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132
|
A
|
Turing Tape
|
PROGRAMMING
| 1,300
|
[
"implementation"
] | null | null |
INTERCAL is the oldest of esoteric programming languages. One of its many weird features is the method of character-based output, known as Turing Tape method. It converts an array of unsigned 8-bit integers into a sequence of characters to print, using the following method.
The integers of the array are processed one by one, starting from the first. Processing *i*-th element of the array is done in three steps:
1. The 8-bit binary notation of the ASCII-code of the previous printed character is reversed. When the first element of the array is processed, the result of this step is considered to be 0.
2. The *i*-th element of the array is subtracted from the result of the previous step modulo 256.
3. The binary notation of the result of the previous step is reversed again to produce ASCII-code of the *i*-th character to be printed.
You are given the text printed using this method. Restore the array used to produce this text.
|
The input will consist of a single line *text* which contains the message printed using the described method. String *text* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *text* will be between 32 (space) and 126 (tilde), inclusive.
|
Output the initial array, which was used to produce *text*, one integer per line.
|
[
"Hello, World!\n"
] |
[
"238\n108\n112\n0\n64\n194\n48\n26\n244\n168\n24\n16\n162\n"
] |
Let's have a closer look at the beginning of the example. The first character is "H" with ASCII-code 72 = 01001000<sub class="lower-index">2</sub>. Its reverse is 00010010<sub class="lower-index">2</sub> = 18, and this number should become the result of the second step of processing. The result of the first step is considered to be 0, so the first element of the array has to be (0 - 18) mod 256 = 238, where *a* mod *b* is the remainder of division of *a* by *b*.
| 500
|
[
{
"input": "Hello, World!",
"output": "238\n108\n112\n0\n64\n194\n48\n26\n244\n168\n24\n16\n162"
},
{
"input": "N",
"output": "142"
},
{
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"output": "110\n30\n80\n174\n252\n156\n252\n112\n240\n158\n206\n194\n166\n100\n168\n6\n134\n244\n16\n228\n192\n28\n132\n44\n180\n116\n118\n232\n242\n46\n210\n160\n160\n38\n50\n192\n12\n52\n252\n220\n118\n16\n126\n80\n184\n240\n60\n128\n30\n66\n228\n104\n184\n218\n56\n176\n72\n30\n164\n116\n76\n48\n240\n88\n126\n110\n114\n114\n70\n146\n158\n154\n150\n200\n210\n200\n216\n124\n218\n154\n36\n244\n56\n78\n166\n24\n72\n74\n74\n16\n212\n168\n52\n236\n252\n84\n44\n168"
},
{
"input": "_]-egPQ]jlIjOA|r?]YI*?D%(;DVTcU5l#FQ]-{sxaqw-'>B3rT g`GgCEv,BzL_(sPArv2&",
"output": "6\n64\n6\n14\n192\n220\n128\n208\n100\n32\n164\n60\n100\n112\n68\n240\n82\n66\n32\n8\n62\n88\n218\n126\n144\n56\n186\n184\n64\n100\n28\n254\n118\n114\n98\n216\n208\n6\n214\n16\n176\n152\n248\n160\n58\n208\n104\n58\n118\n126\n36\n38\n30\n224\n36\n252\n36\n32\n52\n58\n242\n228\n44\n56\n230\n70\n196\n136\n52\n224\n34\n232"
},
{
"input": "x,6Yl%^l5Q+H,1QLwvi}:3td8{ipP(U{\"'FWYn0-r:v)E09",
"output": "226\n234\n200\n210\n100\n146\n42\n68\n138\n34\n182\n194\n222\n168\n2\n88\n68\n128\n216\n216\n98\n144\n158\n8\n10\n62\n72\n136\n4\n246\n106\n204\n154\n96\n130\n120\n80\n36\n106\n88\n102\n242\n238\n218\n242\n150\n112"
},
{
"input": "/Z@PuVh~_3k*d )%Q/|RL",
"output": "12\n154\n88\n248\n92\n68\n84\n152\n132\n46\n246\n130\n46\n34\n112\n240\n26\n150\n182\n244\n24"
},
{
"input": "E-ID~,u/*xLjAn]^+H-'_ q'U9SIOpWFJ*AcN4Y[gD!Nt?1GV=6_6T2&-,9]9WFjVo*hI2Q:r[h2qZTN/`<kaa6Biur*KRv]",
"output": "94\n238\n34\n112\n164\n74\n134\n186\n160\n54\n236\n220\n212\n12\n188\n64\n166\n194\n94\n208\n234\n246\n118\n170\n58\n14\n210\n56\n160\n228\n36\n136\n16\n254\n210\n188\n84\n70\n146\n192\n244\n196\n158\n18\n68\n50\n112\n170\n120\n174\n80\n114\n142\n66\n222\n232\n176\n128\n152\n226\n30\n178\n136\n12\n236\n116\n162\n62\n132\n70\n194\n46\n14\n116\n196\n202\n190\n52\n48\n184\n126\n238\n202\n102\n80\n0\n26\n42\n172\n232\n96\n250\n130\n136\n220\n180"
},
{
"input": "^[O;(`~>S]+Hz^58ca=[osBfevxgL2W,_*AiJumta|)_*H,Ibmls%.KRDcdn6.GmDm=W:X",
"output": "134\n160\n232\n22\n200\n14\n136\n2\n178\n16\n230\n194\n180\n228\n206\n144\n86\n64\n202\n226\n228\n40\n140\n220\n192\n56\n80\n56\n180\n230\n98\n182\n58\n166\n210\n236\n68\n164\n248\n136\n168\n72\n170\n154\n166\n66\n222\n162\n76\n144\n128\n104\n42\n48\n162\n136\n40\n92\n160\n176\n10\n248\n146\n44\n148\n108\n250\n210\n142\n66"
},
{
"input": "t+X/.5,P}@k*VMip=yM1#hrFrV:#KUXot->nCY#.YR.qB",
"output": "210\n90\n186\n38\n128\n200\n120\n42\n76\n188\n44\n130\n234\n184\n28\n136\n82\n30\n236\n38\n200\n174\n200\n236\n20\n228\n14\n152\n242\n40\n144\n36\n200\n122\n56\n6\n180\n40\n214\n80\n218\n80\n214\n230\n76"
},
{
"input": "+Ya%7i6_H%Mg0<AJv3`",
"output": "44\n58\n20\n226\n184\n86\n42\n114\n232\n110\n242\n204\n218\n208\n186\n48\n228\n162\n198"
},
{
"input": "A(k{?;Cqri.Hl,x$PLp=EQsf4p%^G>Y:=0;z8{L]M`77q`\"O&8PSR\"6p.G(@.jAxqiz~qswxc~| ,;~<Rw#=XHbQ4=kJV",
"output": "126\n110\n62\n248\n226\n32\n26\n52\n64\n184\n34\n98\n220\n2\n22\n250\n26\n216\n36\n82\n26\n24\n188\n104\n58\n30\n106\n42\n152\n102\n226\n62\n160\n176\n48\n126\n66\n62\n172\n120\n8\n172\n26\n0\n94\n136\n194\n82\n142\n72\n18\n64\n128\n6\n216\n94\n154\n146\n206\n18\n142\n30\n212\n100\n144\n248\n56\n224\n240\n192\n224\n208\n88\n72\n64\n58\n208\n88\n94\n66\n242\n92\n42\n8\n162\n8\n204\n188\n94\n112\n230\n132\n232"
},
{
"input": "ZWtoEoP\"=Ln'EzM\\)d\"qXHAFAQIxDbY!R4;!4``vG5<H)i{M2e'hD^L9H~SN(A>{bg.i",
"output": "166\n112\n188\n56\n84\n172\n236\n198\n136\n138\n188\n146\n66\n68\n172\n120\n166\n110\n226\n182\n116\n8\n144\n32\n224\n248\n248\n116\n252\n220\n172\n22\n58\n30\n80\n88\n88\n38\n0\n152\n140\n54\n112\n42\n126\n254\n184\n44\n102\n166\n194\n206\n244\n168\n72\n150\n138\n148\n180\n88\n94\n146\n6\n158\n152\n96\n114\n222"
},
{
"input": "w7zw3)Vw&h",
"output": "18\n2\n142\n112\n34\n56\n42\n124\n138\n78"
},
{
"input": "1f$k9Zc(PM'D?xVLWm.Y}o$5g`bRxd9Jl$LMAB5mQi$/6\"@N`IimEvs~zp%)xwRL''>3<\"Z!(09DoyGd{EBA",
"output": "116\n38\n66\n78\n58\n66\n148\n178\n10\n88\n206\n194\n38\n222\n180\n56\n72\n52\n66\n218\n220\n200\n210\n120\n198\n224\n192\n252\n44\n248\n138\n74\n28\n18\n242\n128\n48\n64\n150\n246\n44\n244\n114\n48\n136\n40\n66\n144\n108\n116\n252\n224\n20\n52\n160\n80\n32\n80\n106\n16\n118\n48\n164\n24\n78\n0\n104\n176\n144\n248\n234\n214\n112\n8\n112\n122\n44\n88\n188\n188\n72\n60\n96\n192"
},
{
"input": "G5-bB/m7z/h%zh+%1'>11cTtt>%pt)91\"$IS:#I'K?(AN+;Ply@#3S+K2JP",
"output": "30\n54\n248\n110\n4\n78\n62\n202\n142\n106\n222\n114\n70\n72\n66\n48\n24\n168\n104\n240\n0\n198\n156\n252\n0\n178\n216\n150\n224\n154\n248\n16\n72\n32\n146\n200\n110\n152\n50\n174\n18\n214\n232\n146\n16\n158\n248\n210\n212\n152\n156\n62\n248\n2\n246\n2\n134\n250\n72"
},
{
"input": "]d4VJczIDtIbTWb^j?QeAX%T%}I+tL:t8",
"output": "70\n148\n250\n194\n24\n140\n104\n204\n112\n244\n156\n76\n28\n64\n164\n204\n36\n90\n114\n228\n36\n104\n118\n122\n134\n230\n44\n190\n166\n252\n214\n46\n18"
},
{
"input": "s3=MS8%X",
"output": "50\n2\n16\n10\n232\n174\n120\n138"
},
{
"input": "-dFDYl2g9<k%i6np|qqncD\"sC;3dp2;?b*Ge+*'o7\":w3C.S0A\"baGtiz/uki+IZB!,Hdc!_xPP3*]rS<_",
"output": "76\n142\n196\n64\n136\n100\n234\n102\n74\n96\n102\n50\n14\n42\n246\n104\n208\n176\n0\n24\n176\n164\n222\n118\n12\n230\n16\n166\n24\n194\n112\n224\n182\n242\n114\n60\n210\n128\n112\n238\n10\n168\n232\n110\n34\n10\n78\n170\n190\n138\n62\n254\n192\n164\n180\n152\n56\n106\n70\n216\n64\n194\n66\n56\n24\n190\n80\n34\n236\n96\n66\n138\n220\n20\n0\n62\n120\n154\n108\n132\n142\n66"
},
{
"input": "C4O7b?;zc!LbF%FJV*%Cv8RWSxX\"lV;%t*Dj'k<&1W?)JL+T<qXwP%/36",
"output": "62\n150\n58\n6\n166\n74\n32\n126\n152\n66\n82\n236\n228\n190\n66\n16\n232\n22\n176\n226\n84\n82\n210\n96\n32\n172\n4\n214\n14\n204\n142\n56\n118\n218\n50\n204\n114\n14\n154\n216\n216\n162\n238\n104\n66\n32\n94\n170\n238\n174\n116\n44\n228\n102\n176\n40\n96"
},
{
"input": "YbX.ksH*-e.D~sz$0C6x*-#7cX}@lz<",
"output": "102\n84\n44\n166\n158\n8\n188\n190\n160\n14\n50\n82\n164\n176\n112\n58\n24\n74\n86\n78\n202\n160\n240\n216\n38\n172\n92\n188\n204\n216\n34"
},
{
"input": "o2^\"t",
"output": "10\n170\n210\n54\n22"
},
{
"input": ")`hxy|_K\"-Pb5R'6BtY\"Mu$V!ugxhb=6U1A|ttvq|:N`2f}Z_<<W}wxT~JdK]>Al`}{^*FG<jsg\"D>=A",
"output": "108\n142\n240\n248\n128\n96\n68\n40\n142\n144\n170\n196\n154\n98\n102\n120\n42\n20\n148\n86\n146\n4\n138\n186\n230\n214\n200\n200\n8\n208\n138\n80\n194\n30\n10\n68\n16\n0\n192\n224\n80\n226\n234\n108\n186\n230\n168\n100\n96\n190\n0\n82\n44\n208\n208\n244\n172\n44\n44\n84\n24\n62\n250\n76\n48\n72\n224\n100\n38\n242\n128\n166\n230\n136\n232\n162\n34\n166\n192\n58"
},
{
"input": "JAn}d3f?jI'?QaWI:dR7bH",
"output": "174\n208\n12\n184\n152\n90\n102\n106\n166\n196\n174\n232\n114\n4\n156\n88\n54\n54\n220\n94\n166\n52"
}
] | 1,634,124,034
| 2,147,483,647
|
PyPy 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 154
| 2,150,400
|
from math import ceil
for _ in range(int(input())):
a,b = map(int,input().split())
print(ceil(a/b)*b-a)
|
Title: Turing Tape
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
INTERCAL is the oldest of esoteric programming languages. One of its many weird features is the method of character-based output, known as Turing Tape method. It converts an array of unsigned 8-bit integers into a sequence of characters to print, using the following method.
The integers of the array are processed one by one, starting from the first. Processing *i*-th element of the array is done in three steps:
1. The 8-bit binary notation of the ASCII-code of the previous printed character is reversed. When the first element of the array is processed, the result of this step is considered to be 0.
2. The *i*-th element of the array is subtracted from the result of the previous step modulo 256.
3. The binary notation of the result of the previous step is reversed again to produce ASCII-code of the *i*-th character to be printed.
You are given the text printed using this method. Restore the array used to produce this text.
Input Specification:
The input will consist of a single line *text* which contains the message printed using the described method. String *text* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *text* will be between 32 (space) and 126 (tilde), inclusive.
Output Specification:
Output the initial array, which was used to produce *text*, one integer per line.
Demo Input:
['Hello, World!\n']
Demo Output:
['238\n108\n112\n0\n64\n194\n48\n26\n244\n168\n24\n16\n162\n']
Note:
Let's have a closer look at the beginning of the example. The first character is "H" with ASCII-code 72 = 01001000<sub class="lower-index">2</sub>. Its reverse is 00010010<sub class="lower-index">2</sub> = 18, and this number should become the result of the second step of processing. The result of the first step is considered to be 0, so the first element of the array has to be (0 - 18) mod 256 = 238, where *a* mod *b* is the remainder of division of *a* by *b*.
|
```python
from math import ceil
for _ in range(int(input())):
a,b = map(int,input().split())
print(ceil(a/b)*b-a)
```
| -1
|
|
817
|
A
|
Treasure Hunt
|
PROGRAMMING
| 1,200
|
[
"implementation",
"math",
"number theory"
] | null | null |
Captain Bill the Hummingbird and his crew recieved an interesting challenge offer. Some stranger gave them a map, potion of teleportation and said that only this potion might help them to reach the treasure.
Bottle with potion has two values *x* and *y* written on it. These values define four moves which can be performed using the potion:
- - - -
Map shows that the position of Captain Bill the Hummingbird is (*x*1,<=*y*1) and the position of the treasure is (*x*2,<=*y*2).
You task is to tell Captain Bill the Hummingbird whether he should accept this challenge or decline. If it is possible for Captain to reach the treasure using the potion then output "YES", otherwise "NO" (without quotes).
The potion can be used infinite amount of times.
|
The first line contains four integer numbers *x*1,<=*y*1,<=*x*2,<=*y*2 (<=-<=105<=≤<=*x*1,<=*y*1,<=*x*2,<=*y*2<=≤<=105) — positions of Captain Bill the Hummingbird and treasure respectively.
The second line contains two integer numbers *x*,<=*y* (1<=≤<=*x*,<=*y*<=≤<=105) — values on the potion bottle.
|
Print "YES" if it is possible for Captain to reach the treasure using the potion, otherwise print "NO" (without quotes).
|
[
"0 0 0 6\n2 3\n",
"1 1 3 6\n1 5\n"
] |
[
"YES\n",
"NO\n"
] |
In the first example there exists such sequence of moves:
1. <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/7c939890fb4ed35688177327dac981bfa9216c00.png" style="max-width: 100.0%;max-height: 100.0%;"/> — the first type of move 1. <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/afbfa42fbac4e0641e7466e3aac74cbbb08ed597.png" style="max-width: 100.0%;max-height: 100.0%;"/> — the third type of move
| 0
|
[
{
"input": "0 0 0 6\n2 3",
"output": "YES"
},
{
"input": "1 1 3 6\n1 5",
"output": "NO"
},
{
"input": "5 4 6 -10\n1 1",
"output": "NO"
},
{
"input": "6 -3 -7 -7\n1 2",
"output": "NO"
},
{
"input": "2 -5 -8 8\n2 1",
"output": "YES"
},
{
"input": "70 -81 -17 80\n87 23",
"output": "YES"
},
{
"input": "41 366 218 -240\n3456 1234",
"output": "NO"
},
{
"input": "-61972 -39646 -42371 -24854\n573 238",
"output": "NO"
},
{
"input": "-84870 -42042 94570 98028\n8972 23345",
"output": "YES"
},
{
"input": "-58533 -50999 -1007 -59169\n8972 23345",
"output": "NO"
},
{
"input": "-100000 -100000 100000 100000\n100000 100000",
"output": "YES"
},
{
"input": "-100000 -100000 100000 100000\n1 1",
"output": "YES"
},
{
"input": "5 2 5 3\n1 1",
"output": "NO"
},
{
"input": "5 5 5 5\n5 5",
"output": "YES"
},
{
"input": "0 0 1000 1000\n1 1",
"output": "YES"
},
{
"input": "0 0 0 1\n1 1",
"output": "NO"
},
{
"input": "1 1 4 4\n2 2",
"output": "NO"
},
{
"input": "100000 100000 99999 99999\n100000 100000",
"output": "NO"
},
{
"input": "1 1 1 6\n1 5",
"output": "NO"
},
{
"input": "2 9 4 0\n2 3",
"output": "YES"
},
{
"input": "0 0 0 9\n2 3",
"output": "NO"
},
{
"input": "14 88 14 88\n100 500",
"output": "YES"
},
{
"input": "-1 0 3 0\n4 4",
"output": "NO"
},
{
"input": "0 0 8 9\n2 3",
"output": "NO"
},
{
"input": "-2 5 7 -6\n1 1",
"output": "YES"
},
{
"input": "3 7 -8 8\n2 2",
"output": "NO"
},
{
"input": "-4 -8 -6 -1\n1 3",
"output": "NO"
},
{
"input": "0 8 6 2\n1 1",
"output": "YES"
},
{
"input": "-5 -2 -8 -2\n1 1",
"output": "NO"
},
{
"input": "1 4 -5 0\n1 1",
"output": "YES"
},
{
"input": "8 -4 4 -7\n1 2",
"output": "NO"
},
{
"input": "5 2 2 4\n2 2",
"output": "NO"
},
{
"input": "2 0 -4 6\n1 2",
"output": "NO"
},
{
"input": "-2 6 -5 -4\n1 2",
"output": "YES"
},
{
"input": "-6 5 10 6\n2 4",
"output": "NO"
},
{
"input": "3 -7 1 -8\n1 2",
"output": "NO"
},
{
"input": "4 1 4 -4\n9 4",
"output": "NO"
},
{
"input": "9 -3 -9 -3\n2 2",
"output": "NO"
},
{
"input": "-6 -6 -10 -5\n6 7",
"output": "NO"
},
{
"input": "-5 -2 2 2\n1 7",
"output": "NO"
},
{
"input": "9 0 8 1\n7 10",
"output": "NO"
},
{
"input": "-1 6 -7 -6\n6 4",
"output": "YES"
},
{
"input": "2 2 -3 -3\n3 1",
"output": "NO"
},
{
"input": "2 -6 7 2\n2 1",
"output": "NO"
},
{
"input": "-6 2 -7 -7\n1 2",
"output": "NO"
},
{
"input": "-5 -5 -1 -5\n2 2",
"output": "YES"
},
{
"input": "0 5 3 -6\n2 2",
"output": "NO"
},
{
"input": "0 -6 2 -1\n1 1",
"output": "NO"
},
{
"input": "-6 6 -5 -4\n1 2",
"output": "YES"
},
{
"input": "7 -7 1 -7\n2 2",
"output": "NO"
},
{
"input": "99966 -99952 -99966 99923\n1 1",
"output": "NO"
},
{
"input": "99921 99980 -99956 -99907\n3 4",
"output": "NO"
},
{
"input": "100000 100000 -100000 -100000\n1 1",
"output": "YES"
},
{
"input": "1 0 2 0\n5 1",
"output": "NO"
},
{
"input": "-3 0 -8 0\n7 2",
"output": "NO"
},
{
"input": "-9 4 -5 -1\n8 2",
"output": "NO"
},
{
"input": "-99999 -100000 100000 100000\n1 1",
"output": "NO"
},
{
"input": "0 0 -100 -100\n2 2",
"output": "YES"
},
{
"input": "9 -5 -3 -2\n1 4",
"output": "NO"
},
{
"input": "1 -10 -10 5\n7 5",
"output": "NO"
},
{
"input": "6 -9 -1 -9\n1 9",
"output": "NO"
}
] | 1,553,590,591
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 93
| 0
|
a,b,xx,yy=[int(i) for i in input().split()]
x,y=[int(i) for i in input().split()]
xx-=a
yy-=b
if x==1 and xx%2==0:
print("NO")
exit(0)
elif y==1 and yy%2==0:
print("NO")
exit(0)
if xx%x==0 and yy%y==0 or xx%(2*x)==0 and yy%(2*y)==0:
print("YES")
else:
print("NO")
|
Title: Treasure Hunt
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Captain Bill the Hummingbird and his crew recieved an interesting challenge offer. Some stranger gave them a map, potion of teleportation and said that only this potion might help them to reach the treasure.
Bottle with potion has two values *x* and *y* written on it. These values define four moves which can be performed using the potion:
- - - -
Map shows that the position of Captain Bill the Hummingbird is (*x*1,<=*y*1) and the position of the treasure is (*x*2,<=*y*2).
You task is to tell Captain Bill the Hummingbird whether he should accept this challenge or decline. If it is possible for Captain to reach the treasure using the potion then output "YES", otherwise "NO" (without quotes).
The potion can be used infinite amount of times.
Input Specification:
The first line contains four integer numbers *x*1,<=*y*1,<=*x*2,<=*y*2 (<=-<=105<=≤<=*x*1,<=*y*1,<=*x*2,<=*y*2<=≤<=105) — positions of Captain Bill the Hummingbird and treasure respectively.
The second line contains two integer numbers *x*,<=*y* (1<=≤<=*x*,<=*y*<=≤<=105) — values on the potion bottle.
Output Specification:
Print "YES" if it is possible for Captain to reach the treasure using the potion, otherwise print "NO" (without quotes).
