC238C	6	UME			'''python from qiskit import QuantumCircuit, Aer, execute import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを\|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする '''
QPC003_A4	A24E591CC238C	7	UME			'''python from qiskit import QuantumCircuit, Aer, execute import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを\|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(math.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする '''
QPC003_A4	A24E591CC238C	8	RE	1598 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを\|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(mat.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする '''
QPC003_A4	A24E591CC238C	9	RE	1418 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを\|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを\|+⟩状態にする qc.u1(math.pi/2, i) # 位相を調整して\|1/sqrt(n)⟩状態にする '''
QPC003_A4	A27960C87F4D0	1	RE	1417 ms	153 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(n): for j in range(i+1, n): qc.cp(np.pi / n, i, j) for i in range(n): qc.h(i) qc.x(i) return qc '''
QPC003_A4	A27960C87F4D0	2	WA	1252 ms	155 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(n): for j in range(i+1, n): qc.cp(math.pi / n, i, j) for i in range(n): qc.h(i) qc.x(i) return qc '''
QPC003_A4	A27960C87F4D0	3	WA	1309 ms	155 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2 * np.arccos(np.sqrt(1/n)), 0) for i in range(1, n): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.cx(i - 1, i) qc.ry(theta, i) qc.cx(i - 1, i) return qc '''
QPC003_A4	A27960C87F4D0	4	WA	1252 ms	155 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i, i-1) return qc '''
QPC003_A4	A27960C87F4D0	5	WA	1238 ms	155 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i+1,i) return qc '''
QPC003_A4	A27960C87F4D0	6	WA	1329 ms	155 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i,i+1) return qc '''
QPC003_A4	A27960C87F4D0	7	AC	1964 ms	158 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.cry(theta,i, i+1) qc.cx(i+1,i) return qc '''
QPC003_A4	A28665AD3F65B	1	RE	1582 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.h(0) qc.x(0) for i in range(n): qc.x(i) qc.cx(i,i+1) return qc '''
QPC003_A4	A2C4B9AC3D5E0	1	AC	1736 ms	158 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: a = (1 / n) ** 0.5 qc.ry(2 * math.acos(a), 0) for i in range(n - 2): a = (1 / (n - 1 - i)) ** 0.5 qc.cry(2 * math.acos(a), i, i + 1) for i in range(1, n - 1)[::-1]: for j in range(i): qc.cx(i, j) qc.x(n - 1) for i in range(n - 1): qc.cx(i, n - 1) return qc '''
QPC003_A4	A2D9DDFB5E073	1	WA	2666 ms	159 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range(1, n): qc.ch(i-1, i) qc.cx(i, i-1) return qc '''
QPC003_A4	A3294B7CFDAD0	1	AC	1820 ms	158 MiB	'''python from math import ( pi, # degrees, # radians, asin, acos, # atan2, sqrt, # sin, # cos, # tan ) import numpy as np from qiskit import QuantumCircuit, QuantumRegister # from qiskit.circuit.library.standard_gates import ( # C3XGate, # C3SXGate, # C4XGate, # CCXGate, # DCXGate, # CHGate, # CPhaseGate, # CRXGate, # CRYGate, # CRZGate, # CSwapGate, # CSXGate, # CUGate, # CU1Gate, # CU3Gate, # CXGate, # CYGate, # CZGate, # CCZGate, # HGate, # IGate, # MCPhaseGate, # PhaseGate, # RCCXGate, # RC3XGate, # RXGate, # RXXGate, # RYGate, # RYYGate, # RZGate, # RZZGate, # RZXGate, # XXMinusYYGate, # XXPlusYYGate, # ECRGate, # SGate, # SdgGate, # CSGate, # CSdgGate, # SwapGate, # iSwapGate, # SXGate, # SXdgGate, # TGate, # TdgGate, # UGate, # U1Gate, # U2Gate, # U3Gate, # XGate, # YGate, # ZGate, # ) def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1, n): qc.cry(asin(sqrt((n - i) / (n - i + 1))) * 2, i - 1, i) for i in range(1, n): qc.cx(i, i - 1) return qc '''