Demo Input:
['0 0 0 6\n2 3\n', '1 1 3 6\n1 5\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first example there exists such sequence of moves:
1. <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/7c939890fb4ed35688177327dac981bfa9216c00.png" style="max-width: 100.0%;max-height: 100.0%;"/> — the first type of move 1. <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/afbfa42fbac4e0641e7466e3aac74cbbb08ed597.png" style="max-width: 100.0%;max-height: 100.0%;"/> — the third type of move
|
```python
a,b,xx,yy=[int(i) for i in input().split()]
x,y=[int(i) for i in input().split()]
xx-=a
yy-=b
if x==1 and xx%2==0:
print("NO")
exit(0)
elif y==1 and yy%2==0:
print("NO")
exit(0)
if xx%x==0 and yy%y==0 or xx%(2*x)==0 and yy%(2*y)==0:
print("YES")
else:
print("NO")
```
| 0
|
|
115
|
A
|
Party
|
PROGRAMMING
| 900
|
[
"dfs and similar",
"graphs",
"trees"
] | null | null |
A company has *n* employees numbered from 1 to *n*. Each employee either has no immediate manager or exactly one immediate manager, who is another employee with a different number. An employee *A* is said to be the superior of another employee *B* if at least one of the following is true:
- Employee *A* is the immediate manager of employee *B* - Employee *B* has an immediate manager employee *C* such that employee *A* is the superior of employee *C*.
The company will not have a managerial cycle. That is, there will not exist an employee who is the superior of his/her own immediate manager.
Today the company is going to arrange a party. This involves dividing all *n* employees into several groups: every employee must belong to exactly one group. Furthermore, within any single group, there must not be two employees *A* and *B* such that *A* is the superior of *B*.
What is the minimum number of groups that must be formed?
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=2000) — the number of employees.
The next *n* lines contain the integers *p**i* (1<=≤<=*p**i*<=≤<=*n* or *p**i*<==<=-1). Every *p**i* denotes the immediate manager for the *i*-th employee. If *p**i* is -1, that means that the *i*-th employee does not have an immediate manager.
It is guaranteed, that no employee will be the immediate manager of him/herself (*p**i*<=≠<=*i*). Also, there will be no managerial cycles.
|
Print a single integer denoting the minimum number of groups that will be formed in the party.
|
[
"5\n-1\n1\n2\n1\n-1\n"
] |
[
"3\n"
] |
For the first example, three groups are sufficient, for example:
- Employee 1 - Employees 2 and 4 - Employees 3 and 5
| 500
|
[
{
"input": "5\n-1\n1\n2\n1\n-1",
"output": "3"
},
{
"input": "4\n-1\n1\n2\n3",
"output": "4"
},
{
"input": "12\n-1\n1\n2\n3\n-1\n5\n6\n7\n-1\n9\n10\n11",
"output": "4"
},
{
"input": "6\n-1\n-1\n2\n3\n1\n1",
"output": "3"
},
{
"input": "3\n-1\n1\n1",
"output": "2"
},
{
"input": "1\n-1",
"output": "1"
},
{
"input": "2\n2\n-1",
"output": "2"
},
{
"input": "2\n-1\n-1",
"output": "1"
},
{
"input": "3\n2\n-1\n1",
"output": "3"
},
{
"input": "3\n-1\n-1\n-1",
"output": "1"
},
{
"input": "5\n4\n5\n1\n-1\n4",
"output": "3"
},
{
"input": "12\n-1\n1\n1\n1\n1\n1\n3\n4\n3\n3\n4\n7",
"output": "4"
},
{
"input": "12\n-1\n-1\n1\n-1\n1\n1\n5\n11\n8\n6\n6\n4",
"output": "5"
},
{
"input": "12\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n2\n-1\n-1\n-1",
"output": "2"
},
{
"input": "12\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1",
"output": "1"
},
{
"input": "12\n3\n4\n2\n8\n7\n1\n10\n12\n5\n-1\n9\n11",
"output": "12"
},
{
"input": "12\n5\n6\n7\n1\n-1\n9\n12\n4\n8\n-1\n3\n2",
"output": "11"
},
{
"input": "12\n-1\n9\n11\n6\n6\n-1\n6\n3\n8\n6\n1\n6",
"output": "6"
},
{
"input": "12\n7\n8\n4\n12\n7\n9\n-1\n-1\n-1\n8\n6\n-1",
"output": "3"
},
{
"input": "12\n-1\n10\n-1\n1\n-1\n5\n9\n12\n-1\n-1\n3\n-1",
"output": "2"
},
{
"input": "12\n-1\n7\n9\n12\n1\n7\n-1\n-1\n8\n5\n4\n-1",
"output": "3"
},
{
"input": "12\n11\n11\n8\n9\n1\n1\n2\n-1\n10\n3\n-1\n8",
"output": "5"
},
{
"input": "12\n-1\n8\n9\n-1\n4\n2\n11\n1\n-1\n6\n-1\n10",
"output": "6"
},
{
"input": "12\n7\n4\n4\n-1\n6\n7\n9\n7\n-1\n7\n4\n1",
"output": "4"
},
{
"input": "12\n-1\n6\n10\n6\n1\n11\n5\n9\n11\n5\n1\n9",
"output": "4"
},
{
"input": "12\n8\n6\n6\n8\n6\n-1\n6\n6\n8\n6\n8\n8",
"output": "3"
},
{
"input": "12\n3\n8\n9\n12\n2\n8\n11\n12\n2\n9\n-1\n11",
"output": "7"
},
{
"input": "7\n7\n6\n-1\n-1\n4\n4\n-1",
"output": "3"
},
{
"input": "77\n53\n-1\n48\n-1\n51\n-1\n54\n43\n70\n19\n64\n31\n45\n58\n6\n61\n41\n56\n34\n-1\n54\n-1\n66\n65\n74\n16\n38\n1\n2\n61\n-1\n34\n-1\n-1\n7\n19\n57\n13\n61\n42\n-1\n34\n65\n16\n31\n61\n6\n5\n34\n15\n-1\n13\n4\n22\n74\n7\n-1\n70\n38\n61\n45\n53\n46\n22\n-1\n65\n34\n19\n43\n48\n33\n58\n36\n-1\n47\n24\n34",
"output": "6"
},
{
"input": "5\n2\n3\n4\n5\n-1",
"output": "5"
}
] | 1,660,051,803
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 106
| 124
| 409,600
|
from collections import defaultdict, deque
n = int(input())
adj_list = defaultdict(list)
for i in range(1, n+1):
cur = int(input())
adj_list[cur].append(i)
q = deque(adj_list[-1])
level = 0
ans = 0
while q:
size = len(q)
ans = max(ans, size)
level+=1
for i_ in range(size):
top = q.popleft()
if top in adj_list:
q.extend(adj_list[top])
print(level)
|
Title: Party
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A company has *n* employees numbered from 1 to *n*. Each employee either has no immediate manager or exactly one immediate manager, who is another employee with a different number. An employee *A* is said to be the superior of another employee *B* if at least one of the following is true:
- Employee *A* is the immediate manager of employee *B* - Employee *B* has an immediate manager employee *C* such that employee *A* is the superior of employee *C*.
The company will not have a managerial cycle. That is, there will not exist an employee who is the superior of his/her own immediate manager.
Today the company is going to arrange a party. This involves dividing all *n* employees into several groups: every employee must belong to exactly one group. Furthermore, within any single group, there must not be two employees *A* and *B* such that *A* is the superior of *B*.
What is the minimum number of groups that must be formed?
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=2000) — the number of employees.
The next *n* lines contain the integers *p**i* (1<=≤<=*p**i*<=≤<=*n* or *p**i*<==<=-1). Every *p**i* denotes the immediate manager for the *i*-th employee. If *p**i* is -1, that means that the *i*-th employee does not have an immediate manager.
It is guaranteed, that no employee will be the immediate manager of him/herself (*p**i*<=≠<=*i*). Also, there will be no managerial cycles.
Output Specification:
Print a single integer denoting the minimum number of groups that will be formed in the party.
Demo Input:
['5\n-1\n1\n2\n1\n-1\n']
Demo Output:
['3\n']
Note:
For the first example, three groups are sufficient, for example:
- Employee 1 - Employees 2 and 4 - Employees 3 and 5
|
```python
from collections import defaultdict, deque
n = int(input())
adj_list = defaultdict(list)
for i in range(1, n+1):
cur = int(input())
adj_list[cur].append(i)
q = deque(adj_list[-1])
level = 0
ans = 0
while q:
size = len(q)
ans = max(ans, size)
level+=1
for i_ in range(size):
top = q.popleft()
if top in adj_list:
q.extend(adj_list[top])
print(level)
```
| 3
|
|
82
|
A
|
Double Cola
|
PROGRAMMING
| 1,100
|
[
"implementation",
"math"
] |
A. Double Cola
|
1
|
256
|
Sheldon, Leonard, Penny, Rajesh and Howard are in the queue for a "Double Cola" drink vending machine; there are no other people in the queue. The first one in the queue (Sheldon) buys a can, drinks it and doubles! The resulting two Sheldons go to the end of the queue. Then the next in the queue (Leonard) buys a can, drinks it and gets to the end of the queue as two Leonards, and so on. This process continues ad infinitum.
For example, Penny drinks the third can of cola and the queue will look like this: Rajesh, Howard, Sheldon, Sheldon, Leonard, Leonard, Penny, Penny.
Write a program that will print the name of a man who will drink the *n*-th can.
Note that in the very beginning the queue looks like that: Sheldon, Leonard, Penny, Rajesh, Howard. The first person is Sheldon.
|
The input data consist of a single integer *n* (1<=≤<=*n*<=≤<=109).
It is guaranteed that the pretests check the spelling of all the five names, that is, that they contain all the five possible answers.
|
Print the single line — the name of the person who drinks the *n*-th can of cola. The cans are numbered starting from 1. Please note that you should spell the names like this: "Sheldon", "Leonard", "Penny", "Rajesh", "Howard" (without the quotes). In that order precisely the friends are in the queue initially.
|
[
"1\n",
"6\n",
"1802\n"
] |
[
"Sheldon\n",
"Sheldon\n",
"Penny\n"
] |
none
| 500
|
[
{
"input": "1",
"output": "Sheldon"
},
{
"input": "6",
"output": "Sheldon"
},
{
"input": "1802",
"output": "Penny"
},
{
"input": "1",
"output": "Sheldon"
},
{
"input": "2",
"output": "Leonard"
},
{
"input": "3",
"output": "Penny"
},
{
"input": "4",
"output": "Rajesh"
},
{
"input": "5",
"output": "Howard"
},
{
"input": "10",
"output": "Penny"
},
{
"input": "534",
"output": "Rajesh"
},
{
"input": "5033",
"output": "Howard"
},
{
"input": "10010",
"output": "Howard"
},
{
"input": "500000000",
"output": "Penny"
},
{
"input": "63",
"output": "Rajesh"
},
{
"input": "841",
"output": "Leonard"
},
{
"input": "3667",
"output": "Penny"
},
{
"input": "38614",
"output": "Howard"
},
{
"input": "282798",
"output": "Rajesh"
},
{
"input": "9266286",
"output": "Rajesh"
},
{
"input": "27385966",
"output": "Leonard"
},
{
"input": "121580142",
"output": "Penny"
},
{
"input": "5",
"output": "Howard"
},
{
"input": "300",
"output": "Howard"
},
{
"input": "1745",
"output": "Leonard"
},
{
"input": "8302",
"output": "Rajesh"
},
{
"input": "184518",
"output": "Sheldon"
},
{
"input": "1154414",
"output": "Rajesh"
},
{
"input": "28643950",
"output": "Leonard"
},
{
"input": "159222638",
"output": "Howard"
},
{
"input": "24",
"output": "Penny"
},
{
"input": "505",
"output": "Penny"
},
{
"input": "4425",
"output": "Rajesh"
},
{
"input": "12079",
"output": "Sheldon"
},
{
"input": "469726",
"output": "Penny"
},
{
"input": "3961838",
"output": "Penny"
},
{
"input": "57710446",
"output": "Leonard"
},
{
"input": "80719470",
"output": "Howard"
},
{
"input": "1000000000",
"output": "Penny"
},
{
"input": "999999999",
"output": "Penny"
},
{
"input": "999999998",
"output": "Penny"
},
{
"input": "5",
"output": "Howard"
}
] | 1,578,794,664
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 41
| 109
| 512,000
|
n=int(input())
if n==1:
print('Sheldon')
elif n==2:
print('Leonard')
elif n==3:
print('Penny')
elif n==4:
print('Rajesh')
elif n==5:
print('Howard')
else:
s=5
i=1
while True:
m=2**i
if n<=s+m:
print('Sheldon')
break
elif n<=s+m*2:
print('Leonard')
break
elif n<=s+m*3:
print('Penny')
break
elif n<=s+m*4:
print('Rajesh')
break
elif n<=s+m*5:
print('Howard')
break
s=s+5*2**i
i=i+1
|
Title: Double Cola
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
Sheldon, Leonard, Penny, Rajesh and Howard are in the queue for a "Double Cola" drink vending machine; there are no other people in the queue. The first one in the queue (Sheldon) buys a can, drinks it and doubles! The resulting two Sheldons go to the end of the queue. Then the next in the queue (Leonard) buys a can, drinks it and gets to the end of the queue as two Leonards, and so on. This process continues ad infinitum.
For example, Penny drinks the third can of cola and the queue will look like this: Rajesh, Howard, Sheldon, Sheldon, Leonard, Leonard, Penny, Penny.
Write a program that will print the name of a man who will drink the *n*-th can.
Note that in the very beginning the queue looks like that: Sheldon, Leonard, Penny, Rajesh, Howard. The first person is Sheldon.
Input Specification:
The input data consist of a single integer *n* (1<=≤<=*n*<=≤<=109).
It is guaranteed that the pretests check the spelling of all the five names, that is, that they contain all the five possible answers.
Output Specification:
Print the single line — the name of the person who drinks the *n*-th can of cola. The cans are numbered starting from 1. Please note that you should spell the names like this: "Sheldon", "Leonard", "Penny", "Rajesh", "Howard" (without the quotes). In that order precisely the friends are in the queue initially.
Demo Input:
['1\n', '6\n', '1802\n']
Demo Output:
['Sheldon\n', 'Sheldon\n', 'Penny\n']
Note:
none
|
```python
n=int(input())
if n==1:
print('Sheldon')
elif n==2:
print('Leonard')
elif n==3:
print('Penny')
elif n==4:
print('Rajesh')
elif n==5:
print('Howard')
else:
s=5
i=1
while True:
m=2**i
if n<=s+m:
print('Sheldon')
break
elif n<=s+m*2:
print('Leonard')
break
elif n<=s+m*3:
print('Penny')
break
elif n<=s+m*4:
print('Rajesh')
break
elif n<=s+m*5:
print('Howard')
break
s=s+5*2**i
i=i+1
```
| 3.944546
|
837
|
A
|
Text Volume
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
You are given a text of single-space separated words, consisting of small and capital Latin letters.
Volume of the word is number of capital letters in the word. Volume of the text is maximum volume of all words in the text.
Calculate the volume of the given text.
|
The first line contains one integer number *n* (1<=≤<=*n*<=≤<=200) — length of the text.
The second line contains text of single-space separated words *s*1,<=*s*2,<=...,<=*s**i*, consisting only of small and capital Latin letters.
|
Print one integer number — volume of text.
|
[
"7\nNonZERO\n",
"24\nthis is zero answer text\n",
"24\nHarbour Space University\n"
] |
[
"5\n",
"0\n",
"1\n"
] |
In the first example there is only one word, there are 5 capital letters in it.
In the second example all of the words contain 0 capital letters.
| 0
|
[
{
"input": "7\nNonZERO",
"output": "5"
},
{
"input": "24\nthis is zero answer text",
"output": "0"
},
{
"input": "24\nHarbour Space University",
"output": "1"
},
{
"input": "2\nWM",
"output": "2"
},
{
"input": "200\nLBmJKQLCKUgtTxMoDsEerwvLOXsxASSydOqWyULsRcjMYDWdDCgaDvBfATIWPVSXlbcCLHPYahhxMEYUiaxoCebghJqvmRnaNHYTKLeOiaLDnATPZAOgSNfBzaxLymTGjfzvTegbXsAthTxyDTcmBUkqyGlVGZhoazQzVSoKbTFcCRvYsgSCwjGMxBfWEwMHuagTBxkz",
"output": "105"
},
{
"input": "199\no A r v H e J q k J k v w Q F p O R y R Z o a K R L Z E H t X y X N y y p b x B m r R S q i A x V S u i c L y M n N X c C W Z m S j e w C w T r I S X T D F l w o k f t X u n W w p Z r A k I Y E h s g",
"output": "1"
},
{
"input": "200\nhCyIdivIiISmmYIsCLbpKcTyHaOgTUQEwnQACXnrLdHAVFLtvliTEMlzBVzTesQbhXmcqvwPDeojglBMIjOXANfyQxCSjOJyO SIqOTnRzVzseGIDDYNtrwIusScWSuEhPyEmgQIVEzXofRptjeMzzhtUQxJgcUWILUhEaaRmYRBVsjoqgmyPIKwSajdlNPccOOtWrez",
"output": "50"
},
{
"input": "1\ne",
"output": "0"
},
{
"input": "1\nA",
"output": "1"
},
{
"input": "200\nABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ ABCDEFGHIJ KLMNOPRSTU KLMNOPRSTU KLMNOPRSTU VWXYZABCDE KLMNOPRSTU KLMNOPRSTU KLMNOPRSTU KLMNOPRSTU KZ",
"output": "10"
},
{
"input": "200\nAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA",
"output": "200"
},
{
"input": "200\nffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff",
"output": "0"
},
{
"input": "24\nHarbour Space UniversitY",
"output": "2"
},
{
"input": "5\naA AA",
"output": "2"
},
{
"input": "10\nas AS ASDA",
"output": "4"
},
{
"input": "10\nas AS ASDZ",
"output": "4"
},
{
"input": "3\na A",
"output": "1"
},
{
"input": "24\nHarbour space UniversitY",
"output": "2"
},
{
"input": "10\nas AS ASAa",
"output": "3"
},
{
"input": "15\naAb ABCDFGRHTJS",
"output": "11"
},
{
"input": "53\nsdfAZEZR AZE dfdf dsdRFGSDF ZZDZSD dfsd ERBGF dsfsdfR",
"output": "6"
},
{
"input": "10\nABC ABc AB",
"output": "3"
},
{
"input": "10\nA c de CDE",
"output": "3"
},
{
"input": "4\nA AB",
"output": "2"
},
{
"input": "18\nHARbour Space UNIV",
"output": "4"
},
{
"input": "13\na b c d e f A",
"output": "1"
},
{
"input": "6\nA B CA",
"output": "2"
},
{
"input": "4\naa A",
"output": "1"
},
{
"input": "3\nA a",
"output": "1"
}
] | 1,553,526,111
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 108
| 0
|
input()
S= input()
an=0
for s in S:
if ord(s) >= 65 and ord(s) <= 90:
an += 1
print(an)
|
Title: Text Volume
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given a text of single-space separated words, consisting of small and capital Latin letters.
Volume of the word is number of capital letters in the word. Volume of the text is maximum volume of all words in the text.
Calculate the volume of the given text.
Input Specification:
The first line contains one integer number *n* (1<=≤<=*n*<=≤<=200) — length of the text.
The second line contains text of single-space separated words *s*1,<=*s*2,<=...,<=*s**i*, consisting only of small and capital Latin letters.
Output Specification:
Print one integer number — volume of text.
Demo Input:
['7\nNonZERO\n', '24\nthis is zero answer text\n', '24\nHarbour Space University\n']
Demo Output:
['5\n', '0\n', '1\n']
Note:
In the first example there is only one word, there are 5 capital letters in it.
In the second example all of the words contain 0 capital letters.
|
```python
input()
S= input()
an=0
for s in S:
if ord(s) >= 65 and ord(s) <= 90:
an += 1
print(an)
```
| 0
|
|
37
|
A
|
Towers
|
PROGRAMMING
| 1,000
|
[
"sortings"
] |
A. Towers
|
2
|
256
|
Little Vasya has received a young builder’s kit. The kit consists of several wooden bars, the lengths of all of them are known. The bars can be put one on the top of the other if their lengths are the same.
Vasya wants to construct the minimal number of towers from the bars. Help Vasya to use the bars in the best way possible.
|
The first line contains an integer *N* (1<=≤<=*N*<=≤<=1000) — the number of bars at Vasya’s disposal. The second line contains *N* space-separated integers *l**i* — the lengths of the bars. All the lengths are natural numbers not exceeding 1000.
|
In one line output two numbers — the height of the largest tower and their total number. Remember that Vasya should use all the bars.
|
[
"3\n1 2 3\n",
"4\n6 5 6 7\n"
] |
[
"1 3\n",
"2 3\n"
] |
none
| 500
|
[
{
"input": "3\n1 2 3",
"output": "1 3"
},
{
"input": "4\n6 5 6 7",
"output": "2 3"
},
{
"input": "4\n3 2 1 1",
"output": "2 3"
},
{
"input": "4\n1 2 3 3",
"output": "2 3"
},
{
"input": "3\n20 22 36",
"output": "1 3"
},
{
"input": "25\n47 30 94 41 45 20 96 51 110 129 24 116 9 47 32 82 105 114 116 75 154 151 70 42 162",
"output": "2 23"
},
{
"input": "45\n802 664 442 318 318 827 417 878 711 291 231 414 807 553 657 392 279 202 386 606 465 655 658 112 887 15 25 502 95 44 679 775 942 609 209 871 31 234 4 231 150 110 22 823 193",
"output": "2 43"
},
{
"input": "63\n93 180 116 7 8 179 268 279 136 94 221 153 264 190 278 19 19 63 153 26 158 225 25 49 89 218 111 149 255 225 197 122 243 80 3 224 107 178 202 17 53 92 69 42 228 24 81 205 95 8 265 82 228 156 127 241 172 159 106 60 67 155 111",
"output": "2 57"
},
{
"input": "83\n246 535 994 33 390 927 321 97 223 922 812 705 79 80 977 457 476 636 511 137 6 360 815 319 717 674 368 551 714 628 278 713 761 553 184 414 623 753 428 214 581 115 439 61 677 216 772 592 187 603 658 310 439 559 870 376 109 321 189 337 277 26 70 734 796 907 979 693 570 227 345 650 737 633 701 914 134 403 972 940 371 6 642",
"output": "2 80"
},
{
"input": "105\n246 57 12 204 165 123 246 68 191 310 3 152 386 333 374 257 158 104 333 50 80 290 8 340 101 76 221 316 388 289 138 359 316 26 93 290 105 178 81 195 41 196 218 180 244 292 187 97 315 323 174 119 248 239 92 312 31 2 101 180 307 170 338 314 163 281 217 31 142 238 280 190 190 156 70 74 329 113 151 8 141 313 366 40 253 116 168 124 135 230 294 266 353 389 371 359 195 200 183 237 93 102 315 118 188",
"output": "2 92"
},
{
"input": "123\n112 277 170 247 252 115 157 293 256 143 196 90 12 164 164 42 8 223 167 109 175 232 239 111 148 51 9 254 93 32 268 162 231 91 47 162 161 191 195 145 247 292 129 199 230 94 144 217 18 205 176 20 143 198 121 243 211 262 230 277 195 255 108 290 220 275 158 2 286 200 60 267 278 207 123 150 123 116 131 13 12 226 33 244 30 275 263 45 158 192 254 149 242 176 62 224 221 288 250 160 155 225 132 143 276 293 218 145 197 175 33 129 79 206 210 192 222 262 190 52 274 243 233",
"output": "3 101"
},
{
"input": "5\n5 5 5 5 5",
"output": "5 1"
},
{
"input": "3\n1000 1000 1000",
"output": "3 1"
},
{
"input": "1\n1000",
"output": "1 1"
},
{
"input": "1\n1",
"output": "1 1"
},
{
"input": "5\n1 1000 1000 1000 1000",
"output": "4 2"
},
{
"input": "5\n1000 1000 1000 8 7",
"output": "3 3"
}
] | 1,590,593,635
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 186
| 0
|
n=int(input())
a=[int(i) for i in input().split()]
b=list(set(a))
c=[]
d=[]
for i in range(n):
c.append(a.count(a[i]))
for i in range(n):
d.append(a[i]*c[i])
m=max(d)
p=d.index(m)
print(c[p],len(b))
|
Title: Towers
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Little Vasya has received a young builder’s kit. The kit consists of several wooden bars, the lengths of all of them are known. The bars can be put one on the top of the other if their lengths are the same.
Vasya wants to construct the minimal number of towers from the bars. Help Vasya to use the bars in the best way possible.
Input Specification:
The first line contains an integer *N* (1<=≤<=*N*<=≤<=1000) — the number of bars at Vasya’s disposal. The second line contains *N* space-separated integers *l**i* — the lengths of the bars. All the lengths are natural numbers not exceeding 1000.
Output Specification:
In one line output two numbers — the height of the largest tower and their total number. Remember that Vasya should use all the bars.
Demo Input:
['3\n1 2 3\n', '4\n6 5 6 7\n']
Demo Output:
['1 3\n', '2 3\n']
Note:
none
|
```python
n=int(input())
a=[int(i) for i in input().split()]
b=list(set(a))
c=[]
d=[]
for i in range(n):
c.append(a.count(a[i]))
for i in range(n):
d.append(a[i]*c[i])
m=max(d)
p=d.index(m)
print(c[p],len(b))
```
| 0
|
801
|
A
|
Vicious Keyboard
|
PROGRAMMING
| 1,100
|
[
"brute force"
] | null | null |
Tonio has a keyboard with only two letters, "V" and "K".
One day, he has typed out a string *s* with only these two letters. He really likes it when the string "VK" appears, so he wishes to change at most one letter in the string (or do no changes) to maximize the number of occurrences of that string. Compute the maximum number of times "VK" can appear as a substring (i. e. a letter "K" right after a letter "V") in the resulting string.
|
The first line will contain a string *s* consisting only of uppercase English letters "V" and "K" with length not less than 1 and not greater than 100.
|
Output a single integer, the maximum number of times "VK" can appear as a substring of the given string after changing at most one character.
|
[
"VK\n",
"VV\n",
"V\n",
"VKKKKKKKKKVVVVVVVVVK\n",
"KVKV\n"
] |
[
"1\n",
"1\n",
"0\n",
"3\n",
"1\n"
] |
For the first case, we do not change any letters. "VK" appears once, which is the maximum number of times it could appear.
For the second case, we can change the second character from a "V" to a "K". This will give us the string "VK". This has one occurrence of the string "VK" as a substring.
For the fourth case, we can change the fourth character from a "K" to a "V". This will give us the string "VKKVKKKKKKVVVVVVVVVK". This has three occurrences of the string "VK" as a substring. We can check no other moves can give us strictly more occurrences.
| 500
|
[
{
"input": "VK",
"output": "1"
},
{
"input": "VV",
"output": "1"
},
{
"input": "V",
"output": "0"
},
{
"input": "VKKKKKKKKKVVVVVVVVVK",
"output": "3"
},
{
"input": "KVKV",
"output": "1"
},
{
"input": "VKKVVVKVKVK",
"output": "5"
},
{
"input": "VKVVKVKVVKVKKKKVVVVVVVVKVKVVVVVVKKVKKVKVVKVKKVVVVKV",
"output": "14"
},
{
"input": "VVKKVKKVVKKVKKVKVVKKVKKVVKKVKVVKKVKKVKVVKKVVKKVKVVKKVKVVKKVVKVVKKVKKVKKVKKVKKVKVVKKVKKVKKVKKVKKVVKVK",
"output": "32"
},
{
"input": "KVVKKVKVKVKVKVKKVKVKVVKVKVVKVVKVKKVKVKVKVKVKVKVKVKVKVKVKVKVKVKVVKVKVVKKVKVKK",
"output": "32"
},
{
"input": "KVVVVVKKVKVVKVVVKVVVKKKVKKKVVKVKKKVKKKKVKVVVVVKKKVVVVKKVVVVKKKVKVVVVVVVKKVKVKKKVVKVVVKVVKK",
"output": "21"
},
{
"input": "VVVVVKKVKVKVKVVKVVKKVVKVKKKKKKKVKKKVVVVVVKKVVVKVKVVKVKKVVKVVVKKKKKVVVVVKVVVVKVVVKKVKKVKKKVKKVKKVVKKV",
"output": "25"
},
{
"input": "KKVVKVVKVVKKVVKKVKVVKKV",
"output": "7"
},
{
"input": "KKVVKKVVVKKVKKVKKVVVKVVVKKVKKVVVKKVVVKVVVKVVVKKVVVKKVVVKVVVKKVVVKVVKKVVVKKVVVKKVVKVVVKKVVKKVKKVVVKKV",
"output": "24"
},
{
"input": "KVKVKVKVKVKVKVKVKVKVVKVKVKVKVKVKVKVVKVKVKKVKVKVKVKVVKVKVKVKVKVKVKVKVKKVKVKVV",
"output": "35"
},
{
"input": "VKVVVKKKVKVVKVKVKVKVKVV",
"output": "9"
},
{
"input": "KKKKVKKVKVKVKKKVVVVKK",
"output": "6"
},
{
"input": "KVKVKKVVVVVVKKKVKKKKVVVVKVKKVKVVK",
"output": "9"
},
{
"input": "KKVKKVKKKVKKKVKKKVKVVVKKVVVVKKKVKKVVKVKKVKVKVKVVVKKKVKKKKKVVKVVKVVVKKVVKVVKKKKKVK",
"output": "22"
},
{
"input": "VVVKVKVKVVVVVKVVVKKVVVKVVVVVKKVVKVVVKVVVKVKKKVVKVVVVVKVVVVKKVVKVKKVVKKKVKVVKVKKKKVVKVVVKKKVKVKKKKKK",
"output": "25"
},
{
"input": "VKVVKVVKKKVVKVKKKVVKKKVVKVVKVVKKVKKKVKVKKKVVKVKKKVVKVVKKKVVKKKVKKKVVKKVVKKKVKVKKKVKKKVKKKVKVKKKVVKVK",
"output": "29"
},
{
"input": "KKVKVVVKKVV",
"output": "3"
},
{
"input": "VKVKVKVKVKVKVKVKVKVKVVKVKVKVKVKVK",
"output": "16"
},
{
"input": "VVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVVKKKVV",
"output": "13"
},
{
"input": "VVKKVKVKKKVVVKVVVKVKKVKKKVVVKVVKVKKVKKVKVKVVKKVVKKVKVVKKKVVKKVVVKVKVVVKVKVVKVKKVKKV",
"output": "26"
},
{
"input": "VVKVKKVVKKVVKKVVKKVVKKVKKVVKVKKVVKKVVKKVVKKVVKKVVKVVKKVVKVVKKVVKVVKKVVKKVKKVVKVVKKVVKVVKKVV",
"output": "26"
},
{
"input": "K",
"output": "0"
},
{
"input": "VKVK",
"output": "2"
},
{
"input": "VKVV",
"output": "2"
},
{
"input": "KV",
"output": "0"
},
{
"input": "KK",
"output": "1"
},
{
"input": "KKVK",
"output": "2"
},
{
"input": "KKKK",
"output": "1"
},
{
"input": "KKV",
"output": "1"
},
{
"input": "KKVKVK",
"output": "3"
},
{
"input": "VKKVK",
"output": "2"
},
{
"input": "VKKK",
"output": "2"
},
{
"input": "KKK",
"output": "1"
},
{
"input": "KVV",
"output": "1"
},
{
"input": "KKVKV",
"output": "2"
},
{
"input": "VVK",
"output": "1"
},
{
"input": "VVVKVKVKVKVKVKVK",
"output": "8"
},
{
"input": "KVVVK",
"output": "2"
},
{
"input": "VVVKK",
"output": "2"
},
{
"input": "KKVV",
"output": "1"
},
{
"input": "KKKKKKK",
"output": "1"
},
{
"input": "VKKKVK",
"output": "3"
},
{
"input": "KKVVV",
"output": "1"
},
{
"input": "VVVVVV",
"output": "1"
},
{
"input": "KKKV",
"output": "1"
},
{
"input": "VVKVV",
"output": "2"
},
{
"input": "VKVKKK",
"output": "3"
},
{
"input": "VKKV",
"output": "1"
},
{
"input": "VKKVV",
"output": "2"
},
{
"input": "VVKKVV",
"output": "2"
},
{
"input": "KKVVKKV",
"output": "2"
},
{
"input": "KKKKK",
"output": "1"
},
{
"input": "VKVVKKVKKVVKVKKVKKKVKKVKVKK",
"output": "10"
},
{
"input": "VKVKVV",
"output": "3"
},
{
"input": "VKVVKVV",
"output": "3"
},
{
"input": "VVV",
"output": "1"
},
{
"input": "VVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVV",
"output": "1"
},
{
"input": "VVKKKKKKVKK",
"output": "3"
},
{
"input": "KVKVKVV",
"output": "3"
}
] | 1,498,808,311
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 5
| 46
| 5,529,600
|
s=input()
l=len(s)
x,c=0,0
for i in range(0,l-1):
w=s[i:i+2]
if w=="VK":
x+=1
if w=="VV" or w=="KK":
c+=1
for i in range(0,l-2):
w=s[i:i+3]
if w=="VKK" or w=="KKV" or w=="VVK" or w=="KVV":
c-=1
if c>0:
x+=1
print(x)
|
Title: Vicious Keyboard
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Tonio has a keyboard with only two letters, "V" and "K".
One day, he has typed out a string *s* with only these two letters. He really likes it when the string "VK" appears, so he wishes to change at most one letter in the string (or do no changes) to maximize the number of occurrences of that string. Compute the maximum number of times "VK" can appear as a substring (i. e. a letter "K" right after a letter "V") in the resulting string.
Input Specification:
The first line will contain a string *s* consisting only of uppercase English letters "V" and "K" with length not less than 1 and not greater than 100.
Output Specification:
Output a single integer, the maximum number of times "VK" can appear as a substring of the given string after changing at most one character.
Demo Input:
['VK\n', 'VV\n', 'V\n', 'VKKKKKKKKKVVVVVVVVVK\n', 'KVKV\n']
Demo Output:
['1\n', '1\n', '0\n', '3\n', '1\n']
Note:
For the first case, we do not change any letters. "VK" appears once, which is the maximum number of times it could appear.
For the second case, we can change the second character from a "V" to a "K". This will give us the string "VK". This has one occurrence of the string "VK" as a substring.
For the fourth case, we can change the fourth character from a "K" to a "V". This will give us the string "VKKVKKKKKKVVVVVVVVVK". This has three occurrences of the string "VK" as a substring. We can check no other moves can give us strictly more occurrences.
|
```python
s=input()
l=len(s)
x,c=0,0
for i in range(0,l-1):
w=s[i:i+2]
if w=="VK":
x+=1
if w=="VV" or w=="KK":
c+=1
for i in range(0,l-2):
w=s[i:i+3]
if w=="VKK" or w=="KKV" or w=="VVK" or w=="KVV":
c-=1
if c>0:
x+=1
print(x)
```
| 0
|
|
251
|
A
|
Points on Line
|
PROGRAMMING
| 1,300
|
[
"binary search",
"combinatorics",
"two pointers"
] | null | null |
Little Petya likes points a lot. Recently his mom has presented him *n* points lying on the line *OX*. Now Petya is wondering in how many ways he can choose three distinct points so that the distance between the two farthest of them doesn't exceed *d*.
Note that the order of the points inside the group of three chosen points doesn't matter.
|
The first line contains two integers: *n* and *d* (1<=≤<=*n*<=≤<=105; 1<=≤<=*d*<=≤<=109). The next line contains *n* integers *x*1,<=*x*2,<=...,<=*x**n*, their absolute value doesn't exceed 109 — the *x*-coordinates of the points that Petya has got.
It is guaranteed that the coordinates of the points in the input strictly increase.
|
Print a single integer — the number of groups of three points, where the distance between two farthest points doesn't exceed *d*.
Please do not use the %lld specifier to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams or the %I64d specifier.
|
[
"4 3\n1 2 3 4\n",
"4 2\n-3 -2 -1 0\n",
"5 19\n1 10 20 30 50\n"
] |
[
"4\n",
"2\n",
"1\n"
] |
In the first sample any group of three points meets our conditions.
In the seconds sample only 2 groups of three points meet our conditions: {-3, -2, -1} and {-2, -1, 0}.
In the third sample only one group does: {1, 10, 20}.
| 500
|
[
{
"input": "4 3\n1 2 3 4",
"output": "4"
},
{
"input": "4 2\n-3 -2 -1 0",
"output": "2"
},
{
"input": "5 19\n1 10 20 30 50",
"output": "1"
},
{
"input": "10 5\n31 36 43 47 48 50 56 69 71 86",
"output": "2"
},
{
"input": "10 50\n1 4 20 27 65 79 82 83 99 100",
"output": "25"
},
{
"input": "10 90\n24 27 40 41 61 69 73 87 95 97",
"output": "120"
},
{
"input": "100 100\n-98 -97 -96 -93 -92 -91 -90 -87 -86 -84 -81 -80 -79 -78 -76 -75 -73 -71 -69 -67 -65 -64 -63 -62 -61 -54 -51 -50 -49 -48 -46 -45 -44 -37 -36 -33 -30 -28 -27 -16 -15 -13 -12 -10 -9 -7 -6 -5 -4 2 3 5 8 9 10 11 13 14 15 16 17 19 22 24 25 26 27 28 30 31 32 36 40 43 45 46 47 50 51 52 53 58 60 63 69 70 73 78 80 81 82 85 88 89 90 91 95 96 97 99",
"output": "79351"
},
{
"input": "1 14751211\n847188590",
"output": "0"
},
{
"input": "2 1000000000\n-907894512 -289906312",
"output": "0"
},
{
"input": "2 1000000000\n-14348867 1760823",
"output": "0"
},
{
"input": "3 1000000000\n-5 -1 1",
"output": "1"
}
] | 1,510,088,583
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 9
| 2,000
| 614,400
|
n,d=map(int,input().split())
l=list(map(int,input().split()))
ans=0
for i in range(n):
j=0
while(j<n and l[j]<=l[i]+d):
j+=1
ans+=((j-i-1)*(j-i-2)//2)
print(ans)
|
Title: Points on Line
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Little Petya likes points a lot. Recently his mom has presented him *n* points lying on the line *OX*. Now Petya is wondering in how many ways he can choose three distinct points so that the distance between the two farthest of them doesn't exceed *d*.
Note that the order of the points inside the group of three chosen points doesn't matter.
Input Specification:
The first line contains two integers: *n* and *d* (1<=≤<=*n*<=≤<=105; 1<=≤<=*d*<=≤<=109). The next line contains *n* integers *x*1,<=*x*2,<=...,<=*x**n*, their absolute value doesn't exceed 109 — the *x*-coordinates of the points that Petya has got.
It is guaranteed that the coordinates of the points in the input strictly increase.
Output Specification:
Print a single integer — the number of groups of three points, where the distance between two farthest points doesn't exceed *d*.
Please do not use the %lld specifier to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams or the %I64d specifier.
Demo Input:
['4 3\n1 2 3 4\n', '4 2\n-3 -2 -1 0\n', '5 19\n1 10 20 30 50\n']
Demo Output:
['4\n', '2\n', '1\n']
Note:
In the first sample any group of three points meets our conditions.
In the seconds sample only 2 groups of three points meet our conditions: {-3, -2, -1} and {-2, -1, 0}.
In the third sample only one group does: {1, 10, 20}.
|
```python
n,d=map(int,input().split())
l=list(map(int,input().split()))
ans=0
for i in range(n):
j=0
while(j<n and l[j]<=l[i]+d):
j+=1
ans+=((j-i-1)*(j-i-2)//2)
print(ans)
```
| 0
|
|
4
|
A
|
Watermelon
|
PROGRAMMING
| 800
|
[
"brute force",
"math"
] |
A. Watermelon
|
1
|
64
|
One hot summer day Pete and his friend Billy decided to buy a watermelon. They chose the biggest and the ripest one, in their opinion. After that the watermelon was weighed, and the scales showed *w* kilos. They rushed home, dying of thirst, and decided to divide the berry, however they faced a hard problem.
Pete and Billy are great fans of even numbers, that's why they want to divide the watermelon in such a way that each of the two parts weighs even number of kilos, at the same time it is not obligatory that the parts are equal. The boys are extremely tired and want to start their meal as soon as possible, that's why you should help them and find out, if they can divide the watermelon in the way they want. For sure, each of them should get a part of positive weight.
|
The first (and the only) input line contains integer number *w* (1<=≤<=*w*<=≤<=100) — the weight of the watermelon bought by the boys.
|
Print YES, if the boys can divide the watermelon into two parts, each of them weighing even number of kilos; and NO in the opposite case.
|
[
"8\n"
] |
[
"YES\n"
] |
For example, the boys can divide the watermelon into two parts of 2 and 6 kilos respectively (another variant — two parts of 4 and 4 kilos).
| 0
|
[
{
"input": "8",
"output": "YES"
},
{
"input": "5",
"output": "NO"
},
{
"input": "4",
"output": "YES"
},
{
"input": "3",
"output": "NO"
},
{
"input": "2",
"output": "NO"
},
{
"input": "1",
"output": "NO"
},
{
"input": "7",
"output": "NO"
},
{
"input": "6",
"output": "YES"
},
{
"input": "10",
"output": "YES"
},
{
"input": "9",
"output": "NO"
},
{
"input": "53",
"output": "NO"
},
{
"input": "77",
"output": "NO"
},
{
"input": "32",
"output": "YES"
},
{
"input": "44",
"output": "YES"
},
{
"input": "98",
"output": "YES"
},
{
"input": "99",
"output": "NO"
},
{
"input": "90",
"output": "YES"
},
{
"input": "67",
"output": "NO"
},
{
"input": "100",
"output": "YES"
},
{
"input": "88",
"output": "YES"
}
] | 1,693,057,290
| 3,690
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 60
| 0
|
w = input()
if w != 2 and (w % 2) == 0:
print("YES")
else:
print("NO")
|
Title: Watermelon
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
One hot summer day Pete and his friend Billy decided to buy a watermelon. They chose the biggest and the ripest one, in their opinion. After that the watermelon was weighed, and the scales showed *w* kilos. They rushed home, dying of thirst, and decided to divide the berry, however they faced a hard problem.
Pete and Billy are great fans of even numbers, that's why they want to divide the watermelon in such a way that each of the two parts weighs even number of kilos, at the same time it is not obligatory that the parts are equal. The boys are extremely tired and want to start their meal as soon as possible, that's why you should help them and find out, if they can divide the watermelon in the way they want. For sure, each of them should get a part of positive weight.
Input Specification:
The first (and the only) input line contains integer number *w* (1<=≤<=*w*<=≤<=100) — the weight of the watermelon bought by the boys.
Output Specification:
Print YES, if the boys can divide the watermelon into two parts, each of them weighing even number of kilos; and NO in the opposite case.
Demo Input:
['8\n']
Demo Output:
['YES\n']
Note:
For example, the boys can divide the watermelon into two parts of 2 and 6 kilos respectively (another variant — two parts of 4 and 4 kilos).
|
```python
w = input()
if w != 2 and (w % 2) == 0:
print("YES")
else:
print("NO")
```
| -1
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Natasha is going to fly on a rocket to Mars and return to Earth. Also, on the way to Mars, she will land on $n - 2$ intermediate planets. Formally: we number all the planets from $1$ to $n$. $1$ is Earth, $n$ is Mars. Natasha will make exactly $n$ flights: $1 \to 2 \to \ldots n \to 1$.
Flight from $x$ to $y$ consists of two phases: take-off from planet $x$ and landing to planet $y$. This way, the overall itinerary of the trip will be: the $1$-st planet $\to$ take-off from the $1$-st planet $\to$ landing to the $2$-nd planet $\to$ $2$-nd planet $\to$ take-off from the $2$-nd planet $\to$ $\ldots$ $\to$ landing to the $n$-th planet $\to$ the $n$-th planet $\to$ take-off from the $n$-th planet $\to$ landing to the $1$-st planet $\to$ the $1$-st planet.
The mass of the rocket together with all the useful cargo (but without fuel) is $m$ tons. However, Natasha does not know how much fuel to load into the rocket. Unfortunately, fuel can only be loaded on Earth, so if the rocket runs out of fuel on some other planet, Natasha will not be able to return home. Fuel is needed to take-off from each planet and to land to each planet. It is known that $1$ ton of fuel can lift off $a_i$ tons of rocket from the $i$-th planet or to land $b_i$ tons of rocket onto the $i$-th planet.
For example, if the weight of rocket is $9$ tons, weight of fuel is $3$ tons and take-off coefficient is $8$ ($a_i = 8$), then $1.5$ tons of fuel will be burnt (since $1.5 \cdot 8 = 9 + 3$). The new weight of fuel after take-off will be $1.5$ tons.
Please note, that it is allowed to burn non-integral amount of fuel during take-off or landing, and the amount of initial fuel can be non-integral as well.
Help Natasha to calculate the minimum mass of fuel to load into the rocket. Note, that the rocket must spend fuel to carry both useful cargo and the fuel itself. However, it doesn't need to carry the fuel which has already been burnt. Assume, that the rocket takes off and lands instantly.
|
The first line contains a single integer $n$ ($2 \le n \le 1000$) — number of planets.
The second line contains the only integer $m$ ($1 \le m \le 1000$) — weight of the payload.
The third line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($1 \le a_i \le 1000$), where $a_i$ is the number of tons, which can be lifted off by one ton of fuel.
The fourth line contains $n$ integers $b_1, b_2, \ldots, b_n$ ($1 \le b_i \le 1000$), where $b_i$ is the number of tons, which can be landed by one ton of fuel.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
|
If Natasha can fly to Mars through $(n - 2)$ planets and return to Earth, print the minimum mass of fuel (in tons) that Natasha should take. Otherwise, print a single number $-1$.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
The answer will be considered correct if its absolute or relative error doesn't exceed $10^{-6}$. Formally, let your answer be $p$, and the jury's answer be $q$. Your answer is considered correct if $\frac{|p - q|}{\max{(1, |q|)}} \le 10^{-6}$.
|
[
"2\n12\n11 8\n7 5\n",
"3\n1\n1 4 1\n2 5 3\n",
"6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3\n"
] |
[
"10.0000000000\n",
"-1\n",
"85.4800000000\n"
] |
Let's consider the first example.