QPC003_A4	A337F39474332	1	AC	1769 ms	157 MiB	'''python import numpy as np from qiskit import QuantumCircuit def F_gate(circ,i,j,n,k) : theta = np.arccos(np.sqrt(1/(n-k+1))) circ.ry(-theta,j) circ.cz(i,j) circ.ry(theta,j) def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(n - 1) for i in range(n - 1): F_gate(qc, n-i-1, n-i-2, n, i+1) for i in range(n - 1): qc.cx(n-i-2, n-i-1) return qc '''
QPC003_A4	A33BEFF6BDD13	1	RE	1185 ms	154 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * np.arccos(1 / 2) qc.ry(theta, 0) qc.cry(theta, 0, 1) qc.cry(theta, 0, 2) qc.cry(theta, 0, 3) return qc '''
QPC003_A4	A33BEFF6BDD13	2	RE	1702 ms	156 MiB	'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * np.arccos(1 / 2) qc.ry(theta, 0) qc.cry(theta, 0, 1) qc.cry(theta, 0, 2) qc.cry(theta, 0, 3) return qc '''
QPC003_A4	A3559DC92D056	1	RE	1905 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in reversed(range(1,n)): qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i) qc.cx(i - 1,i) return qc '''
QPC003_A4	A3559DC92D056	2	RE	1766 ms	153 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in reversed(range(1,n)): qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i) qc.cx(i,i - 1) return qc '''
QPC003_A4	A3559DC92D056	3	RE	1532 ms	154 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n - 1): qc.cry(2 * math.atan(math.sprt(n - i)), i, i + 1) qc.cx(i + 1,i) return qc '''
QPC003_A4	A3559DC92D056	4	AC	2100 ms	157 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)] qc.x(0) for i in range(n - 1): qc.cry(theta[i], i, i + 1) qc.cx(i + 1,i) return qc '''
QPC003_A4	A35AA9E0E4E40	1	AC	2793 ms	168 MiB	'''python from qiskit import QuantumCircuit from qiskit.circuit.library import RYGate import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n-1): qc.x(i) theta = math.acos(math.sqrt((n-1)/(n))) * 2 qc.ry(theta, 0) for i in range(1, n-1): theta = math.acos(math.sqrt((n-i-1)/(n-i))) * 2 qc.append(RYGate(theta).control(i), [_ for _ in range(i + 1)]) qc.mcx([_ for _ in range(n - 1)], n - 1) for i in range(n-1): qc.x(i) qc.z(n - 1) return qc '''
QPC003_A4	A39FDB3550EFF	1	RE	1896 ms	158 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.mch(list(range(i)), i) qc.x(i) for i in range(n): qc.x(i) return qc '''
QPC003_A4	A39FDB3550EFF	2	RE	1648 ms	158 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.mch(list(range(i)), i) qc.x(i) for i in range(n): qc.x(i) return qc '''
QPC003_A4	A39FDB3550EFF	3	RE	1776 ms	158 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.append(HGate().control(i), list(range(i+1))) qc.x(i) for i in range(n): qc.x(i) return qc '''
QPC003_A4	A39FDB3550EFF	4	WA	2017 ms	162 MiB	'''python from qiskit import QuantumCircuit from qiskit.circuit.library.standard_gates import HGate def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.append(HGate().control(i), list(range(i+1))) qc.x(i) for i in range(n): qc.x(i) return qc '''
QPC003_A4	A3A716786D1A4	1	RE	1901 ms	156 MiB	'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(0, n): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''
QPC003_A4	A3A716786D1A4	2	RE	1944 ms	157 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(0, n): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''
QPC003_A4	A3A716786D1A4	3	AC	2401 ms	160 MiB	'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(n - 1): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''