Initially, the mass of a rocket with fuel is $22$ tons.
- At take-off from Earth one ton of fuel can lift off $11$ tons of cargo, so to lift off $22$ tons you need to burn $2$ tons of fuel. Remaining weight of the rocket with fuel is $20$ tons.- During landing on Mars, one ton of fuel can land $5$ tons of cargo, so for landing $20$ tons you will need to burn $4$ tons of fuel. There will be $16$ tons of the rocket with fuel remaining.- While taking off from Mars, one ton of fuel can raise $8$ tons of cargo, so to lift off $16$ tons you will need to burn $2$ tons of fuel. There will be $14$ tons of rocket with fuel after that.- During landing on Earth, one ton of fuel can land $7$ tons of cargo, so for landing $14$ tons you will need to burn $2$ tons of fuel. Remaining weight is $12$ tons, that is, a rocket without any fuel.
In the second case, the rocket will not be able even to take off from Earth.
| 0
|
[
{
"input": "2\n12\n11 8\n7 5",
"output": "10.0000000000"
},
{
"input": "3\n1\n1 4 1\n2 5 3",
"output": "-1"
},
{
"input": "6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3",
"output": "85.4800000000"
},
{
"input": "3\n3\n1 2 1\n2 2 2",
"output": "-1"
},
{
"input": "4\n4\n2 3 2 2\n2 3 4 3",
"output": "284.0000000000"
},
{
"input": "5\n2\n1 2 2 1 2\n4 5 1 4 1",
"output": "-1"
},
{
"input": "7\n7\n3 2 6 2 2 2 5\n4 7 5 6 2 2 2",
"output": "4697.0000000000"
},
{
"input": "2\n1000\n12 34\n56 78",
"output": "159.2650775220"
},
{
"input": "8\n4\n1 1 4 1 3 1 8 1\n1 1 1 1 1 3 1 2",
"output": "-1"
},
{
"input": "9\n2\n8 7 1 1 3 7 1 2 4\n4 1 1 8 7 7 1 1 5",
"output": "-1"
},
{
"input": "10\n10\n9 8 8 7 2 10 2 9 2 4\n3 10 6 2 6 6 5 9 4 5",
"output": "3075.7142857143"
},
{
"input": "20\n12\n3 9 12 13 16 18 9 9 19 7 2 5 17 14 7 7 15 16 5 7\n16 9 13 5 14 10 4 3 16 16 12 20 17 11 4 5 5 14 6 15",
"output": "4670.8944493007"
},
{
"input": "30\n5\n25 1 28 1 27 25 24 1 28 1 12 1 29 16 1 1 1 1 27 1 24 1 1 1 1 1 1 1 30 3\n1 22 1 1 24 2 13 1 16 21 1 27 14 16 1 1 7 1 1 18 1 23 10 1 15 16 16 15 10 1",
"output": "-1"
},
{
"input": "40\n13\n1 1 1 23 21 1 1 1 1 1 40 32 1 21 1 8 1 1 36 15 33 1 30 1 1 37 22 1 4 39 7 1 9 37 1 1 1 28 1 1\n1 34 17 1 38 20 8 14 1 18 29 3 21 21 18 14 1 11 1 1 23 1 25 1 14 1 7 31 9 20 25 1 1 1 1 8 26 12 1 1",
"output": "-1"
},
{
"input": "50\n19\n17 7 13 42 19 25 10 25 2 36 17 40 30 48 34 43 34 20 5 15 8 7 43 35 21 40 40 19 30 11 49 7 24 23 43 30 38 49 10 8 30 11 28 50 48 25 25 20 48 24\n49 35 10 22 24 50 50 7 6 13 16 35 12 43 50 44 35 33 38 49 26 18 23 37 7 38 23 20 28 48 41 16 6 32 32 34 11 39 38 9 38 23 16 31 37 47 33 20 46 30",
"output": "7832.1821424977"
},
{
"input": "60\n21\n11 35 1 28 39 13 19 56 13 13 21 25 1 1 23 1 52 26 53 1 1 1 30 39 1 7 1 1 3 1 1 10 1 1 37 1 1 25 1 1 1 53 1 3 48 1 6 5 4 15 1 14 25 53 25 38 27 1 1 1\n1 1 1 35 40 58 10 22 1 56 1 59 1 6 33 1 1 1 1 18 14 1 1 40 25 47 1 34 1 1 53 1 1 25 1 45 1 1 25 34 3 1 1 1 53 27 11 58 1 1 1 10 12 1 1 1 31 52 1 1",
"output": "-1"
},
{
"input": "70\n69\n70 66 57 58 24 60 39 2 48 61 65 22 10 26 68 62 48 25 12 14 45 57 6 30 48 15 46 33 42 28 69 42 64 25 24 8 62 12 68 53 55 20 32 70 3 5 41 49 16 26 2 34 34 20 39 65 18 47 62 31 39 28 61 67 7 14 31 31 53 54\n40 33 24 20 68 20 22 39 53 56 48 38 59 45 47 46 7 69 11 58 61 40 35 38 62 66 18 36 44 48 67 24 14 27 67 63 68 30 50 6 58 7 6 35 20 58 6 12 12 23 14 2 63 27 29 22 49 16 55 40 70 27 27 70 42 38 66 55 69 47",
"output": "217989.4794743629"
},
{
"input": "80\n21\n65 4 26 25 1 1 1 1 1 1 60 1 29 43 48 6 48 13 29 1 1 62 1 1 1 1 1 1 1 26 9 1 22 1 35 13 66 36 1 1 1 38 55 21 70 1 58 70 1 1 38 1 1 20 1 1 51 1 1 28 1 23 11 1 39 47 1 52 41 1 63 1 1 52 1 45 11 10 80 1\n1 1 25 30 1 1 55 54 1 48 10 37 22 1 74 1 78 13 1 65 32 1 1 1 1 69 5 59 1 1 65 1 40 1 31 1 1 75 54 1 60 1 1 1 1 1 1 1 11 29 36 1 72 71 52 1 1 1 37 1 1 75 43 9 53 1 62 1 29 1 40 27 59 74 41 53 19 30 1 73",
"output": "-1"
},
{
"input": "90\n35\n1 68 16 30 24 1 1 1 35 1 1 67 1 1 1 1 33 16 37 77 83 1 77 26 1 1 68 67 70 62 1 47 1 1 1 84 1 65 1 32 83 1 1 1 28 1 71 76 84 1 1 5 1 74 10 1 1 1 38 87 13 1 7 66 81 49 1 9 1 11 1 25 1 1 1 1 7 1 1 36 61 47 51 1 1 69 40 1 37 1\n40 1 21 1 19 51 37 52 64 1 86 1 5 24 1 1 1 19 36 1 1 77 24 4 1 18 89 1 1 1 1 1 29 22 1 80 32 36 6 1 63 1 30 1 1 1 86 79 73 52 9 1 1 11 7 1 25 20 1 20 1 49 1 37 1 41 1 1 1 1 54 55 1 10 1 1 1 1 1 1 66 1 68 1 1 1 1 53 1 1",
"output": "-1"
},
{
"input": "2\n1\n1 1\n1 1",
"output": "-1"
},
{
"input": "2\n1\n1 1\n2 2",
"output": "-1"
},
{
"input": "2\n1\n2 2\n1 1",
"output": "-1"
},
{
"input": "2\n1\n2 2\n2 2",
"output": "15.0000000000"
},
{
"input": "2\n2\n1 1\n1 1",
"output": "-1"
},
{
"input": "2\n2\n1 1\n2 2",
"output": "-1"
},
{
"input": "2\n2\n2 2\n1 1",
"output": "-1"
},
{
"input": "2\n2\n2 2\n2 2",
"output": "30.0000000000"
},
{
"input": "40\n55\n1 382 1 1 1 629 111 689 396 614 1 1 995 148 7 820 913 1 1 169 157 1 702 1 159 1 1 226 1 253 1 319 1 130 1 1 1 466 1 756\n1 23 555 1 412 1 1 373 316 234 888 1 112 818 33 443 313 1 235 1 1 610 110 535 1 445 1 386 1 1 758 1 292 1 862 1 244 428 530 1",
"output": "-1"
},
{
"input": "49\n1\n100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100\n3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3",
"output": "695580114.6380882263"
},
{
"input": "2\n12\n11 8\n1 1",
"output": "-1"
},
{
"input": "3\n3\n7 11 17\n19 31 33",
"output": "1.6012429470"
}
] | 1,575,122,769
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 76
| 186
| 1,843,200
|
from math import *
from collections import *
import sys
sys.setrecursionlimit(10**9)
n = int(input())
y = int(input())
z = y
a = list(map(int,input().split()))
b = list(map(int,input().split()))
if(1 in a or 1 in b):
print(-1)
exit(0)
for i in range(n):
x = y/(a[i]-1)
y += x
for i in range(n):
x = y/(b[i]-1)
y += x
print(y-z)
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Natasha is going to fly on a rocket to Mars and return to Earth. Also, on the way to Mars, she will land on $n - 2$ intermediate planets. Formally: we number all the planets from $1$ to $n$. $1$ is Earth, $n$ is Mars. Natasha will make exactly $n$ flights: $1 \to 2 \to \ldots n \to 1$.
Flight from $x$ to $y$ consists of two phases: take-off from planet $x$ and landing to planet $y$. This way, the overall itinerary of the trip will be: the $1$-st planet $\to$ take-off from the $1$-st planet $\to$ landing to the $2$-nd planet $\to$ $2$-nd planet $\to$ take-off from the $2$-nd planet $\to$ $\ldots$ $\to$ landing to the $n$-th planet $\to$ the $n$-th planet $\to$ take-off from the $n$-th planet $\to$ landing to the $1$-st planet $\to$ the $1$-st planet.
The mass of the rocket together with all the useful cargo (but without fuel) is $m$ tons. However, Natasha does not know how much fuel to load into the rocket. Unfortunately, fuel can only be loaded on Earth, so if the rocket runs out of fuel on some other planet, Natasha will not be able to return home. Fuel is needed to take-off from each planet and to land to each planet. It is known that $1$ ton of fuel can lift off $a_i$ tons of rocket from the $i$-th planet or to land $b_i$ tons of rocket onto the $i$-th planet.
For example, if the weight of rocket is $9$ tons, weight of fuel is $3$ tons and take-off coefficient is $8$ ($a_i = 8$), then $1.5$ tons of fuel will be burnt (since $1.5 \cdot 8 = 9 + 3$). The new weight of fuel after take-off will be $1.5$ tons.
Please note, that it is allowed to burn non-integral amount of fuel during take-off or landing, and the amount of initial fuel can be non-integral as well.
Help Natasha to calculate the minimum mass of fuel to load into the rocket. Note, that the rocket must spend fuel to carry both useful cargo and the fuel itself. However, it doesn't need to carry the fuel which has already been burnt. Assume, that the rocket takes off and lands instantly.
Input Specification:
The first line contains a single integer $n$ ($2 \le n \le 1000$) — number of planets.
The second line contains the only integer $m$ ($1 \le m \le 1000$) — weight of the payload.
The third line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($1 \le a_i \le 1000$), where $a_i$ is the number of tons, which can be lifted off by one ton of fuel.
The fourth line contains $n$ integers $b_1, b_2, \ldots, b_n$ ($1 \le b_i \le 1000$), where $b_i$ is the number of tons, which can be landed by one ton of fuel.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
Output Specification:
If Natasha can fly to Mars through $(n - 2)$ planets and return to Earth, print the minimum mass of fuel (in tons) that Natasha should take. Otherwise, print a single number $-1$.
It is guaranteed, that if Natasha can make a flight, then it takes no more than $10^9$ tons of fuel.
The answer will be considered correct if its absolute or relative error doesn't exceed $10^{-6}$. Formally, let your answer be $p$, and the jury's answer be $q$. Your answer is considered correct if $\frac{|p - q|}{\max{(1, |q|)}} \le 10^{-6}$.
Demo Input:
['2\n12\n11 8\n7 5\n', '3\n1\n1 4 1\n2 5 3\n', '6\n2\n4 6 3 3 5 6\n2 6 3 6 5 3\n']
Demo Output:
['10.0000000000\n', '-1\n', '85.4800000000\n']
Note:
Let's consider the first example.
Initially, the mass of a rocket with fuel is $22$ tons.
- At take-off from Earth one ton of fuel can lift off $11$ tons of cargo, so to lift off $22$ tons you need to burn $2$ tons of fuel. Remaining weight of the rocket with fuel is $20$ tons.- During landing on Mars, one ton of fuel can land $5$ tons of cargo, so for landing $20$ tons you will need to burn $4$ tons of fuel. There will be $16$ tons of the rocket with fuel remaining.- While taking off from Mars, one ton of fuel can raise $8$ tons of cargo, so to lift off $16$ tons you will need to burn $2$ tons of fuel. There will be $14$ tons of rocket with fuel after that.- During landing on Earth, one ton of fuel can land $7$ tons of cargo, so for landing $14$ tons you will need to burn $2$ tons of fuel. Remaining weight is $12$ tons, that is, a rocket without any fuel.
In the second case, the rocket will not be able even to take off from Earth.
|
```python
from math import *
from collections import *
import sys
sys.setrecursionlimit(10**9)
n = int(input())
y = int(input())
z = y
a = list(map(int,input().split()))
b = list(map(int,input().split()))
if(1 in a or 1 in b):
print(-1)
exit(0)
for i in range(n):
x = y/(a[i]-1)
y += x
for i in range(n):
x = y/(b[i]-1)
y += x
print(y-z)
```
| 3
|
|
673
|
A
|
Bear and Game
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Bear Limak likes watching sports on TV. He is going to watch a game today. The game lasts 90 minutes and there are no breaks.
Each minute can be either interesting or boring. If 15 consecutive minutes are boring then Limak immediately turns TV off.
You know that there will be *n* interesting minutes *t*1,<=*t*2,<=...,<=*t**n*. Your task is to calculate for how many minutes Limak will watch the game.
|
The first line of the input contains one integer *n* (1<=≤<=*n*<=≤<=90) — the number of interesting minutes.
The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t*1<=<<=*t*2<=<<=... *t**n*<=≤<=90), given in the increasing order.
|
Print the number of minutes Limak will watch the game.
|
[
"3\n7 20 88\n",
"9\n16 20 30 40 50 60 70 80 90\n",
"9\n15 20 30 40 50 60 70 80 90\n"
] |
[
"35\n",
"15\n",
"90\n"
] |
In the first sample, minutes 21, 22, ..., 35 are all boring and thus Limak will turn TV off immediately after the 35-th minute. So, he would watch the game for 35 minutes.
In the second sample, the first 15 minutes are boring.
In the third sample, there are no consecutive 15 boring minutes. So, Limak will watch the whole game.
| 500
|
[
{
"input": "3\n7 20 88",
"output": "35"
},
{
"input": "9\n16 20 30 40 50 60 70 80 90",
"output": "15"
},
{
"input": "9\n15 20 30 40 50 60 70 80 90",
"output": "90"
},
{
"input": "30\n6 11 12 15 22 24 30 31 32 33 34 35 40 42 44 45 47 50 53 54 57 58 63 67 75 77 79 81 83 88",
"output": "90"
},
{
"input": "60\n1 2 4 5 6 7 11 14 16 18 20 21 22 23 24 25 26 33 34 35 36 37 38 39 41 42 43 44 46 47 48 49 52 55 56 57 58 59 60 61 63 64 65 67 68 70 71 72 73 74 75 77 78 80 82 83 84 85 86 88",
"output": "90"
},
{
"input": "90\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90",
"output": "90"
},
{
"input": "1\n1",
"output": "16"
},
{
"input": "5\n15 30 45 60 75",
"output": "90"
},
{
"input": "6\n14 29 43 59 70 74",
"output": "58"
},
{
"input": "1\n15",
"output": "30"
},
{
"input": "1\n16",
"output": "15"
},
{
"input": "14\n14 22 27 31 35 44 46 61 62 69 74 79 88 89",
"output": "90"
},
{
"input": "76\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90",
"output": "90"
},
{
"input": "1\n90",
"output": "15"
},
{
"input": "6\n13 17 32 47 60 66",
"output": "81"
},
{
"input": "84\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84",
"output": "90"
},
{
"input": "9\n6 20 27 28 40 53 59 70 85",
"output": "90"
},
{
"input": "12\n14 22 27 31 35 44 62 69 74 79 88 89",
"output": "59"
},
{
"input": "5\n15 30 45 60 74",
"output": "89"
},
{
"input": "72\n3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89",
"output": "54"
},
{
"input": "8\n1 16 30 31 32 33 34 50",
"output": "49"
},
{
"input": "12\n1 3 6 10 15 21 28 36 45 55 66 78",
"output": "90"
},
{
"input": "25\n1 2 3 4 5 6 7 8 9 10 11 23 36 50 65 81 82 83 84 85 86 87 88 89 90",
"output": "80"
},
{
"input": "8\n5 17 20 35 42 53 67 76",
"output": "90"
},
{
"input": "9\n15 28 39 48 55 60 63 64 74",
"output": "89"
},
{
"input": "10\n15 28 39 48 55 60 63 64 74 82",
"output": "90"
},
{
"input": "2\n1 18",
"output": "16"
},
{
"input": "9\n10 20 30 40 50 60 70 80 84",
"output": "90"
},
{
"input": "2\n16 50",
"output": "15"
},
{
"input": "6\n15 30 45 60 75 84",
"output": "90"
},
{
"input": "8\n15 20 30 40 50 60 73 83",
"output": "90"
},
{
"input": "8\n10 20 30 40 50 60 70 80",
"output": "90"
},
{
"input": "3\n1 20 90",
"output": "16"
},
{
"input": "6\n15 30 45 60 74 89",
"output": "90"
}
] | 1,613,320,250
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
while True:
if len(x) == 1:
if x[0] == n:
print(90)
break
elif x[0] != n:
if x[0] > 15
print(15)
break
else:
print(x[0] + 15)
elif x[0] > 15:
break
print(15)
b = False
break
elif x[i+1] - x[i] >= 15:
print(x[i] + 15)
b = False
break
i+=1
if i + 1 >= n:
break
if b == True :
print(90)
|
Title: Bear and Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Bear Limak likes watching sports on TV. He is going to watch a game today. The game lasts 90 minutes and there are no breaks.
Each minute can be either interesting or boring. If 15 consecutive minutes are boring then Limak immediately turns TV off.
You know that there will be *n* interesting minutes *t*1,<=*t*2,<=...,<=*t**n*. Your task is to calculate for how many minutes Limak will watch the game.
Input Specification:
The first line of the input contains one integer *n* (1<=≤<=*n*<=≤<=90) — the number of interesting minutes.
The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t*1<=<<=*t*2<=<<=... *t**n*<=≤<=90), given in the increasing order.
Output Specification:
Print the number of minutes Limak will watch the game.
Demo Input:
['3\n7 20 88\n', '9\n16 20 30 40 50 60 70 80 90\n', '9\n15 20 30 40 50 60 70 80 90\n']
Demo Output:
['35\n', '15\n', '90\n']
Note:
In the first sample, minutes 21, 22, ..., 35 are all boring and thus Limak will turn TV off immediately after the 35-th minute. So, he would watch the game for 35 minutes.
In the second sample, the first 15 minutes are boring.
In the third sample, there are no consecutive 15 boring minutes. So, Limak will watch the whole game.
|
```python
while True:
if len(x) == 1:
if x[0] == n:
print(90)
break
elif x[0] != n:
if x[0] > 15
print(15)
break
else:
print(x[0] + 15)
elif x[0] > 15:
break
print(15)
b = False
break
elif x[i+1] - x[i] >= 15:
print(x[i] + 15)
b = False
break
i+=1
if i + 1 >= n:
break
if b == True :
print(90)
```
| -1
|
|
237
|
A
|
Free Cash
|
PROGRAMMING
| 1,000
|
[
"implementation"
] | null | null |
Valera runs a 24/7 fast food cafe. He magically learned that next day *n* people will visit his cafe. For each person we know the arrival time: the *i*-th person comes exactly at *h**i* hours *m**i* minutes. The cafe spends less than a minute to serve each client, but if a client comes in and sees that there is no free cash, than he doesn't want to wait and leaves the cafe immediately.
Valera is very greedy, so he wants to serve all *n* customers next day (and get more profit). However, for that he needs to ensure that at each moment of time the number of working cashes is no less than the number of clients in the cafe.
Help Valera count the minimum number of cashes to work at his cafe next day, so that they can serve all visitors.
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=105), that is the number of cafe visitors.
Each of the following *n* lines has two space-separated integers *h**i* and *m**i* (0<=≤<=*h**i*<=≤<=23; 0<=≤<=*m**i*<=≤<=59), representing the time when the *i*-th person comes into the cafe.
Note that the time is given in the chronological order. All time is given within one 24-hour period.
|
Print a single integer — the minimum number of cashes, needed to serve all clients next day.
|
[
"4\n8 0\n8 10\n8 10\n8 45\n",
"3\n0 12\n10 11\n22 22\n"
] |
[
"2\n",
"1\n"
] |
In the first sample it is not enough one cash to serve all clients, because two visitors will come into cafe in 8:10. Therefore, if there will be one cash in cafe, then one customer will be served by it, and another one will not wait and will go away.
In the second sample all visitors will come in different times, so it will be enough one cash.
| 500
|
[
{
"input": "4\n8 0\n8 10\n8 10\n8 45",
"output": "2"
},
{
"input": "3\n0 12\n10 11\n22 22",
"output": "1"
},
{
"input": "5\n12 8\n15 27\n15 27\n16 2\n19 52",
"output": "2"
},
{
"input": "7\n5 6\n7 34\n7 34\n7 34\n12 29\n15 19\n20 23",
"output": "3"
},
{
"input": "8\n0 36\n4 7\n4 7\n4 7\n11 46\n12 4\n15 39\n18 6",
"output": "3"
},
{
"input": "20\n4 12\n4 21\n4 27\n4 56\n5 55\n7 56\n11 28\n11 36\n14 58\n15 59\n16 8\n17 12\n17 23\n17 23\n17 23\n17 23\n17 23\n17 23\n20 50\n22 32",
"output": "6"
},
{
"input": "10\n1 30\n1 30\n1 30\n1 30\n1 30\n1 30\n1 30\n1 30\n1 30\n1 30",
"output": "10"
},
{
"input": "50\n0 23\n1 21\n2 8\n2 45\n3 1\n4 19\n4 37\n7 7\n7 40\n8 43\n9 51\n10 13\n11 2\n11 19\n11 30\n12 37\n12 37\n12 37\n12 37\n12 37\n12 37\n12 37\n12 37\n12 54\n13 32\n13 42\n14 29\n14 34\n14 48\n15 0\n15 27\n16 22\n16 31\n17 25\n17 26\n17 33\n18 14\n18 16\n18 20\n19 0\n19 5\n19 56\n20 22\n21 26\n22 0\n22 10\n22 11\n22 36\n23 17\n23 20",
"output": "8"
},
{
"input": "10\n0 39\n1 35\n1 49\n1 51\n5 24\n7 40\n7 56\n16 42\n23 33\n23 49",
"output": "1"
},
{
"input": "15\n0 16\n6 15\n8 2\n8 6\n8 7\n10 1\n10 1\n10 3\n10 12\n13 5\n14 16\n14 16\n14 16\n14 16\n14 16",
"output": "5"
},
{
"input": "2\n0 24\n1 0",
"output": "1"
},
{
"input": "1\n0 0",
"output": "1"
},
{
"input": "1\n1 5",
"output": "1"
},
{
"input": "1\n1 1",
"output": "1"
},
{
"input": "3\n0 0\n0 0\n0 0",
"output": "3"
},
{
"input": "1\n5 0",
"output": "1"
},
{
"input": "5\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "5"
},
{
"input": "1\n10 10",
"output": "1"
},
{
"input": "1\n8 0",
"output": "1"
},
{
"input": "10\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0",
"output": "10"
},
{
"input": "2\n0 0\n0 1",
"output": "1"
},
{
"input": "2\n8 5\n8 5",
"output": "2"
}
] | 1,650,624,863
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 62
| 0
|
n = int(input())
h = []
m = []
for i in range(n):
a, b = map(int, input().split())
h.append(a)
m.append(b)
k = 1
for i in range(n-1):
if h[i] == h[i+1]:
if m[i] == m[i+1]:
k = k+1
print(k)
|
Title: Free Cash
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera runs a 24/7 fast food cafe. He magically learned that next day *n* people will visit his cafe. For each person we know the arrival time: the *i*-th person comes exactly at *h**i* hours *m**i* minutes. The cafe spends less than a minute to serve each client, but if a client comes in and sees that there is no free cash, than he doesn't want to wait and leaves the cafe immediately.
Valera is very greedy, so he wants to serve all *n* customers next day (and get more profit). However, for that he needs to ensure that at each moment of time the number of working cashes is no less than the number of clients in the cafe.
Help Valera count the minimum number of cashes to work at his cafe next day, so that they can serve all visitors.
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=105), that is the number of cafe visitors.
Each of the following *n* lines has two space-separated integers *h**i* and *m**i* (0<=≤<=*h**i*<=≤<=23; 0<=≤<=*m**i*<=≤<=59), representing the time when the *i*-th person comes into the cafe.
Note that the time is given in the chronological order. All time is given within one 24-hour period.
Output Specification:
Print a single integer — the minimum number of cashes, needed to serve all clients next day.
Demo Input:
['4\n8 0\n8 10\n8 10\n8 45\n', '3\n0 12\n10 11\n22 22\n']
Demo Output:
['2\n', '1\n']
Note:
In the first sample it is not enough one cash to serve all clients, because two visitors will come into cafe in 8:10. Therefore, if there will be one cash in cafe, then one customer will be served by it, and another one will not wait and will go away.
In the second sample all visitors will come in different times, so it will be enough one cash.
|
```python
n = int(input())
h = []
m = []
for i in range(n):
a, b = map(int, input().split())
h.append(a)
m.append(b)
k = 1
for i in range(n-1):
if h[i] == h[i+1]:
if m[i] == m[i+1]:
k = k+1
print(k)
```
| 0
|
|
915
|
C
|
Permute Digits
|
PROGRAMMING
| 1,700
|
[
"dp",
"greedy"
] | null | null |
You are given two positive integer numbers *a* and *b*. Permute (change order) of the digits of *a* to construct maximal number not exceeding *b*. No number in input and/or output can start with the digit 0.
It is allowed to leave *a* as it is.
|
The first line contains integer *a* (1<=≤<=*a*<=≤<=1018). The second line contains integer *b* (1<=≤<=*b*<=≤<=1018). Numbers don't have leading zeroes. It is guaranteed that answer exists.
|
Print the maximum possible number that is a permutation of digits of *a* and is not greater than *b*. The answer can't have any leading zeroes. It is guaranteed that the answer exists.
The number in the output should have exactly the same length as number *a*. It should be a permutation of digits of *a*.
|
[
"123\n222\n",
"3921\n10000\n",
"4940\n5000\n"
] |
[
"213\n",
"9321\n",
"4940\n"
] |
none
| 0
|
[
{
"input": "123\n222",
"output": "213"
},
{
"input": "3921\n10000",
"output": "9321"
},
{
"input": "4940\n5000",
"output": "4940"
},
{
"input": "23923472834\n23589234723",
"output": "23498743322"
},
{
"input": "102391019\n491010301",
"output": "399211100"
},
{
"input": "123456789123456789\n276193619183618162",
"output": "276193618987554432"
},
{
"input": "1000000000000000000\n1000000000000000000",
"output": "1000000000000000000"
},
{
"input": "1\n1000000000000000000",
"output": "1"
},
{
"input": "999999999999999999\n1000000000000000000",
"output": "999999999999999999"
},
{
"input": "2475345634895\n3455834583479",
"output": "3455834579642"
},
{
"input": "15778899\n98715689",
"output": "98598771"
},
{
"input": "4555\n5454",
"output": "4555"
},
{
"input": "122112\n221112",
"output": "221112"
},
{
"input": "199999999999991\n191000000000000",
"output": "119999999999999"
},
{
"input": "13\n31",
"output": "31"
},
{
"input": "212\n211",
"output": "122"
},
{
"input": "222234\n322223",
"output": "243222"
},
{
"input": "123456789\n987654311",
"output": "987654231"
},
{
"input": "20123\n21022",
"output": "20321"
},
{
"input": "10101\n11000",
"output": "10110"
},
{
"input": "592\n924",
"output": "592"
},
{
"input": "5654456\n5634565",
"output": "5566544"
},
{
"input": "655432\n421631",
"output": "365542"
},
{
"input": "200\n200",
"output": "200"
},
{
"input": "123456789987654321\n121111111111111111",
"output": "119988776655443322"
},
{
"input": "12345\n21344",
"output": "15432"
},
{
"input": "120\n200",
"output": "120"
},
{
"input": "123\n212",
"output": "132"
},
{
"input": "2184645\n5213118",
"output": "5186442"
},
{
"input": "9912346\n9912345",
"output": "9694321"
},
{
"input": "5003\n5000",
"output": "3500"
},
{
"input": "12345\n31234",
"output": "25431"
},
{
"input": "5001\n5000",
"output": "1500"
},
{
"input": "53436\n53425",
"output": "53364"
},
{
"input": "9329\n3268",
"output": "2993"
},
{
"input": "1234567890\n9000000001",
"output": "8976543210"
},
{
"input": "321\n212",
"output": "132"
},
{
"input": "109823464\n901234467",
"output": "896443210"
},
{
"input": "6543\n6542",
"output": "6534"
},
{
"input": "555441\n555100",
"output": "554541"
},
{
"input": "472389479\n327489423",
"output": "327487994"
},
{
"input": "45645643756464352\n53465475637456247",
"output": "53465475636654442"
},
{
"input": "254\n599",
"output": "542"
},
{
"input": "5232222345652321\n5000000000000000",
"output": "4655533322222221"
},
{
"input": "201\n200",
"output": "120"
},
{
"input": "14362799391220361\n45160821596433661",
"output": "43999766332221110"
},
{
"input": "3453\n5304",
"output": "4533"
},
{
"input": "989\n998",
"output": "998"
},
{
"input": "5200000000234\n5200000000311",
"output": "5200000000243"
},
{
"input": "5555132\n1325442",
"output": "1255553"
},
{
"input": "123\n211",
"output": "132"
},
{
"input": "65689\n66123",
"output": "65986"
},
{
"input": "123451234567890\n123456789012345",
"output": "123456789012345"
},
{
"input": "22115\n22015",
"output": "21521"
},
{
"input": "123\n311",
"output": "231"
},
{
"input": "12222\n21111",
"output": "12222"
},
{
"input": "765\n567",
"output": "567"
},
{
"input": "9087645\n9087640",
"output": "9087564"
},
{
"input": "1111111122222333\n2220000000000000",
"output": "2213332221111111"
},
{
"input": "7901\n7108",
"output": "7091"
},
{
"input": "215489\n215488",
"output": "214985"
},
{
"input": "102\n200",
"output": "120"
},
{
"input": "19260817\n20011213",
"output": "19876210"
},
{
"input": "12345\n53200",
"output": "53142"
},
{
"input": "1040003001\n1040003000",
"output": "1040001300"
},
{
"input": "295\n924",
"output": "592"
},
{
"input": "20000000000000001\n20000000000000000",
"output": "12000000000000000"
},
{
"input": "99988877\n99887766",
"output": "99879887"
},
{
"input": "12\n12",
"output": "12"
},
{
"input": "199999999999999999\n900000000000000000",
"output": "199999999999999999"
},
{
"input": "1234\n4310",
"output": "4231"
},
{
"input": "100011\n100100",
"output": "100011"
},
{
"input": "328899\n328811",
"output": "299883"
},
{
"input": "646722972346\n397619201220",
"output": "397476664222"
},
{
"input": "1203\n1200",
"output": "1032"
},
{
"input": "1\n2",
"output": "1"
},
{
"input": "1112\n2110",
"output": "1211"
},
{
"input": "4545\n5540",
"output": "5454"
},
{
"input": "3053\n5004",
"output": "3530"
},
{
"input": "3503\n5004",
"output": "3530"
},
{
"input": "351731653766064847\n501550303749042658",
"output": "501548777666643331"
},
{
"input": "10123456789013451\n26666666666666666",
"output": "26598754433111100"
},
{
"input": "1110111\n1100000",
"output": "1011111"
},
{
"input": "30478\n32265",
"output": "30874"
},
{
"input": "456546546549874615\n441554543131214545",
"output": "441554498766665554"
},
{
"input": "214\n213",
"output": "142"
},
{
"input": "415335582799619283\n133117803602859310",
"output": "132999887655543321"
},
{
"input": "787\n887",
"output": "877"
},
{
"input": "3333222288889999\n3333222288881111",
"output": "3332999988883222"
},
{
"input": "495779862481416791\n836241745208800994",
"output": "829998777665444111"
},
{
"input": "139\n193",
"output": "193"
},
{
"input": "9568\n6500",
"output": "5986"
},
{
"input": "3208899\n3228811",
"output": "3209988"
},
{
"input": "27778\n28710",
"output": "27877"
},
{
"input": "62345\n46415",
"output": "46352"
},
{
"input": "405739873179209\n596793907108871",
"output": "594998777332100"
},
{
"input": "365\n690",
"output": "653"
},
{
"input": "8388731334391\n4710766672578",
"output": "4398887333311"
},
{
"input": "1230\n1200",
"output": "1032"
},
{
"input": "1025\n5000",
"output": "2510"
},
{
"input": "4207799\n4027711",
"output": "2997740"
},
{
"input": "4444222277779999\n4444222277771111",
"output": "4442999977774222"
},
{
"input": "7430\n3047",
"output": "3047"
},
{
"input": "649675735\n540577056",
"output": "539776654"
},
{
"input": "26\n82",
"output": "62"
},
{
"input": "241285\n207420",
"output": "185422"
},
{
"input": "3\n3",
"output": "3"
},
{
"input": "12\n21",
"output": "21"
},
{
"input": "481287\n826607",
"output": "824871"
},
{
"input": "40572351\n59676984",
"output": "57543210"
},
{
"input": "268135787269\n561193454469",
"output": "539887766221"
},
{
"input": "4\n9",
"output": "4"
},
{
"input": "5\n6",
"output": "5"
},
{
"input": "60579839\n33370073",
"output": "30998765"
},
{
"input": "49939\n39200",
"output": "34999"
},
{
"input": "2224\n4220",
"output": "2422"
},
{
"input": "427799\n427711",
"output": "299774"
},
{
"input": "49\n90",
"output": "49"
},
{
"input": "93875\n82210",
"output": "79853"
},
{
"input": "78831\n7319682",
"output": "88731"
},
{
"input": "937177\n7143444",
"output": "977731"
},
{
"input": "499380628\n391990337",
"output": "390988642"
},
{
"input": "2090909\n2900000",
"output": "2099900"
},
{
"input": "112233445566778890\n987654321987654320",
"output": "987654321876543210"
},
{
"input": "48257086\n80903384",
"output": "80876542"
},
{
"input": "112233445566778890\n900654321987654320",
"output": "898776655443322110"
},
{
"input": "112233445566778890\n123456789123456788",
"output": "123456789123456780"
},
{
"input": "5207799\n5027711",
"output": "2997750"
},
{
"input": "200000000000000001\n200000000000000000",
"output": "120000000000000000"
},
{
"input": "597402457\n797455420",
"output": "797455420"
},
{
"input": "90\n94",
"output": "90"
},
{
"input": "86888\n88683",
"output": "86888"
},
{
"input": "419155888\n588151913",
"output": "588151894"
},
{
"input": "408919130\n191830070",
"output": "191830049"
},
{
"input": "524975\n554924",
"output": "554792"
},
{
"input": "53029\n30524",
"output": "30295"
},
{
"input": "5549\n5542",
"output": "5495"
},
{
"input": "6\n9",
"output": "6"
},
{
"input": "87\n810",
"output": "87"
},
{
"input": "920491855\n281495062",
"output": "281495059"
},
{
"input": "6691\n6910",
"output": "6691"
},
{
"input": "533\n335",
"output": "335"
},
{
"input": "999999999999999998\n999999999999999997",
"output": "999999999999999989"
},
{
"input": "21111111111111111\n21111111111111110",
"output": "12111111111111111"
},
{
"input": "2\n12",
"output": "2"
},
{
"input": "76544\n45744",
"output": "45674"
},
{
"input": "2000000000000001\n2000000000000000",
"output": "1200000000000000"
},
{
"input": "740867\n467701",
"output": "467087"
},
{
"input": "2\n6",
"output": "2"
},
{
"input": "103\n130",
"output": "130"
},
{
"input": "2423712\n8466235",
"output": "7432221"
},
{
"input": "84\n48",
"output": "48"
},
{
"input": "1210\n12113",
"output": "2110"
},
{
"input": "2430\n20786",
"output": "4320"
},
{
"input": "100\n999",
"output": "100"
},
{
"input": "19325\n21903",
"output": "21593"
},
{
"input": "1969\n23251",
"output": "9961"
}
] | 1,623,065,740
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 3
| 124
| 0
|
a = list(map(int, input()))
l = sorted(a)
l.reverse()
b = int(input())
otv = '0' * len(a)
for i in range(len(a)):
g = int(otv[0:i] + str(l[i]) + otv[i + 1:])
if int(otv[0:i] + str(l[i]) + otv[i + 1:]) > b:
c = 0
while int(otv[0:i] + str(l[c]) + otv[i + 1:]) > b:
c += 1
otv = otv[0:i] + str(l[c]) + otv[i + 1:]
l.pop(c)
l.insert(c, 10 ** 18 + 1)
else:
otv = otv[0:i] + str(l[i]) + otv[i + 1:]
l.pop(i)
l.insert(i, 10 ** 18 + 1)
print(int(otv))
|
Title: Permute Digits
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given two positive integer numbers *a* and *b*. Permute (change order) of the digits of *a* to construct maximal number not exceeding *b*. No number in input and/or output can start with the digit 0.
It is allowed to leave *a* as it is.
Input Specification:
The first line contains integer *a* (1<=≤<=*a*<=≤<=1018). The second line contains integer *b* (1<=≤<=*b*<=≤<=1018). Numbers don't have leading zeroes. It is guaranteed that answer exists.
Output Specification:
Print the maximum possible number that is a permutation of digits of *a* and is not greater than *b*. The answer can't have any leading zeroes. It is guaranteed that the answer exists.
The number in the output should have exactly the same length as number *a*. It should be a permutation of digits of *a*.
Demo Input:
['123\n222\n', '3921\n10000\n', '4940\n5000\n']
Demo Output:
['213\n', '9321\n', '4940\n']
Note:
none
|
```python
a = list(map(int, input()))
l = sorted(a)
l.reverse()
b = int(input())
otv = '0' * len(a)
for i in range(len(a)):
g = int(otv[0:i] + str(l[i]) + otv[i + 1:])
if int(otv[0:i] + str(l[i]) + otv[i + 1:]) > b:
c = 0
while int(otv[0:i] + str(l[c]) + otv[i + 1:]) > b:
c += 1
otv = otv[0:i] + str(l[c]) + otv[i + 1:]
l.pop(c)
l.insert(c, 10 ** 18 + 1)
else:
otv = otv[0:i] + str(l[i]) + otv[i + 1:]
l.pop(i)
l.insert(i, 10 ** 18 + 1)
print(int(otv))
```
| 0
|
|
988
|
A
|
Diverse Team
|
PROGRAMMING
| 800
|
[
"brute force",
"implementation"
] | null | null |
There are $n$ students in a school class, the rating of the $i$-th student on Codehorses is $a_i$. You have to form a team consisting of $k$ students ($1 \le k \le n$) such that the ratings of all team members are distinct.
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct numbers which should be the indices of students in the team you form. If there are multiple answers, print any of them.
|
The first line contains two integers $n$ and $k$ ($1 \le k \le n \le 100$) — the number of students and the size of the team you have to form.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 100$), where $a_i$ is the rating of $i$-th student.
|
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct integers from $1$ to $n$ which should be the indices of students in the team you form. All the ratings of the students in the team should be distinct. You may print the indices in any order. If there are multiple answers, print any of them.
Assume that the students are numbered from $1$ to $n$.
|
[
"5 3\n15 13 15 15 12\n",
"5 4\n15 13 15 15 12\n",
"4 4\n20 10 40 30\n"
] |
[
"YES\n1 2 5 \n",
"NO\n",
"YES\n1 2 3 4 \n"
] |
All possible answers for the first example:
- {1 2 5} - {2 3 5} - {2 4 5}
Note that the order does not matter.
| 0
|
[
{
"input": "5 3\n15 13 15 15 12",
"output": "YES\n1 2 5 "
},
{
"input": "5 4\n15 13 15 15 12",
"output": "NO"
},
{
"input": "4 4\n20 10 40 30",
"output": "YES\n1 2 3 4 "
},
{
"input": "1 1\n1",
"output": "YES\n1 "
},
{
"input": "100 53\n16 17 1 2 27 5 9 9 53 24 17 33 35 24 20 48 56 73 12 14 39 55 58 13 59 73 29 26 40 33 22 29 34 22 55 38 63 66 36 13 60 42 10 15 21 9 11 5 23 37 79 47 26 3 79 53 44 8 71 75 42 11 34 39 79 33 10 26 23 23 17 14 54 41 60 31 83 5 45 4 14 35 6 60 28 48 23 18 60 36 21 28 7 34 9 25 52 43 54 19",
"output": "YES\n1 2 3 4 5 6 7 9 10 12 13 15 16 17 18 19 20 21 22 23 24 25 27 28 29 31 33 36 37 38 39 41 42 43 44 45 47 49 50 51 52 54 57 58 59 60 73 74 76 77 79 80 83 "
},
{
"input": "2 2\n100 100",
"output": "NO"
},
{
"input": "2 2\n100 99",
"output": "YES\n1 2 "
},
{
"input": "100 100\n63 100 75 32 53 24 73 98 76 15 70 48 8 81 88 58 95 78 27 92 14 16 72 43 46 39 66 38 64 42 59 9 22 51 4 6 10 94 28 99 68 80 35 50 45 20 47 7 30 26 49 91 77 19 96 57 65 1 11 13 31 12 82 87 93 34 62 3 21 79 56 41 89 18 44 23 74 86 2 33 69 36 61 67 25 83 5 84 90 37 40 29 97 60 52 55 54 71 17 85",
"output": "YES\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 "
},
{
"input": "100 41\n54 16 42 3 45 6 9 72 100 13 24 57 35 5 89 13 97 27 43 9 73 89 48 16 48 55 18 15 55 28 30 6 18 41 100 61 9 42 35 54 57 25 73 15 42 54 49 5 72 48 30 55 4 43 94 5 60 92 93 23 89 75 53 92 74 93 89 28 69 6 3 49 15 28 49 57 54 55 30 57 69 18 89 6 25 23 93 74 30 13 87 53 6 42 4 54 60 30 4 35",
"output": "NO"
},
{
"input": "100 2\n70 64 70 32 70 64 32 70 64 32 32 64 70 64 64 32 64 64 64 70 70 64 64 64 64 70 32 64 70 64 32 70 70 70 64 70 64 70 64 32 70 32 70 64 64 64 32 70 64 70 70 32 70 32 32 32 70 32 70 32 64 64 70 32 32 64 70 64 32 32 64 64 32 32 70 70 32 70 32 64 32 70 64 64 32 64 32 64 70 32 70 32 70 64 64 64 70 70 64 70",
"output": "YES\n1 2 "
}
] | 1,660,381,198
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 4
| 31
| 0
|
n = input().split()
k = int(n[1])
n = int(n[0])
a = input().split()
for i in range(n):
a[i]=int(a[i])
s = set(a)
if(len(s)>=k):
print("YES")
for i in s:
for j in range(len(a)):
if(a[j]==i):
print(j+1,end = " ")
break
else:
print("NO")
|
Title: Diverse Team
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are $n$ students in a school class, the rating of the $i$-th student on Codehorses is $a_i$. You have to form a team consisting of $k$ students ($1 \le k \le n$) such that the ratings of all team members are distinct.
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct numbers which should be the indices of students in the team you form. If there are multiple answers, print any of them.
Input Specification:
The first line contains two integers $n$ and $k$ ($1 \le k \le n \le 100$) — the number of students and the size of the team you have to form.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 100$), where $a_i$ is the rating of $i$-th student.
Output Specification:
If it is impossible to form a suitable team, print "NO" (without quotes). Otherwise print "YES", and then print $k$ distinct integers from $1$ to $n$ which should be the indices of students in the team you form. All the ratings of the students in the team should be distinct. You may print the indices in any order. If there are multiple answers, print any of them.
Assume that the students are numbered from $1$ to $n$.
Demo Input:
['5 3\n15 13 15 15 12\n', '5 4\n15 13 15 15 12\n', '4 4\n20 10 40 30\n']
Demo Output:
['YES\n1 2 5 \n', 'NO\n', 'YES\n1 2 3 4 \n']
Note:
All possible answers for the first example:
- {1 2 5} - {2 3 5} - {2 4 5}
Note that the order does not matter.
|
```python
n = input().split()
k = int(n[1])
n = int(n[0])
a = input().split()
for i in range(n):
a[i]=int(a[i])
s = set(a)
if(len(s)>=k):
print("YES")
for i in s:
for j in range(len(a)):
if(a[j]==i):
print(j+1,end = " ")
break
else:
print("NO")
```
| 0
|
|
270
|
A
|
Fancy Fence
|
PROGRAMMING
| 1,100
|
[
"geometry",
"implementation",
"math"
] | null | null |
Emuskald needs a fence around his farm, but he is too lazy to build it himself. So he purchased a fence-building robot.
He wants the fence to be a regular polygon. The robot builds the fence along a single path, but it can only make fence corners at a single angle *a*.