QPC003_A3

AFADD5DA171D1

2

WA

1459 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: # 量子ビット0を|1⟩にするためにXゲートを適用 qc.x(0) # 量子ビット0にアダマールゲートを適用 qc.h(0) # 量子ビット1にHゲートを適用 qc.h(1) # 量子ビット2にHゲートを適用 qc.h(2) # 各状態の位相を調整 pi = 3.14159 qc.rz(pi / 3, 0) # |100⟩ qc.rz(pi / 3, 1) # |010⟩ qc.rz(pi / 3, 2) # |001⟩ return qc '''

QPC003_A3

AFDE7D6BFE13A

1

WA

1535 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.h(0) qc.cx(0,1) qc.cx(0,2) return qc '''

QPC003_A3

AFDE7D6BFE13A

2

RE

1436 ms

153 MiB

'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) qc.cx(0,1) qc.cx(0,2) return qc '''

QPC003_A3

AFDE7D6BFE13A

3

RE

1396 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0) qc.cx(0,1) qc.cx(0,2) return qc '''

QPC003_A3

AFDE7D6BFE13A

4

RE

1403 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.ry(2 * math.atan(pow(2,0.5), 1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''

QPC003_A3

AFDE7D6BFE13A

5

RE

1513 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(pow(2,0.5), 0,1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''

QPC003_A3

AFDE7D6BFE13A

6

RE

1484 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(math.sqrt(2), 0,1)) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''

QPC003_A3

AFDE7D6BFE13A

7

AC

1581 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.x(0) qc.cry(2 * math.atan(math.sqrt(2)), 0,1) qc.cx(1,0) qc.cry(2*math.atan(1),1,2) qc.cx(2,1) return qc '''

QPC003_A3

AFF1911F70140

1

WA

1507 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve() -> QuantumCircuit: qc = QuantumCircuit(3) # Write your code here: qc.h(0) qc.h(1) qc.h(2) qc.x(0) return qc '''

QPC003_A3

AFFAE60BB63F2

1

RE

1510 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.cx(0,1) qc.ry(theta,1) qc.cx(1,2) return qc '''

QPC003_A3

AFFAE60BB63F2

2

RE

1154 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.ch(0,1) qc.cx(1,0) qc.ry(theta,1) qc.ch(1,2) qc.cx(2,1) return qc '''

QPC003_A3

AFFAE60BB63F2

3

RE

1168 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve() -> QuantumCircuit: qc = QuantumCircuit(2) # Write your code here: theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3))) qc.ry(theta,0) qc.cx(0, 1) qc.cx(0, 2) return qc '''

QPC003_A4

A003A4C8324EB

1

AC

1929 ms

156 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) theta = math.asin(1.0 / math.sqrt(n)) qc.ry(2.0 * theta, 0) qc.x(0) qc.cx(0, 1) qc.x(0) for i in range(1, n - 1): theta = math.asin(1.0 / math.sqrt(n-i)) qc.cry(2.0*theta, i, i+1) qc.cx(i, i+1) qc.cx(i+1, i) return qc '''

QPC003_A4

A03D81149875C

1

RE

1209 ms

153 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(n-i)) qc.cry(theta,i-1,i) qc.cx(i,i-1) return qc '''

QPC003_A4

A03D81149875C

2

RE

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(math.sqrt(n-i))) qc.cry(theta,i-1,i) qc.cx(i,i-) return qc '''

QPC003_A4

A03D81149875C

3

RE

1338 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1,n): theta=math.atan(2*math.atan(math.sqrt(n-i))) qc.cry(theta,i-1,i) qc.cx(i,i-1) return qc '''

QPC003_A4

A03D81149875C

4

RE

1638 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)] qc.x(0) for i in range(n-1): qc.cry(theta[i],i,i+1) qc.cx(i+1,i) return qc '''

QPC003_A4

A03D81149875C

5

AC

1852 ms

157 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)] qc.x(0) for i in range(n-1): qc.cry(theta[i],i,i+1) qc.cx(i+1,i) return qc '''

QPC003_A4

A03DE0435906C

1

WA

2022 ms

160 MiB

'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(acos(1-2/n), 0) qc.x(0) for i in range(1, n-1): qc.cry(acos(1 - 2 / (n-i)), i-1, i) qc.x(i) for i in range(n-1): qc.x(i) return qc '''

QPC003_A4

A03DE0435906C

2

WA

1921 ms

161 MiB

'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(acos(1-2/n), 0) qc.x(0) for i in range(1, n): qc.cry(acos(1 - 2 / (n-i)), i-1, i) qc.x(i) for i in range(n): qc.x(i) return qc '''

QPC003_A4

A0460F58C5610

1

WA

1456 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(range(n)) return qc '''

QPC003_A4

A0460F58C5610

2

WA

1671 ms

156 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Define angles for controlled-Ry gates theta = [2 * math.atan(math.sqrt(i)) for i in range(1, n)] # Generate angles for controlled-Ry gates # Start with the initial state by flipping the first qubit to |1⟩ qc.x(0) # Apply controlled-Ry rotations and CNOT gates for i in range(n - 1): qc.cry(theta[i], i, i + 1) # Apply controlled-Ry on qubits i and i+1 qc.cx(i + 1, i) # Apply CNOT between qubits i+1 (control) and i (target) return qc '''