Will the robot be able to build the fence Emuskald wants? In other words, is there a regular polygon which angles are equal to *a*?
|
The first line of input contains an integer *t* (0<=<<=*t*<=<<=180) — the number of tests. Each of the following *t* lines contains a single integer *a* (0<=<<=*a*<=<<=180) — the angle the robot can make corners at measured in degrees.
|
For each test, output on a single line "YES" (without quotes), if the robot can build a fence Emuskald wants, and "NO" (without quotes), if it is impossible.
|
[
"3\n30\n60\n90\n"
] |
[
"NO\nYES\nYES\n"
] |
In the first test case, it is impossible to build the fence, since there is no regular polygon with angle <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/df5f4b07dd5316fde165b43657b2696e2919e791.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
In the second test case, the fence is a regular triangle, and in the last test case — a square.
| 500
|
[
{
"input": "3\n30\n60\n90",
"output": "NO\nYES\nYES"
},
{
"input": "6\n1\n2\n3\n170\n179\n25",
"output": "NO\nNO\nNO\nYES\nYES\nNO"
}
] | 1,659,556,458
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 3
| 92
| 0
|
# (n-2) *180 /n = a
# 180 n - 360 = an
# n(180-a) = 360
# n = 360 / (180-a)
t = int(input())
while t:
t-=1
a = int(input())
n = 360 / (180-a)
if(int(n)==n):
print('YES')
else:
print('NO')
|
Title: Fancy Fence
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Emuskald needs a fence around his farm, but he is too lazy to build it himself. So he purchased a fence-building robot.
He wants the fence to be a regular polygon. The robot builds the fence along a single path, but it can only make fence corners at a single angle *a*.
Will the robot be able to build the fence Emuskald wants? In other words, is there a regular polygon which angles are equal to *a*?
Input Specification:
The first line of input contains an integer *t* (0<=<<=*t*<=<<=180) — the number of tests. Each of the following *t* lines contains a single integer *a* (0<=<<=*a*<=<<=180) — the angle the robot can make corners at measured in degrees.
Output Specification:
For each test, output on a single line "YES" (without quotes), if the robot can build a fence Emuskald wants, and "NO" (without quotes), if it is impossible.
Demo Input:
['3\n30\n60\n90\n']
Demo Output:
['NO\nYES\nYES\n']
Note:
In the first test case, it is impossible to build the fence, since there is no regular polygon with angle <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/df5f4b07dd5316fde165b43657b2696e2919e791.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
In the second test case, the fence is a regular triangle, and in the last test case — a square.
|
```python
# (n-2) *180 /n = a
# 180 n - 360 = an
# n(180-a) = 360
# n = 360 / (180-a)
t = int(input())
while t:
t-=1
a = int(input())
n = 360 / (180-a)
if(int(n)==n):
print('YES')
else:
print('NO')
```
| 3
|
|
659
|
C
|
Tanya and Toys
|
PROGRAMMING
| 1,200
|
[
"greedy",
"implementation"
] | null | null |
In Berland recently a new collection of toys went on sale. This collection consists of 109 types of toys, numbered with integers from 1 to 109. A toy from the new collection of the *i*-th type costs *i* bourles.
Tania has managed to collect *n* different types of toys *a*1,<=*a*2,<=...,<=*a**n* from the new collection. Today is Tanya's birthday, and her mother decided to spend no more than *m* bourles on the gift to the daughter. Tanya will choose several different types of toys from the new collection as a gift. Of course, she does not want to get a type of toy which she already has.
Tanya wants to have as many distinct types of toys in her collection as possible as the result. The new collection is too diverse, and Tanya is too little, so she asks you to help her in this.
|
The first line contains two integers *n* (1<=≤<=*n*<=≤<=100<=000) and *m* (1<=≤<=*m*<=≤<=109) — the number of types of toys that Tanya already has and the number of bourles that her mom is willing to spend on buying new toys.
The next line contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109) — the types of toys that Tanya already has.
|
In the first line print a single integer *k* — the number of different types of toys that Tanya should choose so that the number of different types of toys in her collection is maximum possible. Of course, the total cost of the selected toys should not exceed *m*.
In the second line print *k* distinct space-separated integers *t*1,<=*t*2,<=...,<=*t**k* (1<=≤<=*t**i*<=≤<=109) — the types of toys that Tanya should choose.
If there are multiple answers, you may print any of them. Values of *t**i* can be printed in any order.
|
[
"3 7\n1 3 4\n",
"4 14\n4 6 12 8\n"
] |
[
"2\n2 5 \n",
"4\n7 2 3 1\n"
] |
In the first sample mom should buy two toys: one toy of the 2-nd type and one toy of the 5-th type. At any other purchase for 7 bourles (assuming that the toys of types 1, 3 and 4 have already been bought), it is impossible to buy two and more toys.
| 1,000
|
[
{
"input": "3 7\n1 3 4",
"output": "2\n2 5 "
},
{
"input": "4 14\n4 6 12 8",
"output": "4\n1 2 3 5 "
},
{
"input": "5 6\n97746 64770 31551 96547 65684",
"output": "3\n1 2 3 "
},
{
"input": "10 10\n94125 56116 29758 94024 29289 31663 99794 35076 25328 58656",
"output": "4\n1 2 3 4 "
},
{
"input": "30 38\n9560 64176 75619 53112 54160 68775 12655 13118 99502 89757 78434 42521 19210 1927 34097 5416 56110 44786 59126 44266 79240 65567 54602 25325 37171 2879 89291 89121 39568 28162",
"output": "8\n1 2 3 4 5 6 7 8 "
},
{
"input": "1 999999298\n85187",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "1 999999119\n34421",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "1 1000000000\n1",
"output": "44719\n2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 15..."
},
{
"input": "1 1000000000\n44720",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "1 1000000000\n44719",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "1 1000000000\n44721",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "3 1000000000\n123456789 234567891 345678912",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "2 5\n999999999 1000000000",
"output": "2\n1 2 "
},
{
"input": "2 1000000000\n1 1000000000",
"output": "44719\n2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 15..."
},
{
"input": "3 100000\n1000000000 100000000 1",
"output": "445\n2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 ..."
},
{
"input": "5 5\n100000000 200000000 300000000 400000000 1000000000",
"output": "2\n1 2 "
},
{
"input": "6 3\n1 2 3 4 5 6",
"output": "0"
},
{
"input": "2 1\n1 2",
"output": "0"
},
{
"input": "1 1000000000\n1000000000",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "5 1000000\n1000000000 100000000 10000000 99999999 123456789",
"output": "1413\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 1..."
},
{
"input": "2 10000000\n1234567 123456",
"output": "4471\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 1..."
},
{
"input": "1 1\n1000000000",
"output": "1\n1 "
},
{
"input": "1 1000000000\n9999999",
"output": "44720\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 ..."
},
{
"input": "5 10000\n1000000000 888888888 777777777 666666666 959595959",
"output": "140\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 "
},
{
"input": "3 1\n1000000000 999999999 999999998",
"output": "1\n1 "
},
{
"input": "5 100000000\n100000000 999999999 1 2 3",
"output": "14138\n4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 15..."
},
{
"input": "3 55\n100000000 1000000000 999999999",
"output": "10\n1 2 3 4 5 6 7 8 9 10 "
},
{
"input": "2 10\n5 10000009",
"output": "4\n1 2 3 4 "
},
{
"input": "3 10000000\n999999999 999999998 999999997",
"output": "4471\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 1..."
},
{
"input": "1 1100\n1000000000",
"output": "46\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 "
},
{
"input": "1 40\n1000000000",
"output": "8\n1 2 3 4 5 6 7 8 "
}
] | 1,523,124,283
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 8
| 1,000
| 8,396,800
|
n,k=map(int,input().split())
import sys
a=list(map(int,sys.stdin.readline().split()))
a.sort()
b=[]
l=0
for i in range(1,k+1):
if i not in a:
if (k-i)>=0:
b.append(i)
k-=i
l+=1
else: break
if k==0:
break
print(l)
print(*b)
|
Title: Tanya and Toys
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
In Berland recently a new collection of toys went on sale. This collection consists of 109 types of toys, numbered with integers from 1 to 109. A toy from the new collection of the *i*-th type costs *i* bourles.
Tania has managed to collect *n* different types of toys *a*1,<=*a*2,<=...,<=*a**n* from the new collection. Today is Tanya's birthday, and her mother decided to spend no more than *m* bourles on the gift to the daughter. Tanya will choose several different types of toys from the new collection as a gift. Of course, she does not want to get a type of toy which she already has.
Tanya wants to have as many distinct types of toys in her collection as possible as the result. The new collection is too diverse, and Tanya is too little, so she asks you to help her in this.
Input Specification:
The first line contains two integers *n* (1<=≤<=*n*<=≤<=100<=000) and *m* (1<=≤<=*m*<=≤<=109) — the number of types of toys that Tanya already has and the number of bourles that her mom is willing to spend on buying new toys.
The next line contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109) — the types of toys that Tanya already has.
Output Specification:
In the first line print a single integer *k* — the number of different types of toys that Tanya should choose so that the number of different types of toys in her collection is maximum possible. Of course, the total cost of the selected toys should not exceed *m*.
In the second line print *k* distinct space-separated integers *t*1,<=*t*2,<=...,<=*t**k* (1<=≤<=*t**i*<=≤<=109) — the types of toys that Tanya should choose.
If there are multiple answers, you may print any of them. Values of *t**i* can be printed in any order.
Demo Input:
['3 7\n1 3 4\n', '4 14\n4 6 12 8\n']
Demo Output:
['2\n2 5 \n', '4\n7 2 3 1\n']
Note:
In the first sample mom should buy two toys: one toy of the 2-nd type and one toy of the 5-th type. At any other purchase for 7 bourles (assuming that the toys of types 1, 3 and 4 have already been bought), it is impossible to buy two and more toys.
|
```python
n,k=map(int,input().split())
import sys
a=list(map(int,sys.stdin.readline().split()))
a.sort()
b=[]
l=0
for i in range(1,k+1):
if i not in a:
if (k-i)>=0:
b.append(i)
k-=i
l+=1
else: break
if k==0:
break
print(l)
print(*b)
```
| 0
|
|
231
|
A
|
Team
|
PROGRAMMING
| 800
|
[
"brute force",
"greedy"
] | null | null |
One day three best friends Petya, Vasya and Tonya decided to form a team and take part in programming contests. Participants are usually offered several problems during programming contests. Long before the start the friends decided that they will implement a problem if at least two of them are sure about the solution. Otherwise, the friends won't write the problem's solution.
This contest offers *n* problems to the participants. For each problem we know, which friend is sure about the solution. Help the friends find the number of problems for which they will write a solution.
|
The first input line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems in the contest. Then *n* lines contain three integers each, each integer is either 0 or 1. If the first number in the line equals 1, then Petya is sure about the problem's solution, otherwise he isn't sure. The second number shows Vasya's view on the solution, the third number shows Tonya's view. The numbers on the lines are separated by spaces.
|
Print a single integer — the number of problems the friends will implement on the contest.
|
[
"3\n1 1 0\n1 1 1\n1 0 0\n",
"2\n1 0 0\n0 1 1\n"
] |
[
"2\n",
"1\n"
] |
In the first sample Petya and Vasya are sure that they know how to solve the first problem and all three of them know how to solve the second problem. That means that they will write solutions for these problems. Only Petya is sure about the solution for the third problem, but that isn't enough, so the friends won't take it.
In the second sample the friends will only implement the second problem, as Vasya and Tonya are sure about the solution.
| 500
|
[
{
"input": "3\n1 1 0\n1 1 1\n1 0 0",
"output": "2"
},
{
"input": "2\n1 0 0\n0 1 1",
"output": "1"
},
{
"input": "1\n1 0 0",
"output": "0"
},
{
"input": "2\n1 0 0\n1 1 1",
"output": "1"
},
{
"input": "5\n1 0 0\n0 1 0\n1 1 1\n0 0 1\n0 0 0",
"output": "1"
},
{
"input": "10\n0 1 0\n0 1 0\n1 1 0\n1 0 0\n0 0 1\n0 1 1\n1 1 1\n1 1 0\n0 0 0\n0 0 0",
"output": "4"
},
{
"input": "15\n0 1 0\n1 0 0\n1 1 0\n1 1 1\n0 1 0\n0 0 1\n1 0 1\n1 0 1\n1 0 1\n0 0 0\n1 1 1\n1 1 0\n0 1 1\n1 1 0\n1 1 1",
"output": "10"
},
{
"input": "50\n0 0 0\n0 1 1\n1 1 1\n0 1 0\n1 0 1\n1 1 1\n0 0 1\n1 0 0\n1 1 0\n1 0 1\n0 1 0\n0 0 1\n1 1 0\n0 1 0\n1 1 0\n0 0 0\n1 1 1\n1 0 1\n0 0 1\n1 1 0\n1 1 1\n0 1 1\n1 1 0\n0 0 0\n0 0 0\n1 1 1\n0 0 0\n1 1 1\n0 1 1\n0 0 1\n0 0 0\n0 0 0\n1 1 0\n1 1 0\n1 0 1\n1 0 0\n1 0 1\n1 0 1\n0 1 1\n1 1 0\n1 1 0\n0 1 0\n1 0 1\n0 0 0\n0 0 0\n0 0 0\n0 0 1\n1 1 1\n0 1 1\n1 0 1",
"output": "29"
},
{
"input": "1\n1 1 1",
"output": "1"
},
{
"input": "8\n0 0 0\n0 0 1\n0 0 0\n0 1 1\n1 0 0\n1 0 1\n1 1 0\n1 1 1",
"output": "4"
},
{
"input": "16\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "16"
}
] | 1,697,363,012
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 21
| 154
| 1,843,200
|
n = int(input())
total = 0
for i in range(n):
nums = input().split()
nums = map(int, nums)
if sum(nums) >= 2:
total += 1
print(total)
|
Title: Team
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day three best friends Petya, Vasya and Tonya decided to form a team and take part in programming contests. Participants are usually offered several problems during programming contests. Long before the start the friends decided that they will implement a problem if at least two of them are sure about the solution. Otherwise, the friends won't write the problem's solution.
This contest offers *n* problems to the participants. For each problem we know, which friend is sure about the solution. Help the friends find the number of problems for which they will write a solution.
Input Specification:
The first input line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems in the contest. Then *n* lines contain three integers each, each integer is either 0 or 1. If the first number in the line equals 1, then Petya is sure about the problem's solution, otherwise he isn't sure. The second number shows Vasya's view on the solution, the third number shows Tonya's view. The numbers on the lines are separated by spaces.
Output Specification:
Print a single integer — the number of problems the friends will implement on the contest.
Demo Input:
['3\n1 1 0\n1 1 1\n1 0 0\n', '2\n1 0 0\n0 1 1\n']
Demo Output:
['2\n', '1\n']
Note:
In the first sample Petya and Vasya are sure that they know how to solve the first problem and all three of them know how to solve the second problem. That means that they will write solutions for these problems. Only Petya is sure about the solution for the third problem, but that isn't enough, so the friends won't take it.
In the second sample the friends will only implement the second problem, as Vasya and Tonya are sure about the solution.
|
```python
n = int(input())
total = 0
for i in range(n):
nums = input().split()
nums = map(int, nums)
if sum(nums) >= 2:
total += 1
print(total)
```
| 3
|
|
300
|
B
|
Coach
|
PROGRAMMING
| 1,500
|
[
"brute force",
"dfs and similar",
"graphs"
] | null | null |
A programming coach has *n* students to teach. We know that *n* is divisible by 3. Let's assume that all students are numbered from 1 to *n*, inclusive.
Before the university programming championship the coach wants to split all students into groups of three. For some pairs of students we know that they want to be on the same team. Besides, if the *i*-th student wants to be on the same team with the *j*-th one, then the *j*-th student wants to be on the same team with the *i*-th one. The coach wants the teams to show good results, so he wants the following condition to hold: if the *i*-th student wants to be on the same team with the *j*-th, then the *i*-th and the *j*-th students must be on the same team. Also, it is obvious that each student must be on exactly one team.
Help the coach and divide the teams the way he wants.
|
The first line of the input contains integers *n* and *m* (3<=≤<=*n*<=≤<=48, . Then follow *m* lines, each contains a pair of integers *a**i*,<=*b**i* (1<=≤<=*a**i*<=<<=*b**i*<=≤<=*n*) — the pair *a**i*,<=*b**i* means that students with numbers *a**i* and *b**i* want to be on the same team.
It is guaranteed that *n* is divisible by 3. It is guaranteed that each pair *a**i*,<=*b**i* occurs in the input at most once.
|
If the required division into teams doesn't exist, print number -1. Otherwise, print lines. In each line print three integers *x**i*, *y**i*, *z**i* (1<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=*n*) — the *i*-th team.
If there are multiple answers, you are allowed to print any of them.
|
[
"3 0\n",
"6 4\n1 2\n2 3\n3 4\n5 6\n",
"3 3\n1 2\n2 3\n1 3\n"
] |
[
"3 2 1 \n",
"-1\n",
"3 2 1 \n"
] |
none
| 1,000
|
[
{
"input": "3 0",
"output": "3 2 1 "
},
{
"input": "6 4\n1 2\n2 3\n3 4\n5 6",
"output": "-1"
},
{
"input": "3 3\n1 2\n2 3\n1 3",
"output": "3 2 1 "
},
{
"input": "6 3\n1 2\n3 4\n5 6",
"output": "-1"
},
{
"input": "15 9\n1 4\n1 6\n2 7\n2 11\n4 6\n5 12\n7 11\n9 14\n13 15",
"output": "6 4 1 \n11 7 2 \n12 5 3 \n14 9 8 \n15 13 10 "
},
{
"input": "3 1\n1 3",
"output": "3 2 1 "
},
{
"input": "15 13\n1 9\n1 11\n2 7\n2 12\n3 8\n3 15\n4 10\n5 6\n5 14\n6 14\n7 12\n8 15\n9 11",
"output": "11 9 1 \n12 7 2 \n14 6 5 \n15 8 3 \n13 10 4 "
},
{
"input": "36 27\n1 34\n2 18\n2 20\n3 9\n3 21\n4 5\n4 25\n5 25\n6 13\n6 22\n8 23\n8 31\n9 21\n10 14\n11 17\n11 19\n13 22\n15 24\n15 26\n17 19\n18 20\n23 31\n24 26\n28 29\n28 33\n29 33\n32 36",
"output": "19 17 11 \n20 18 2 \n21 9 3 \n22 13 6 \n25 5 4 \n26 24 15 \n31 23 8 \n33 29 28 \n14 10 7 \n34 12 1 \n36 32 16 \n35 30 27 "
},
{
"input": "18 12\n1 10\n2 4\n2 8\n3 15\n3 18\n4 8\n5 6\n9 13\n12 14\n12 16\n14 16\n15 18",
"output": "8 4 2 \n16 14 12 \n18 15 3 \n7 6 5 \n11 10 1 \n17 13 9 "
},
{
"input": "39 27\n1 2\n1 25\n2 25\n4 16\n5 22\n5 28\n6 7\n6 26\n7 26\n8 24\n10 31\n10 38\n11 17\n11 21\n12 35\n12 37\n13 34\n17 21\n18 23\n19 39\n22 28\n27 29\n27 36\n29 36\n31 38\n32 33\n35 37",
"output": "21 17 11 \n25 2 1 \n26 7 6 \n28 22 5 \n36 29 27 \n37 35 12 \n38 31 10 \n16 4 3 \n23 18 9 \n24 14 8 \n33 32 15 \n34 20 13 \n39 30 19 "
},
{
"input": "12 7\n1 2\n4 5\n6 12\n7 8\n9 10\n9 11\n10 11",
"output": "-1"
},
{
"input": "33 22\n3 9\n3 28\n4 12\n5 11\n5 31\n6 18\n8 15\n8 29\n9 28\n10 22\n11 31\n13 14\n15 29\n16 23\n16 27\n17 25\n17 32\n19 21\n20 30\n23 27\n24 33\n25 32",
"output": "-1"
},
{
"input": "18 8\n1 14\n2 16\n4 7\n5 11\n8 9\n8 12\n9 12\n10 18",
"output": "12 9 8 \n7 4 3 \n11 6 5 \n14 13 1 \n16 15 2 \n18 17 10 "
},
{
"input": "27 21\n1 3\n2 9\n2 11\n5 16\n5 25\n7 26\n8 14\n8 22\n9 11\n10 17\n10 27\n12 21\n13 20\n13 23\n14 22\n15 18\n15 19\n16 25\n17 27\n18 19\n20 23",
"output": "11 9 2 \n19 18 15 \n22 14 8 \n23 20 13 \n25 16 5 \n27 17 10 \n4 3 1 \n21 12 6 \n26 24 7 "
},
{
"input": "24 21\n1 14\n2 6\n3 4\n3 19\n4 19\n5 7\n5 21\n7 21\n8 18\n8 23\n9 15\n9 16\n10 12\n10 17\n11 22\n12 17\n13 20\n13 24\n15 16\n18 23\n20 24",
"output": "-1"
},
{
"input": "45 31\n1 5\n2 45\n3 29\n3 30\n4 16\n4 32\n6 40\n7 13\n7 25\n8 42\n10 31\n11 20\n11 26\n12 27\n12 34\n13 25\n14 24\n14 43\n15 36\n15 37\n16 32\n18 19\n18 33\n19 33\n20 26\n23 41\n24 43\n27 34\n28 39\n29 30\n36 37",
"output": "25 13 7 \n26 20 11 \n30 29 3 \n32 16 4 \n33 19 18 \n34 27 12 \n37 36 15 \n43 24 14 \n9 5 1 \n31 17 10 \n39 28 21 \n40 22 6 \n41 35 23 \n42 38 8 \n45 44 2 "
},
{
"input": "18 9\n1 16\n2 17\n4 6\n5 18\n7 8\n7 15\n8 15\n9 11\n10 13",
"output": "-1"
},
{
"input": "6 6\n1 6\n1 3\n3 6\n2 4\n4 5\n2 5",
"output": "5 4 2 \n6 3 1 "
},
{
"input": "48 48\n7 39\n39 45\n7 45\n25 26\n26 31\n25 31\n4 11\n11 19\n4 19\n8 16\n16 37\n8 37\n14 22\n22 33\n14 33\n6 12\n12 46\n6 46\n29 44\n44 48\n29 48\n15 27\n27 41\n15 41\n3 24\n24 34\n3 34\n13 20\n20 47\n13 47\n5 9\n9 36\n5 36\n21 40\n40 43\n21 43\n2 35\n35 38\n2 38\n23 28\n28 42\n23 42\n1 10\n10 32\n1 32\n17 18\n18 30\n17 30",
"output": "19 11 4 \n30 18 17 \n31 26 25 \n32 10 1 \n33 22 14 \n34 24 3 \n36 9 5 \n37 16 8 \n38 35 2 \n41 27 15 \n42 28 23 \n43 40 21 \n45 39 7 \n46 12 6 \n47 20 13 \n48 44 29 "
},
{
"input": "12 9\n1 2\n2 4\n1 3\n5 6\n6 8\n5 7\n9 10\n10 12\n9 11",
"output": "-1"
},
{
"input": "9 7\n1 2\n3 4\n5 6\n7 8\n2 3\n2 5\n2 7",
"output": "-1"
},
{
"input": "9 3\n4 5\n6 7\n8 9",
"output": "5 4 1 \n7 6 2 \n9 8 3 "
},
{
"input": "6 2\n3 4\n5 6",
"output": "4 3 1 \n6 5 2 "
},
{
"input": "9 7\n1 2\n2 3\n1 3\n4 5\n4 6\n4 7\n4 8",
"output": "-1"
},
{
"input": "6 1\n1 2",
"output": "3 2 1 \n6 5 4 "
},
{
"input": "48 1\n1 2",
"output": "3 2 1 \n6 5 4 \n9 8 7 \n12 11 10 \n15 14 13 \n18 17 16 \n21 20 19 \n24 23 22 \n27 26 25 \n30 29 28 \n33 32 31 \n36 35 34 \n39 38 37 \n42 41 40 \n45 44 43 \n48 47 46 "
}
] | 1,689,230,250
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 27
| 312
| 2,252,800
|
import sys
from collections import defaultdict
input = sys.stdin.readline
n, m = map(int, input().split())
d = defaultdict(list)
for i in range(m):
u, v = map(int, input().split())
d[u].append(v)
d[v].append(u)
v = [0] * (n + 1)
p = [-1] * (n + 1)
ans = []
al = []
db = []
for i in range(1, n + 1):
if(not v[i]):
v[i] = 1
if(len(d[i]) == 2):
if(v[d[i][0]] or v[d[i][1]]):
print(-1)
exit()
ans.append([i, d[i][0], d[i][1]])
v[d[i][0]], v[d[i][1]] = 1, 1
elif(len(d[i]) == 1):
if(v[d[i][0]]):
print(-1)
exit()
db.append([i, d[i][0]])
v[d[i][0]] = 1
elif(len(d[i]) == 0):
al.append(i)
else:
print(-1)
exit()
if((len(al) - len(db)) % 3 == 0 and len(al) >= len(db)):
for i in ans:
print(*i)
for i in range(len(db)):
print(al[i], db[i][0], db[i][1])
for i in range(len(db), len(al), 3):
print(al[i], al[i + 1], al[i + 2])
else:
print(-1)
|
Title: Coach
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A programming coach has *n* students to teach. We know that *n* is divisible by 3. Let's assume that all students are numbered from 1 to *n*, inclusive.