QPC003_A4

A0460F58C5610

3

AC

2006 ms

157 MiB

'''python import math from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)] qc.x(0) for i in range(n - 1): qc.cry(theta[i], i, i + 1) qc.cx(i + 1, i) return qc '''

QPC003_A4

A069404B4EC84

1

RE

2123 ms

156 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n-1): qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1) qc.cx(i+1, i) return qc '''

QPC003_A4

A069404B4EC84

2

AC

2551 ms

161 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n-1): qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1) qc.cx(i+1, i) return qc '''

QPC003_A4

A099B65030BFB

1

AC

1906 ms

158 MiB

'''python from qiskit import QuantumCircuit from math import acos def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = acos((2 - n)/n) qc.u(theta, 0 , 0, 0) for m in range(0, n - 2): theta = acos((3 + m - n)/(n - m - 1)) qc.cu(theta, 0, 0, 0, m, m+1) for m in range(n - 1): qc.mcx(list(range(n - m - 1)), n - m - 1) qc.x(0) return qc '''

QPC003_A4

A09FA2083D8C4

1

RE

1588 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2*acos(1/sqrt(n-i)),0); for i in range(1,n-1): qc.cry(2*acos(1/sqrt(n-i)),i-1,i) for i in range(n-1,0,-1): qc.cx(i-1,i) qc.x(0) return qc '''

QPC003_A4

A09FA2083D8C4

2

AC

1838 ms

158 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2*math.acos(1/math.sqrt(n)),0) for i in range(1,n-1): qc.cry(2*math.acos(1/math.sqrt(n-i)),i-1,i) for i in range(n-1,0,-1): qc.cx(i-1,i) qc.x(0) return qc '''

QPC003_A4

A109C204DF7C1

1

AC

1662 ms

158 MiB

'''python from qiskit import QuantumCircuit from math import pi, acos, sqrt def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) for i in range(n): if i: qc.cry(acos(sqrt(1/(n-i))) * 2, i-1, i) else: qc.ry(acos(sqrt(1/(n-i))) * 2, i) for i in range(n-1, 0, -1): qc.cx(i-1, i) qc.x(0) return qc '''

QPC003_A4

A10CA3439EADE

1

WA

1349 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(0) return qc '''

QPC003_A4

A10CA3439EADE

2

WA

1316 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) return qc '''

QPC003_A4

A10CA3439EADE

3

RE

1436 ms

153 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) for i in range(n): qc.ry(2 * amplitude, i) return qc '''

QPC003_A4

A10CA3439EADE

4

WA

1742 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) for i in range(n): qc.ry(2 * amplitude, i) return qc '''

QPC003_A4

A10CA3439EADE

5

UGE

1433 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: amplitude = 1 /math.sqrt(n) state = [0] * (2**n) for i in range(n): state[2**i] = amplitude qc.initialize(state) return qc '''

QPC003_A4

A10CA3439EADE

6

RE

1191 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) for i in range(1,n): qc.append(CXGate(),[0,i]) return qc '''

QPC003_A4

A10CA3439EADE

7

RE

1457 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) for i in range(1,n): qc.append(CXGate(), [0, i]) return qc '''

QPC003_A4

A10CA3439EADE

8

RE

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.append(HGate(), [0]) # H on the first qubit for i in range(1, n): qc.append(CXGate(), [0, i]) return qc '''

QPC003_A4

A10CA3439EADE

9

WA

1343 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here for i in range(n): qc.h(i) qc.measure_all() return qc '''

QPC003_A4

A10CA3439EADE

10

WA

1368 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here qc.h(0) for i in range(1,n): qc.cx(0,i) qc.measure_all() return qc '''

QPC003_A4

A10CA3439EADE

11

WA

1272 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here qc.h(0) for i in range(1,n): qc.cx(0,i) return qc '''

QPC003_A4

A1AF2CAFE30A4

1

AC

3000 ms

162 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: prob_amp = np.sqrt(1 / n) rot_ang = 2 * np.arccos(prob_amp) qc.x(0) for i in range(n - 1): comp_amp = np.sqrt(1 - i / n) rot_ang = 2 * np.arccos(prob_amp / (comp_amp)) qc.cry(rot_ang, i, i + 1) qc.cx(i + 1, i) return qc '''