Before the university programming championship the coach wants to split all students into groups of three. For some pairs of students we know that they want to be on the same team. Besides, if the *i*-th student wants to be on the same team with the *j*-th one, then the *j*-th student wants to be on the same team with the *i*-th one. The coach wants the teams to show good results, so he wants the following condition to hold: if the *i*-th student wants to be on the same team with the *j*-th, then the *i*-th and the *j*-th students must be on the same team. Also, it is obvious that each student must be on exactly one team.
Help the coach and divide the teams the way he wants.
Input Specification:
The first line of the input contains integers *n* and *m* (3<=≤<=*n*<=≤<=48, . Then follow *m* lines, each contains a pair of integers *a**i*,<=*b**i* (1<=≤<=*a**i*<=<<=*b**i*<=≤<=*n*) — the pair *a**i*,<=*b**i* means that students with numbers *a**i* and *b**i* want to be on the same team.
It is guaranteed that *n* is divisible by 3. It is guaranteed that each pair *a**i*,<=*b**i* occurs in the input at most once.
Output Specification:
If the required division into teams doesn't exist, print number -1. Otherwise, print lines. In each line print three integers *x**i*, *y**i*, *z**i* (1<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=*n*) — the *i*-th team.
If there are multiple answers, you are allowed to print any of them.
Demo Input:
['3 0\n', '6 4\n1 2\n2 3\n3 4\n5 6\n', '3 3\n1 2\n2 3\n1 3\n']
Demo Output:
['3 2 1 \n', '-1\n', '3 2 1 \n']
Note:
none
|
```python
import sys
from collections import defaultdict
input = sys.stdin.readline
n, m = map(int, input().split())
d = defaultdict(list)
for i in range(m):
u, v = map(int, input().split())
d[u].append(v)
d[v].append(u)
v = [0] * (n + 1)
p = [-1] * (n + 1)
ans = []
al = []
db = []
for i in range(1, n + 1):
if(not v[i]):
v[i] = 1
if(len(d[i]) == 2):
if(v[d[i][0]] or v[d[i][1]]):
print(-1)
exit()
ans.append([i, d[i][0], d[i][1]])
v[d[i][0]], v[d[i][1]] = 1, 1
elif(len(d[i]) == 1):
if(v[d[i][0]]):
print(-1)
exit()
db.append([i, d[i][0]])
v[d[i][0]] = 1
elif(len(d[i]) == 0):
al.append(i)
else:
print(-1)
exit()
if((len(al) - len(db)) % 3 == 0 and len(al) >= len(db)):
for i in ans:
print(*i)
for i in range(len(db)):
print(al[i], db[i][0], db[i][1])
for i in range(len(db), len(al), 3):
print(al[i], al[i + 1], al[i + 2])
else:
print(-1)
```
| 3
|
|
492
|
A
|
Vanya and Cubes
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Vanya got *n* cubes. He decided to build a pyramid from them. Vanya wants to build the pyramid as follows: the top level of the pyramid must consist of 1 cube, the second level must consist of 1<=+<=2<==<=3 cubes, the third level must have 1<=+<=2<=+<=3<==<=6 cubes, and so on. Thus, the *i*-th level of the pyramid must have 1<=+<=2<=+<=...<=+<=(*i*<=-<=1)<=+<=*i* cubes.
Vanya wants to know what is the maximum height of the pyramid that he can make using the given cubes.
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=104) — the number of cubes given to Vanya.
|
Print the maximum possible height of the pyramid in the single line.
|
[
"1\n",
"25\n"
] |
[
"1\n",
"4\n"
] |
Illustration to the second sample:
| 500
|
[
{
"input": "1",
"output": "1"
},
{
"input": "25",
"output": "4"
},
{
"input": "2",
"output": "1"
},
{
"input": "4115",
"output": "28"
},
{
"input": "9894",
"output": "38"
},
{
"input": "7969",
"output": "35"
},
{
"input": "6560",
"output": "33"
},
{
"input": "4",
"output": "2"
},
{
"input": "3",
"output": "1"
},
{
"input": "5",
"output": "2"
},
{
"input": "19",
"output": "3"
},
{
"input": "20",
"output": "4"
},
{
"input": "9880",
"output": "38"
},
{
"input": "9879",
"output": "37"
},
{
"input": "7770",
"output": "35"
},
{
"input": "7769",
"output": "34"
},
{
"input": "2925",
"output": "25"
},
{
"input": "220",
"output": "10"
},
{
"input": "219",
"output": "9"
},
{
"input": "3046",
"output": "25"
},
{
"input": "7590",
"output": "34"
},
{
"input": "1014",
"output": "17"
},
{
"input": "7142",
"output": "34"
},
{
"input": "9999",
"output": "38"
},
{
"input": "10000",
"output": "38"
}
] | 1,684,590,329
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 1
| 46
| 0
|
n = int(input())
i = 1
while (i * (i + 1) * (2 * i + 1)) // 6 <= n:
i += 1
print(i - 1)
|
Title: Vanya and Cubes
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vanya got *n* cubes. He decided to build a pyramid from them. Vanya wants to build the pyramid as follows: the top level of the pyramid must consist of 1 cube, the second level must consist of 1<=+<=2<==<=3 cubes, the third level must have 1<=+<=2<=+<=3<==<=6 cubes, and so on. Thus, the *i*-th level of the pyramid must have 1<=+<=2<=+<=...<=+<=(*i*<=-<=1)<=+<=*i* cubes.
Vanya wants to know what is the maximum height of the pyramid that he can make using the given cubes.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=104) — the number of cubes given to Vanya.
Output Specification:
Print the maximum possible height of the pyramid in the single line.
Demo Input:
['1\n', '25\n']
Demo Output:
['1\n', '4\n']
Note:
Illustration to the second sample:
|
```python
n = int(input())
i = 1
while (i * (i + 1) * (2 * i + 1)) // 6 <= n:
i += 1
print(i - 1)
```
| 0
|
|
978
|
B
|
File Name
|
PROGRAMMING
| 800
|
[
"greedy",
"strings"
] | null | null |
You can not just take the file and send it. When Polycarp trying to send a file in the social network "Codehorses", he encountered an unexpected problem. If the name of the file contains three or more "x" (lowercase Latin letters "x") in a row, the system considers that the file content does not correspond to the social network topic. In this case, the file is not sent and an error message is displayed.
Determine the minimum number of characters to remove from the file name so after that the name does not contain "xxx" as a substring. Print 0 if the file name does not initially contain a forbidden substring "xxx".
You can delete characters in arbitrary positions (not necessarily consecutive). If you delete a character, then the length of a string is reduced by $1$. For example, if you delete the character in the position $2$ from the string "exxxii", then the resulting string is "exxii".
|
The first line contains integer $n$ $(3 \le n \le 100)$ — the length of the file name.
The second line contains a string of length $n$ consisting of lowercase Latin letters only — the file name.
|
Print the minimum number of characters to remove from the file name so after that the name does not contain "xxx" as a substring. If initially the file name dost not contain a forbidden substring "xxx", print 0.
|
[
"6\nxxxiii\n",
"5\nxxoxx\n",
"10\nxxxxxxxxxx\n"
] |
[
"1\n",
"0\n",
"8\n"
] |
In the first example Polycarp tried to send a file with name contains number $33$, written in Roman numerals. But he can not just send the file, because it name contains three letters "x" in a row. To send the file he needs to remove any one of this letters.
| 0
|
[
{
"input": "6\nxxxiii",
"output": "1"
},
{
"input": "5\nxxoxx",
"output": "0"
},
{
"input": "10\nxxxxxxxxxx",
"output": "8"
},
{
"input": "100\nxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx",
"output": "98"
},
{
"input": "99\nxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxaxxa",
"output": "0"
},
{
"input": "3\nxxx",
"output": "1"
},
{
"input": "77\naaabbbcccdddeeefffggghhhiiijjjkkklllmmmnnnooopppqqqrrrssstttuuuvvvwwwxxyyyzzz",
"output": "0"
},
{
"input": "100\nuxxxxxlmexxxxxxxwnxxexxxxxcxxfydxxxxxxvmdxxxxxxisxxxxxxxxidkxxxpxxxxxxxxmnuxxxxjxxxqcxxwmxxxxxxxxmrx",
"output": "41"
},
{
"input": "100\nxxxxxxxxxxxjtxxxxxxxxcxxxxxxcfxxxxzxxxxxxgxxxxxbxxxxbxxxxxxxxdycxxxxokixxxkizxxgcxxxxxxxxexxxxxfxxxc",
"output": "49"
},
{
"input": "100\nuxxxxxlmexxxxxxxwnxxexxxxxcxxfydxxxxxxvmdxxxxxxisxxxxxxxxidkxxxpxxxxxxxxmnuxxxxjxxxqcxxwmxxxxxwxxxxx",
"output": "41"
},
{
"input": "34\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "0"
},
{
"input": "5\nfcyju",
"output": "0"
},
{
"input": "100\nihygyvdvyeifomhxhkhdkimquvgallbqharcyriyqkidnwykozuhvkwdldlztpabgyuflikychqpdenwzgtlzotyumjgdsrbxxxx",
"output": "2"
}
] | 1,673,970,037
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 7
| 77
| 0
|
lent =int(input())
b = input()
lst = []
for j in b:
lst.append(j)
ind = lst.index('x')
nu = 0
for i in lst:
lst_s = set(lst)
if len(lst_s) == 1:
nu=lent-2
break
else:
if lst[ind+1] == lst[ind+2] == 'x':
lst.remove('x')
nu +=1
print(nu)
|
Title: File Name
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You can not just take the file and send it. When Polycarp trying to send a file in the social network "Codehorses", he encountered an unexpected problem. If the name of the file contains three or more "x" (lowercase Latin letters "x") in a row, the system considers that the file content does not correspond to the social network topic. In this case, the file is not sent and an error message is displayed.
Determine the minimum number of characters to remove from the file name so after that the name does not contain "xxx" as a substring. Print 0 if the file name does not initially contain a forbidden substring "xxx".
You can delete characters in arbitrary positions (not necessarily consecutive). If you delete a character, then the length of a string is reduced by $1$. For example, if you delete the character in the position $2$ from the string "exxxii", then the resulting string is "exxii".
Input Specification:
The first line contains integer $n$ $(3 \le n \le 100)$ — the length of the file name.
The second line contains a string of length $n$ consisting of lowercase Latin letters only — the file name.
Output Specification:
Print the minimum number of characters to remove from the file name so after that the name does not contain "xxx" as a substring. If initially the file name dost not contain a forbidden substring "xxx", print 0.
Demo Input:
['6\nxxxiii\n', '5\nxxoxx\n', '10\nxxxxxxxxxx\n']
Demo Output:
['1\n', '0\n', '8\n']
Note:
In the first example Polycarp tried to send a file with name contains number $33$, written in Roman numerals. But he can not just send the file, because it name contains three letters "x" in a row. To send the file he needs to remove any one of this letters.
|
```python
lent =int(input())
b = input()
lst = []
for j in b:
lst.append(j)
ind = lst.index('x')
nu = 0
for i in lst:
lst_s = set(lst)
if len(lst_s) == 1:
nu=lent-2
break
else:
if lst[ind+1] == lst[ind+2] == 'x':
lst.remove('x')
nu +=1
print(nu)
```
| 0
|
|
59
|
A
|
Word
|
PROGRAMMING
| 800
|
[
"implementation",
"strings"
] |
A. Word
|
2
|
256
|
Vasya is very upset that many people on the Net mix uppercase and lowercase letters in one word. That's why he decided to invent an extension for his favorite browser that would change the letters' register in every word so that it either only consisted of lowercase letters or, vice versa, only of uppercase ones. At that as little as possible letters should be changed in the word. For example, the word HoUse must be replaced with house, and the word ViP — with VIP. If a word contains an equal number of uppercase and lowercase letters, you should replace all the letters with lowercase ones. For example, maTRIx should be replaced by matrix. Your task is to use the given method on one given word.
|
The first line contains a word *s* — it consists of uppercase and lowercase Latin letters and possesses the length from 1 to 100.
|
Print the corrected word *s*. If the given word *s* has strictly more uppercase letters, make the word written in the uppercase register, otherwise - in the lowercase one.
|
[
"HoUse\n",
"ViP\n",
"maTRIx\n"
] |
[
"house\n",
"VIP\n",
"matrix\n"
] |
none
| 500
|
[
{
"input": "HoUse",
"output": "house"
},
{
"input": "ViP",
"output": "VIP"
},
{
"input": "maTRIx",
"output": "matrix"
},
{
"input": "BNHWpnpawg",
"output": "bnhwpnpawg"
},
{
"input": "VTYGP",
"output": "VTYGP"
},
{
"input": "CHNenu",
"output": "chnenu"
},
{
"input": "ERPZGrodyu",
"output": "erpzgrodyu"
},
{
"input": "KSXBXWpebh",
"output": "KSXBXWPEBH"
},
{
"input": "qvxpqullmcbegsdskddortcvxyqlbvxmmkhevovnezubvpvnrcajpxraeaxizgaowtfkzywvhnbgzsxbhkaipcmoumtikkiyyaiv",
"output": "qvxpqullmcbegsdskddortcvxyqlbvxmmkhevovnezubvpvnrcajpxraeaxizgaowtfkzywvhnbgzsxbhkaipcmoumtikkiyyaiv"
},
{
"input": "Amnhaxtaopjzrkqlbroiyipitndczpunwygstmzevgyjdzyanxkdqnvgkikfabwouwkkbzuiuvgvxgpizsvqsbwepktpdrgdkmfd",
"output": "amnhaxtaopjzrkqlbroiyipitndczpunwygstmzevgyjdzyanxkdqnvgkikfabwouwkkbzuiuvgvxgpizsvqsbwepktpdrgdkmfd"
},
{
"input": "ISAGFJFARYFBLOPQDSHWGMCNKMFTLVFUGNJEWGWNBLXUIATXEkqiettmmjgydwcpafqrppdsrrrtguinqbgmzzfqwonkpgpcwenv",
"output": "isagfjfaryfblopqdshwgmcnkmftlvfugnjewgwnblxuiatxekqiettmmjgydwcpafqrppdsrrrtguinqbgmzzfqwonkpgpcwenv"
},
{
"input": "XHRPXZEGHSOCJPICUIXSKFUZUPYTSGJSDIYBCMNMNBPNDBXLXBzhbfnqvwcffvrdhtickyqhupmcehlsyvncqmfhautvxudqdhgg",
"output": "xhrpxzeghsocjpicuixskfuzupytsgjsdiybcmnmnbpndbxlxbzhbfnqvwcffvrdhtickyqhupmcehlsyvncqmfhautvxudqdhgg"
},
{
"input": "RJIQZMJCIMSNDBOHBRAWIENODSALETAKGKPYUFGVEFGCBRENZGAdkcetqjljtmttlonpekcovdzebzdkzggwfsxhapmjkdbuceak",
"output": "RJIQZMJCIMSNDBOHBRAWIENODSALETAKGKPYUFGVEFGCBRENZGADKCETQJLJTMTTLONPEKCOVDZEBZDKZGGWFSXHAPMJKDBUCEAK"
},
{
"input": "DWLWOBHNMMGTFOLFAECKBRNNGLYLYDXTGTVRLMEESZOIUATZZZXUFUZDLSJXMEVRTESSFBWLNZZCLCQWEVNNUCXYVHNGNXHCBDFw",
"output": "DWLWOBHNMMGTFOLFAECKBRNNGLYLYDXTGTVRLMEESZOIUATZZZXUFUZDLSJXMEVRTESSFBWLNZZCLCQWEVNNUCXYVHNGNXHCBDFW"
},
{
"input": "NYCNHJWGBOCOTSPETKKHVWFGAQYNHOVJWJHCIEFOUQZXOYUIEQDZALFKTEHTVDBVJMEUBJUBCMNVPWGDPNCHQHZJRCHYRFPVIGUB",
"output": "NYCNHJWGBOCOTSPETKKHVWFGAQYNHOVJWJHCIEFOUQZXOYUIEQDZALFKTEHTVDBVJMEUBJUBCMNVPWGDPNCHQHZJRCHYRFPVIGUB"
},
{
"input": "igxoixiecetohtgjgbqzvlaobkhstejxdklghowtvwunnnvauriohuspsdmpzckprwajyxldoyckgjivjpmbfqtszmtocovxwge",
"output": "igxoixiecetohtgjgbqzvlaobkhstejxdklghowtvwunnnvauriohuspsdmpzckprwajyxldoyckgjivjpmbfqtszmtocovxwge"
},
{
"input": "Ykkekrsqolzryiwsmdlnbmfautxxxauoojrddvwklgnlyrfcvhorrzbmtcrvpaypqhcffdqhwziipyyskcmztjprjqvmzzqhqnw",
"output": "ykkekrsqolzryiwsmdlnbmfautxxxauoojrddvwklgnlyrfcvhorrzbmtcrvpaypqhcffdqhwziipyyskcmztjprjqvmzzqhqnw"
},
{
"input": "YQOMLKYAORUQQUCQZCDYMIVDHGWZFFRMUVTAWCHERFPMNRYRIkgqrciokgajamehmcxgerpudvsqyonjonsxgbnefftzmygncks",
"output": "yqomlkyaoruqqucqzcdymivdhgwzffrmuvtawcherfpmnryrikgqrciokgajamehmcxgerpudvsqyonjonsxgbnefftzmygncks"
},
{
"input": "CDOZDPBVVVHNBJVBYHEOXWFLJKRWJCAJMIFCOZWWYFKVWOGTVJcuusigdqfkumewjtdyitveeiaybwrhomrwmpdipjwiuxfnwuz",
"output": "CDOZDPBVVVHNBJVBYHEOXWFLJKRWJCAJMIFCOZWWYFKVWOGTVJCUUSIGDQFKUMEWJTDYITVEEIAYBWRHOMRWMPDIPJWIUXFNWUZ"
},
{
"input": "WHIUVEXHVOOIJIDVJVPQUBJMEVPMPDKQWJKFBZSGSKUXMIPPMJWuckzcpxosodcjaaakvlxpbiigsiauviilylnnqlyucziihqg",
"output": "WHIUVEXHVOOIJIDVJVPQUBJMEVPMPDKQWJKFBZSGSKUXMIPPMJWUCKZCPXOSODCJAAAKVLXPBIIGSIAUVIILYLNNQLYUCZIIHQG"
},
{
"input": "VGHUNFOXKETUYMZDJNGTAOIOANYXSGYNFOGOFFLDAWEUKYFOZXCJTCAFXZYLQZERYZLRSQXYQGAPCSUDPMEYTNCTTTMFAGVDWBO",
"output": "VGHUNFOXKETUYMZDJNGTAOIOANYXSGYNFOGOFFLDAWEUKYFOZXCJTCAFXZYLQZERYZLRSQXYQGAPCSUDPMEYTNCTTTMFAGVDWBO"
},
{
"input": "EDUANHCQDOCJHFONTTSWBUJSTTIXBIXMAIUFSGFLXWAYIURTVAVZPYQDLAWIGCLMPHXCEFCJPFAAHXVNGQUFNHADAIUAZIDMHDd",
"output": "EDUANHCQDOCJHFONTTSWBUJSTTIXBIXMAIUFSGFLXWAYIURTVAVZPYQDLAWIGCLMPHXCEFCJPFAAHXVNGQUFNHADAIUAZIDMHDD"
},
{
"input": "EBWOVSNLYTWWXrnovgugogtjahnmatomubebyxakas",
"output": "ebwovsnlytwwxrnovgugogtjahnmatomubebyxakas"
},
{
"input": "AORNNDKTRLRVGDPXJKXFTPFpopuzrlqumrxssskvbm",
"output": "AORNNDKTRLRVGDPXJKXFTPFPOPUZRLQUMRXSSSKVBM"
},
{
"input": "DBBZJCWQEVGYHEEUHJAWRHBDPsnplijbwtdibqrrheebfxqcvn",
"output": "dbbzjcwqevgyheeuhjawrhbdpsnplijbwtdibqrrheebfxqcvn"
},
{
"input": "t",
"output": "t"
},
{
"input": "N",
"output": "N"
},
{
"input": "kv",
"output": "kv"
},
{
"input": "Ur",
"output": "ur"
},
{
"input": "CN",
"output": "CN"
}
] | 1,576,473,152
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 30
| 218
| 0
|
s=input()
l=0
u=0
sz=len(s)
for x in s:
if (ord(x)-65)<26:
u+=1
else:
l+=1
if l>=(sz/2):
print(s.lower())
else:
print(s.upper())
|
Title: Word
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Vasya is very upset that many people on the Net mix uppercase and lowercase letters in one word. That's why he decided to invent an extension for his favorite browser that would change the letters' register in every word so that it either only consisted of lowercase letters or, vice versa, only of uppercase ones. At that as little as possible letters should be changed in the word. For example, the word HoUse must be replaced with house, and the word ViP — with VIP. If a word contains an equal number of uppercase and lowercase letters, you should replace all the letters with lowercase ones. For example, maTRIx should be replaced by matrix. Your task is to use the given method on one given word.
Input Specification:
The first line contains a word *s* — it consists of uppercase and lowercase Latin letters and possesses the length from 1 to 100.
Output Specification:
Print the corrected word *s*. If the given word *s* has strictly more uppercase letters, make the word written in the uppercase register, otherwise - in the lowercase one.