QPC003_A4

A1C5F56E70050

1

RE

1284 ms

154 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

2

RE

1178 ms

153 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

3

RE

1179 ms

154 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): angle[i+1]=np.arccos(1/np.sqrt(i+1)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

4

RE

1402 ms

153 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): angle[i+1]=np.arccos(1/np.sqrt(i+1)) for i in range(n): if i>n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

5

RE

1223 ms

153 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

6

RE

1503 ms

153 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-3,n-2) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

7

RE

1703 ms

154 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

8

RE

1620 ms

154 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * n for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n): if i<n-2: qc.cry(angle[n-i]*2,i,i+1) else: qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

9

WA

1841 ms

157 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

10

RE

1243 ms

153 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

11

WA

1793 ms

158 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

12

WA

1681 ms

158 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-i+1+j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

13

WA

1311 ms

158 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-i+1+j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

14

WA

2002 ms

158 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''

QPC003_A4

A1C5F56E70050

15

AC

1724 ms

157 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) if n==2: qc.h(0) qc.x(0) qc.cx(0,1) qc.x(0) return qc else: qc.x(0) angle = [0] * (n+1) for i in range(n+1): if i==0: pass else: angle[i]=np.arccos(1/np.sqrt(i)) for i in range(n-2): qc.cry(angle[n-i]*2,i,i+1) qc.cx(n-2,n-3) qc.ch(n-2,n-1) qc.cx(n-1,n-2) for i in range(n+1): if i<4: pass else: for j in range(i-1): qc.cx(n-1-j,n-i) return qc '''

QPC003_A4

A1CADEC397BB8

1

WA

1318 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range (1, n): qc.cx(0, 1) return qc '''

QPC003_A4

A1CADEC397BB8

2

WA

1390 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(1, n): qc.h(i) qc.x(0) for i in range(1, n): qc.cx(i, 0) for i in range(1, n): qc.h(i) return qc '''

QPC003_A4

A1CADEC397BB8

3

RE

1132 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) return qc '''

QPC003_A4

A1CADEC397BB8

4

WA

1302 ms

155 MiB

'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) return qc '''

QPC003_A4

A1CADEC397BB8

5

WA

1393 ms

157 MiB

'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n): theta = 2 * atan(sqrt(n - i - 1) / (i + 1)) qc.cry(theta, i - 1, i) for i in range(n - 2, -1, -1): qc.cx(i, i + 1) qc.x(0) return qc '''

QPC003_A4

A1CADEC397BB8

6

AC

1536 ms

158 MiB

'''python from qiskit import QuantumCircuit from math import sqrt, atan def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * atan(sqrt(n - 1)) qc.ry(theta, 0) for i in range(1, n-1): theta = 2 * atan(sqrt(n - i - 1)) qc.cry(theta, i - 1, i) for i in range(0, n-1): qc.cx(n-2-i, n-i -1) qc.x(0) return qc '''

QPC003_A4

A21EA979689C7

1

RE

1579 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(2 * math.acos(math.sqrt(2/3) ), 0) for i in range(1, n): qc.cry(2 * math.acos(math.sqrt((n-(i+1)) / (n-(i+1)+1)) ), 0,i) return qc '''

QPC003_A4

A21EA979689C7

2

RE

1214 ms

153 MiB

'''python def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.ry(2 * math.acos(math.sqrt((n - 1) / n)), 0) for i in range(1, n): qc.cry(2 * math.acos(math.sqrt((n - i) / (n - i + 1))), 0, i) return qc '''

QPC003_A4

A2448A6945483

1

WA

1299 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): theta = math.acos(1 / math.sqrt(n - i)) qc.ry(2 * theta, i) # Apply controlled NOTs to ensure only one qubit is in the |1⟩ state per state if i < n - 1: qc.cx(i, i + 1) return qc '''

QPC003_A4

A24E591CC238C

1

WA

1575 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(1,n): qc.cx(0,i) return qc '''

QPC003_A4

A24E591CC238C

2

WA

1264 ms

155 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(1,n): qc.cx(0,i) return qc '''

QPC003_A4

A24E591CC238C

3

WA

1366 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range(1,n): qc.cx(0,i) return qc '''

QPC003_A4

A24E591CC238C

4

RE

1308 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする return qc '''

QPC003_A4

A24E591CC238C

5

RE

1531 ms

154 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする return qc '''

QPC003_A4

A24E591CC238C

6

UME

'''python from qiskit import QuantumCircuit, Aer, execute import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(np.pi/2, 0, np.pi, i) # 量子ビットを|+⟩状態にする qc.u1(np.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする '''

QPC003_A4

A24E591CC238C

7

UME

'''python from qiskit import QuantumCircuit, Aer, execute import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを|+⟩状態にする qc.u1(math.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする '''

QPC003_A4

A24E591CC238C

8

RE

1598 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを|+⟩状態にする qc.u1(mat.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする '''

QPC003_A4

A24E591CC238C

9

RE

1418 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: # すべての量子ビットを|0⟩状態に初期化 for i in range(n): qc.initialize([1, 0], i) # one-hot状態を生成 for i in range(n): qc.u3(math.pi/2, 0, math.pi, i) # 量子ビットを|+⟩状態にする qc.u1(math.pi/2, i) # 位相を調整して|1/sqrt(n)⟩状態にする '''

QPC003_A4

A27960C87F4D0

1

RE

1417 ms

153 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(n): for j in range(i+1, n): qc.cp(np.pi / n, i, j) for i in range(n): qc.h(i) qc.x(i) return qc '''

QPC003_A4

A27960C87F4D0

2

WA

1252 ms

155 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.h(i) for i in range(n): for j in range(i+1, n): qc.cp(math.pi / n, i, j) for i in range(n): qc.h(i) qc.x(i) return qc '''

QPC003_A4

A27960C87F4D0

3

WA

1309 ms

155 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.ry(2 * np.arccos(np.sqrt(1/n)), 0) for i in range(1, n): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.cx(i - 1, i) qc.ry(theta, i) qc.cx(i - 1, i) return qc '''

QPC003_A4

A27960C87F4D0

4

WA

1252 ms

155 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i, i-1) return qc '''

QPC003_A4

A27960C87F4D0

5

WA

1238 ms

155 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i+1,i) return qc '''

QPC003_A4

A27960C87F4D0

6

WA

1329 ms

155 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.ry(theta, i+1) qc.cx(i,i+1) return qc '''

QPC003_A4

A27960C87F4D0

7

AC

1964 ms

158 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(0) for i in range(n-1): theta = 2 * np.arccos(np.sqrt(1 / (n - i))) qc.cry(theta,i, i+1) qc.cx(i+1,i) return qc '''

QPC003_A4

A28665AD3F65B

1

RE

1582 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.h(0) qc.x(0) for i in range(n): qc.x(i) qc.cx(i,i+1) return qc '''

QPC003_A4

A2C4B9AC3D5E0

1

AC

1736 ms

158 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: a = (1 / n) ** 0.5 qc.ry(2 * math.acos(a), 0) for i in range(n - 2): a = (1 / (n - 1 - i)) ** 0.5 qc.cry(2 * math.acos(a), i, i + 1) for i in range(1, n - 1)[::-1]: for j in range(i): qc.cx(i, j) qc.x(n - 1) for i in range(n - 1): qc.cx(i, n - 1) return qc '''

QPC003_A4

A2D9DDFB5E073

1

WA

2666 ms

159 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.h(0) for i in range(1, n): qc.ch(i-1, i) qc.cx(i, i-1) return qc '''

QPC003_A4

A3294B7CFDAD0

1

AC

1820 ms

158 MiB

'''python from math import ( pi, # degrees, # radians, asin, acos, # atan2, sqrt, # sin, # cos, # tan ) import numpy as np from qiskit import QuantumCircuit, QuantumRegister # from qiskit.circuit.library.standard_gates import ( # C3XGate, # C3SXGate, # C4XGate, # CCXGate, # DCXGate, # CHGate, # CPhaseGate, # CRXGate, # CRYGate, # CRZGate, # CSwapGate, # CSXGate, # CUGate, # CU1Gate, # CU3Gate, # CXGate, # CYGate, # CZGate, # CCZGate, # HGate, # IGate, # MCPhaseGate, # PhaseGate, # RCCXGate, # RC3XGate, # RXGate, # RXXGate, # RYGate, # RYYGate, # RZGate, # RZZGate, # RZXGate, # XXMinusYYGate, # XXPlusYYGate, # ECRGate, # SGate, # SdgGate, # CSGate, # CSdgGate, # SwapGate, # iSwapGate, # SXGate, # SXdgGate, # TGate, # TdgGate, # UGate, # U1Gate, # U2Gate, # U3Gate, # XGate, # YGate, # ZGate, # ) def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(1, n): qc.cry(asin(sqrt((n - i) / (n - i + 1))) * 2, i - 1, i) for i in range(1, n): qc.cx(i, i - 1) return qc '''

QPC003_A4

A337F39474332

1

AC

1769 ms

157 MiB

'''python import numpy as np from qiskit import QuantumCircuit def F_gate(circ,i,j,n,k) : theta = np.arccos(np.sqrt(1/(n-k+1))) circ.ry(-theta,j) circ.cz(i,j) circ.ry(theta,j) def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) qc.x(n - 1) for i in range(n - 1): F_gate(qc, n-i-1, n-i-2, n, i+1) for i in range(n - 1): qc.cx(n-i-2, n-i-1) return qc '''

QPC003_A4

A33BEFF6BDD13

1

RE

1185 ms

154 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * np.arccos(1 / 2) qc.ry(theta, 0) qc.cry(theta, 0, 1) qc.cry(theta, 0, 2) qc.cry(theta, 0, 3) return qc '''

QPC003_A4

A33BEFF6BDD13

2

RE

1702 ms

156 MiB

'''python from qiskit import QuantumCircuit import numpy as np def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = 2 * np.arccos(1 / 2) qc.ry(theta, 0) qc.cry(theta, 0, 1) qc.cry(theta, 0, 2) qc.cry(theta, 0, 3) return qc '''

QPC003_A4

A3559DC92D056

1

RE

1905 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in reversed(range(1,n)): qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i) qc.cx(i - 1,i) return qc '''

QPC003_A4

A3559DC92D056

2

RE

1766 ms

153 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in reversed(range(1,n)): qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i) qc.cx(i,i - 1) return qc '''

QPC003_A4

A3559DC92D056

3

RE

1532 ms

154 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for i in range(n - 1): qc.cry(2 * math.atan(math.sprt(n - i)), i, i + 1) qc.cx(i + 1,i) return qc '''

QPC003_A4

A3559DC92D056

4

AC

2100 ms

157 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)] qc.x(0) for i in range(n - 1): qc.cry(theta[i], i, i + 1) qc.cx(i + 1,i) return qc '''

QPC003_A4

A35AA9E0E4E40

1

AC

2793 ms

168 MiB

'''python from qiskit import QuantumCircuit from qiskit.circuit.library import RYGate import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n-1): qc.x(i) theta = math.acos(math.sqrt((n-1)/(n))) * 2 qc.ry(theta, 0) for i in range(1, n-1): theta = math.acos(math.sqrt((n-i-1)/(n-i))) * 2 qc.append(RYGate(theta).control(i), [_ for _ in range(i + 1)]) qc.mcx([_ for _ in range(n - 1)], n - 1) for i in range(n-1): qc.x(i) qc.z(n - 1) return qc '''

QPC003_A4

A39FDB3550EFF

1

RE

1896 ms

158 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): qc.mch(list(range(i)), i) qc.x(i) for i in range(n): qc.x(i) return qc '''

QPC003_A4

A39FDB3550EFF

2

RE

1648 ms

158 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.mch(list(range(i)), i) qc.x(i) for i in range(n): qc.x(i) return qc '''

QPC003_A4

A39FDB3550EFF

3

RE

1776 ms

158 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.append(HGate().control(i), list(range(i+1))) qc.x(i) for i in range(n): qc.x(i) return qc '''

QPC003_A4

A39FDB3550EFF

4

WA

2017 ms

162 MiB

'''python from qiskit import QuantumCircuit from qiskit.circuit.library.standard_gates import HGate def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: for i in range(n): if i == 0: qc.h(i) else: qc.append(HGate().control(i), list(range(i+1))) qc.x(i) for i in range(n): qc.x(i) return qc '''

QPC003_A4

A3A716786D1A4

1

RE

1901 ms

156 MiB

'''python from qiskit import QuantumCircuit def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(0, n): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''

QPC003_A4

A3A716786D1A4

2

RE

1944 ms

157 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(0, n): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''

QPC003_A4

A3A716786D1A4

3

AC

2401 ms

160 MiB

'''python from qiskit import QuantumCircuit import math def solve(n: int) -> QuantumCircuit: qc = QuantumCircuit(n) # Write your code here: qc.x(0) for _ in range(n - 1): qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1) qc.cx(_ + 1, _) return qc '''