Demo Input:
['HoUse\n', 'ViP\n', 'maTRIx\n']
Demo Output:
['house\n', 'VIP\n', 'matrix\n']
Note:
none
|
```python
s=input()
l=0
u=0
sz=len(s)
for x in s:
if (ord(x)-65)<26:
u+=1
else:
l+=1
if l>=(sz/2):
print(s.lower())
else:
print(s.upper())
```
| 3.9455
|
544
|
B
|
Sea and Islands
|
PROGRAMMING
| 1,400
|
[
"constructive algorithms",
"implementation"
] | null | null |
A map of some object is a rectangular field consisting of *n* rows and *n* columns. Each cell is initially occupied by the sea but you can cover some some cells of the map with sand so that exactly *k* islands appear on the map. We will call a set of sand cells to be island if it is possible to get from each of them to each of them by moving only through sand cells and by moving from a cell only to a side-adjacent cell. The cells are called to be side-adjacent if they share a vertical or horizontal side. It is easy to see that islands do not share cells (otherwise they together form a bigger island).
Find a way to cover some cells with sand so that exactly *k* islands appear on the *n*<=×<=*n* map, or determine that no such way exists.
|
The single line contains two positive integers *n*, *k* (1<=≤<=*n*<=≤<=100, 0<=≤<=*k*<=≤<=*n*2) — the size of the map and the number of islands you should form.
|
If the answer doesn't exist, print "NO" (without the quotes) in a single line.
Otherwise, print "YES" in the first line. In the next *n* lines print the description of the map. Each of the lines of the description must consist only of characters 'S' and 'L', where 'S' is a cell that is occupied by the sea and 'L' is the cell covered with sand. The length of each line of the description must equal *n*.
If there are multiple answers, you may print any of them.
You should not maximize the sizes of islands.
|
[
"5 2\n",
"5 25\n"
] |
[
"YES\nSSSSS\nLLLLL\nSSSSS\nLLLLL\nSSSSS\n",
"NO\n"
] |
none
| 1,000
|
[
{
"input": "5 2",
"output": "YES\nSSSSS\nLLLLL\nSSSSS\nLLLLL\nSSSSS"
},
{
"input": "5 25",
"output": "NO"
},
{
"input": "82 6047",
"output": "NO"
},
{
"input": "6 5",
"output": "YES\nLSLSLS\nSLSLSS\nSSSSSS\nSSSSSS\nSSSSSS\nSSSSSS"
},
{
"input": "10 80",
"output": "NO"
},
{
"input": "48 1279",
"output": "NO"
},
{
"input": "40 1092",
"output": "NO"
},
{
"input": "9 12",
"output": "YES\nLSLSLSLSL\nSLSLSLSLS\nLSLSLSSSS\nSSSSSSSSS\nSSSSSSSSS\nSSSSSSSSS\nSSSSSSSSS\nSSSSSSSSS\nSSSSSSSSS"
},
{
"input": "43 146",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSS..."
},
{
"input": "100 5000",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS..."
},
{
"input": "100 4999",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS..."
},
{
"input": "100 5001",
"output": "NO"
},
{
"input": "99 4901",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nS..."
},
{
"input": "99 4900",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nS..."
},
{
"input": "99 4902",
"output": "NO"
},
{
"input": "99 9801",
"output": "NO"
},
{
"input": "99 10",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nS..."
},
{
"input": "99 1",
"output": "YES\nLSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nS..."
},
{
"input": "100 10000",
"output": "NO"
},
{
"input": "100 10",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS..."
},
{
"input": "50 1200",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL..."
},
{
"input": "50 1438",
"output": "NO"
},
{
"input": "50 2447",
"output": "NO"
},
{
"input": "49 1719",
"output": "NO"
},
{
"input": "51 1996",
"output": "NO"
},
{
"input": "51 1981",
"output": "NO"
},
{
"input": "34 1060",
"output": "NO"
},
{
"input": "74 3901",
"output": "NO"
},
{
"input": "65 617",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS..."
},
{
"input": "89 497",
"output": "YES\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS\nLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSL\nSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLSLS..."
},
{
"input": "34 621",
"output": "NO"
},
{
"input": "1 0",
"output": "YES\nS"
},
{
"input": "10 0",
"output": "YES\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS\nSSSSSSSSSS"
},
{
"input": "11 0",
"output": "YES\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS\nSSSSSSSSSSS"
},
{
"input": "99 0",
"output": "YES\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nS..."
},
{
"input": "100 0",
"output": "YES\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS\nSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSSS..."
},
{
"input": "1 1",
"output": "YES\nL"
},
{
"input": "2 1",
"output": "YES\nLS\nSS"
},
{
"input": "2 0",
"output": "YES\nSS\nSS"
},
{
"input": "2 2",
"output": "YES\nLS\nSL"
},
{
"input": "2 3",
"output": "NO"
},
{
"input": "2 4",
"output": "NO"
}
] | 1,431,020,972
| 4,772
|
Python 3
|
RUNTIME_ERROR
|
PRETESTS
| 0
| 30
| 0
|
import sys
def max(n):
if n % 2 == 0: return(int(n**2/2))
else: return(int(n**2/2)+1)
def get(n):
if n == 0:
return("S")
else:
return("L")
n = int(input())
k = int(input())
l = []
m = []
b = 1
count = k
if k > max(n):
print("NO")
sys.exit(0)
else:
for y in range(n):
m.append("S")
for x in range(n):
l.append(m.copy())
for x in range(n):
if count == 0:
break
if n % 2 == 0:
b = 1-b
for y in range(n):
if count == 0:
break
if b == 1:
l[x][y] = "L"
count-=1
b = 1-b
print("YES")
for x in range(n):
for y in range(n):
sys.stdout.write(l[x][y])
print()
|
Title: Sea and Islands
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A map of some object is a rectangular field consisting of *n* rows and *n* columns. Each cell is initially occupied by the sea but you can cover some some cells of the map with sand so that exactly *k* islands appear on the map. We will call a set of sand cells to be island if it is possible to get from each of them to each of them by moving only through sand cells and by moving from a cell only to a side-adjacent cell. The cells are called to be side-adjacent if they share a vertical or horizontal side. It is easy to see that islands do not share cells (otherwise they together form a bigger island).
Find a way to cover some cells with sand so that exactly *k* islands appear on the *n*<=×<=*n* map, or determine that no such way exists.
Input Specification:
The single line contains two positive integers *n*, *k* (1<=≤<=*n*<=≤<=100, 0<=≤<=*k*<=≤<=*n*2) — the size of the map and the number of islands you should form.
Output Specification:
If the answer doesn't exist, print "NO" (without the quotes) in a single line.
Otherwise, print "YES" in the first line. In the next *n* lines print the description of the map. Each of the lines of the description must consist only of characters 'S' and 'L', where 'S' is a cell that is occupied by the sea and 'L' is the cell covered with sand. The length of each line of the description must equal *n*.
If there are multiple answers, you may print any of them.
You should not maximize the sizes of islands.
Demo Input:
['5 2\n', '5 25\n']
Demo Output:
['YES\nSSSSS\nLLLLL\nSSSSS\nLLLLL\nSSSSS\n', 'NO\n']
Note:
none
|
```python
import sys
def max(n):
if n % 2 == 0: return(int(n**2/2))
else: return(int(n**2/2)+1)
def get(n):
if n == 0:
return("S")
else:
return("L")
n = int(input())
k = int(input())
l = []
m = []
b = 1
count = k
if k > max(n):
print("NO")
sys.exit(0)
else:
for y in range(n):
m.append("S")
for x in range(n):
l.append(m.copy())
for x in range(n):
if count == 0:
break
if n % 2 == 0:
b = 1-b
for y in range(n):
if count == 0:
break
if b == 1:
l[x][y] = "L"
count-=1
b = 1-b
print("YES")
for x in range(n):
for y in range(n):
sys.stdout.write(l[x][y])
print()
```
| -1
|
|
621
|
A
|
Wet Shark and Odd and Even
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
Today, Wet Shark is given *n* integers. Using any of these integers no more than once, Wet Shark wants to get maximum possible even (divisible by 2) sum. Please, calculate this value for Wet Shark.
Note, that if Wet Shark uses no integers from the *n* integers, the sum is an even integer 0.
|
The first line of the input contains one integer, *n* (1<=≤<=*n*<=≤<=100<=000). The next line contains *n* space separated integers given to Wet Shark. Each of these integers is in range from 1 to 109, inclusive.
|
Print the maximum possible even sum that can be obtained if we use some of the given integers.
|
[
"3\n1 2 3\n",
"5\n999999999 999999999 999999999 999999999 999999999\n"
] |
[
"6",
"3999999996"
] |
In the first sample, we can simply take all three integers for a total sum of 6.
In the second sample Wet Shark should take any four out of five integers 999 999 999.
| 500
|
[
{
"input": "3\n1 2 3",
"output": "6"
},
{
"input": "5\n999999999 999999999 999999999 999999999 999999999",
"output": "3999999996"
},
{
"input": "1\n1",
"output": "0"
},
{
"input": "15\n39 52 88 78 46 95 84 98 55 3 68 42 6 18 98",
"output": "870"
},
{
"input": "15\n59 96 34 48 8 72 67 90 15 85 7 90 97 47 25",
"output": "840"
},
{
"input": "15\n87 37 91 29 58 45 51 74 70 71 47 38 91 89 44",
"output": "922"
},
{
"input": "15\n11 81 49 7 11 14 30 67 29 50 90 81 77 18 59",
"output": "674"
},
{
"input": "15\n39 21 95 89 73 90 9 55 85 32 30 21 68 59 82",
"output": "848"
},
{
"input": "15\n59 70 48 54 26 67 84 39 40 18 77 69 70 88 93",
"output": "902"
},
{
"input": "15\n87 22 98 32 88 36 72 31 100 97 17 16 60 22 20",
"output": "798"
},
{
"input": "15\n15 63 51 13 37 9 43 19 55 79 57 60 50 59 31",
"output": "632"
},
{
"input": "1\n4",
"output": "4"
},
{
"input": "2\n1 4",
"output": "4"
},
{
"input": "3\n1 2 4",
"output": "6"
},
{
"input": "2\n9 3",
"output": "12"
},
{
"input": "2\n1000000000 1001",
"output": "1000000000"
},
{
"input": "3\n1 8 4",
"output": "12"
},
{
"input": "3\n7 4 4",
"output": "8"
},
{
"input": "5\n2 3 4 5 3",
"output": "14"
},
{
"input": "2\n4 5",
"output": "4"
},
{
"input": "3\n2 4 5",
"output": "6"
},
{
"input": "3\n2 2 3",
"output": "4"
},
{
"input": "2\n2 3",
"output": "2"
},
{
"input": "4\n2 3 7 7",
"output": "16"
},
{
"input": "2\n999999999 2",
"output": "2"
},
{
"input": "2\n2 5",
"output": "2"
},
{
"input": "3\n5 3 1",
"output": "8"
},
{
"input": "4\n3 2 5 7",
"output": "14"
}
] | 1,588,052,316
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 87
| 186
| 8,396,800
|
n=int(input())
l=list(map(int,input().split()))
e=[]
o=[]
for i in l:
if i%2==0:
e +=[i]
else:
o +=[i]
if len(o)%2==0:
print(sum(o)+sum(e))
else:
o.sort()
print(sum(e)+sum(o[1:]))
|
Title: Wet Shark and Odd and Even
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Today, Wet Shark is given *n* integers. Using any of these integers no more than once, Wet Shark wants to get maximum possible even (divisible by 2) sum. Please, calculate this value for Wet Shark.
Note, that if Wet Shark uses no integers from the *n* integers, the sum is an even integer 0.
Input Specification:
The first line of the input contains one integer, *n* (1<=≤<=*n*<=≤<=100<=000). The next line contains *n* space separated integers given to Wet Shark. Each of these integers is in range from 1 to 109, inclusive.
Output Specification:
Print the maximum possible even sum that can be obtained if we use some of the given integers.
Demo Input:
['3\n1 2 3\n', '5\n999999999 999999999 999999999 999999999 999999999\n']
Demo Output:
['6', '3999999996']
Note:
In the first sample, we can simply take all three integers for a total sum of 6.
In the second sample Wet Shark should take any four out of five integers 999 999 999.
|
```python
n=int(input())
l=list(map(int,input().split()))
e=[]
o=[]
for i in l:
if i%2==0:
e +=[i]
else:
o +=[i]
if len(o)%2==0:
print(sum(o)+sum(e))
else:
o.sort()
print(sum(e)+sum(o[1:]))
```
| 3
|
|
734
|
A
|
Anton and Danik
|
PROGRAMMING
| 800
|
[
"implementation",
"strings"
] | null | null |
Anton likes to play chess, and so does his friend Danik.
Once they have played *n* games in a row. For each game it's known who was the winner — Anton or Danik. None of the games ended with a tie.
Now Anton wonders, who won more games, he or Danik? Help him determine this.
|
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of games played.
The second line contains a string *s*, consisting of *n* uppercase English letters 'A' and 'D' — the outcome of each of the games. The *i*-th character of the string is equal to 'A' if the Anton won the *i*-th game and 'D' if Danik won the *i*-th game.
|
If Anton won more games than Danik, print "Anton" (without quotes) in the only line of the output.
If Danik won more games than Anton, print "Danik" (without quotes) in the only line of the output.
If Anton and Danik won the same number of games, print "Friendship" (without quotes).
|
[
"6\nADAAAA\n",
"7\nDDDAADA\n",
"6\nDADADA\n"
] |
[
"Anton\n",
"Danik\n",
"Friendship\n"
] |
In the first sample, Anton won 6 games, while Danik — only 1. Hence, the answer is "Anton".
In the second sample, Anton won 3 games and Danik won 4 games, so the answer is "Danik".
In the third sample, both Anton and Danik won 3 games and the answer is "Friendship".
| 500
|
[
{
"input": "6\nADAAAA",
"output": "Anton"
},
{
"input": "7\nDDDAADA",
"output": "Danik"
},
{
"input": "6\nDADADA",
"output": "Friendship"
},
{
"input": "10\nDDDDADDADD",
"output": "Danik"
},
{
"input": "40\nAAAAAAAAADDAAAAAAAAAAADADDAAAAAAAAAAADAA",
"output": "Anton"
},
{
"input": "200\nDDDDDDDADDDDDDAADADAADAAADAADADAAADDDADDDDDDADDDAADDDAADADDDDDADDDAAAADAAADDDDDAAADAADDDAAAADDADADDDAADDAADAAADAADAAAADDAADDADAAAADADDDAAAAAADDAADAADAADADDDAAADAAAADADDADAAAAAADADADDDADDDAADDADDDAAAAD",
"output": "Friendship"
},
{
"input": "1\nA",
"output": "Anton"
},
{
"input": "1\nD",
"output": "Danik"
},
{
"input": "2\nDA",
"output": "Friendship"
},
{
"input": "4\nDADA",
"output": "Friendship"
},
{
"input": "4\nDAAD",
"output": "Friendship"
},
{
"input": "3\nADD",
"output": "Danik"
},
{
"input": "3\nDAD",
"output": "Danik"
},
{
"input": "2\nDA",
"output": "Friendship"
},
{
"input": "379\nAADAAAAAADDAAAAAADAADADADDAAAAADADDAADAAAADDDADAAAAAAADAADAAAAAAADAAAAAAAAADAAAAAAADAAAAAAAAAAADDDADAAAAAAAADAADADAAAADAAAAAAAAAAAAAAAAADAAAADDDAADAAAAAAADAAADAAADAADDDADDAAADAAAAAADDDADDDAAADAAAADAAAAAAAAADAAADAAAAAAAAADAAAAAAAAAAAAAAAAAADADAAAAAAAAAAADAAAAADAAAADAAAAAAAAAAAAADADAADAAAAAAAADAADAAAAAAAADAAAAAAAADDDAAAAAADAAADAAAAAADAADAAAAAADAAAADADAADAAAAAADAAAADAADDAADAADAAA",
"output": "Anton"
}
] | 1,695,786,522
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 25
| 46
| 5,939,200
|
def antonandDanik():
n = int(input())
wonCode = input()
if wonCode.count('A') > wonCode.count('D'):
print("Anton")
elif wonCode.count('A') < wonCode.count('D'):
print("Danik")
else:
print("Friendship")
antonandDanik()
|
Title: Anton and Danik
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Anton likes to play chess, and so does his friend Danik.
Once they have played *n* games in a row. For each game it's known who was the winner — Anton or Danik. None of the games ended with a tie.
Now Anton wonders, who won more games, he or Danik? Help him determine this.
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of games played.
The second line contains a string *s*, consisting of *n* uppercase English letters 'A' and 'D' — the outcome of each of the games. The *i*-th character of the string is equal to 'A' if the Anton won the *i*-th game and 'D' if Danik won the *i*-th game.
Output Specification:
If Anton won more games than Danik, print "Anton" (without quotes) in the only line of the output.
If Danik won more games than Anton, print "Danik" (without quotes) in the only line of the output.
If Anton and Danik won the same number of games, print "Friendship" (without quotes).
Demo Input:
['6\nADAAAA\n', '7\nDDDAADA\n', '6\nDADADA\n']
Demo Output:
['Anton\n', 'Danik\n', 'Friendship\n']
Note:
In the first sample, Anton won 6 games, while Danik — only 1. Hence, the answer is "Anton".
In the second sample, Anton won 3 games and Danik won 4 games, so the answer is "Danik".
In the third sample, both Anton and Danik won 3 games and the answer is "Friendship".
|
```python
def antonandDanik():
n = int(input())
wonCode = input()
if wonCode.count('A') > wonCode.count('D'):
print("Anton")
elif wonCode.count('A') < wonCode.count('D'):
print("Danik")
else:
print("Friendship")
antonandDanik()
```
| 3
|
|
120
|
A
|
Elevator
|
PROGRAMMING
| 1,000
|
[
"brute force",
"implementation",
"math"
] | null | null |
A sky scraper with 1000 floors has been built in the city of N. It has modern superfast elevators to help to travel from one floor to another. Each elevator has two doors, the front one and the back one. If one goes in through the front door, he goes out through the back one and vice versa. The elevator has two rails numbered with numbers 1 and 2. Rail 1 is located to the left of the entrance to the front door (or correspondingly, to the right of the entrance to the back door). Rail 2 is located opposite it, to the right of the entrance to the front door and to the left of the entrance to the back door. We know that each person in the city of N holds at a rail with the strongest hand.
One day a VIP person visited the city and of course, he took a look at the skyscraper and took a ride in the elevator. We know the door through which he entered and the rail he was holding at. Now we need to determine as soon as possible whether he is left-handed or right-handed.
|
The first line indicates the door through which the very important person entered the elevator. It contains "front" if the person enters the elevator through the front door and "back" if he entered the elevator through the back door. The second line contains integer *a* (1<=≤<=*a*<=≤<=2) which denotes the number of the rail at which the person was holding.
|
Print character "R" if the VIP is right-handed or "L" if he is left-handed.
|
[
"front\n1\n"
] |
[
"L\n"
] |
none
| 0
|
[
{
"input": "front\n1",
"output": "L"
},
{
"input": "back\n1",
"output": "R"
},
{
"input": "front\n2",
"output": "R"
},
{
"input": "back\n2",
"output": "L"
}
] | 1,579,389,922
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 278
| 716,800
|
import re
import sys
stdin = None
with open(0) as file:
stdin = file.read()
DOOR = {"front": 1, "back": 2}
RAIL = { "1": 2, "2": 1}
door, rail = re.findall("(\w+)\n(\d)", stdin)[0]
hand = "L" if DOOR[door] + RAIL[rail] == 3 else "R"
print(door, rail, hand)
|
Title: Elevator
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A sky scraper with 1000 floors has been built in the city of N. It has modern superfast elevators to help to travel from one floor to another. Each elevator has two doors, the front one and the back one. If one goes in through the front door, he goes out through the back one and vice versa. The elevator has two rails numbered with numbers 1 and 2. Rail 1 is located to the left of the entrance to the front door (or correspondingly, to the right of the entrance to the back door). Rail 2 is located opposite it, to the right of the entrance to the front door and to the left of the entrance to the back door. We know that each person in the city of N holds at a rail with the strongest hand.
One day a VIP person visited the city and of course, he took a look at the skyscraper and took a ride in the elevator. We know the door through which he entered and the rail he was holding at. Now we need to determine as soon as possible whether he is left-handed or right-handed.
Input Specification:
The first line indicates the door through which the very important person entered the elevator. It contains "front" if the person enters the elevator through the front door and "back" if he entered the elevator through the back door. The second line contains integer *a* (1<=≤<=*a*<=≤<=2) which denotes the number of the rail at which the person was holding.
Output Specification:
Print character "R" if the VIP is right-handed or "L" if he is left-handed.
Demo Input:
['front\n1\n']
Demo Output:
['L\n']
Note:
none
|
```python
import re
import sys
stdin = None
with open(0) as file:
stdin = file.read()
DOOR = {"front": 1, "back": 2}
RAIL = { "1": 2, "2": 1}
door, rail = re.findall("(\w+)\n(\d)", stdin)[0]
hand = "L" if DOOR[door] + RAIL[rail] == 3 else "R"
print(door, rail, hand)
```
| -1
|
|
61
|
A
|
Ultra-Fast Mathematician
|
PROGRAMMING
| 800
|
[
"implementation"
] |
A. Ultra-Fast Mathematician
|
2
|
256
|
Shapur was an extremely gifted student. He was great at everything including Combinatorics, Algebra, Number Theory, Geometry, Calculus, etc. He was not only smart but extraordinarily fast! He could manage to sum 1018 numbers in a single second.
One day in 230 AD Shapur was trying to find out if any one can possibly do calculations faster than him. As a result he made a very great contest and asked every one to come and take part.
In his contest he gave the contestants many different pairs of numbers. Each number is made from digits 0 or 1. The contestants should write a new number corresponding to the given pair of numbers. The rule is simple: The *i*-th digit of the answer is 1 if and only if the *i*-th digit of the two given numbers differ. In the other case the *i*-th digit of the answer is 0.
Shapur made many numbers and first tried his own speed. He saw that he can perform these operations on numbers of length ∞ (length of a number is number of digits in it) in a glance! He always gives correct answers so he expects the contestants to give correct answers, too. He is a good fellow so he won't give anyone very big numbers and he always gives one person numbers of same length.
Now you are going to take part in Shapur's contest. See if you are faster and more accurate.
|
There are two lines in each input. Each of them contains a single number. It is guaranteed that the numbers are made from 0 and 1 only and that their length is same. The numbers may start with 0. The length of each number doesn't exceed 100.
|
Write one line — the corresponding answer. Do not omit the leading 0s.
|
[
"1010100\n0100101\n",
"000\n111\n",
"1110\n1010\n",
"01110\n01100\n"
] |
[
"1110001\n",
"111\n",
"0100\n",
"00010\n"
] |
none
| 500
|
[
{
"input": "1010100\n0100101",
"output": "1110001"
},
{
"input": "000\n111",
"output": "111"
},
{
"input": "1110\n1010",
"output": "0100"
},
{
"input": "01110\n01100",
"output": "00010"
},
{
"input": "011101\n000001",
"output": "011100"
},
{
"input": "10\n01",
"output": "11"
},
{
"input": "00111111\n11011101",
"output": "11100010"
},
{
"input": "011001100\n101001010",
"output": "110000110"
},
{
"input": "1100100001\n0110101100",
"output": "1010001101"
},
{
"input": "00011101010\n10010100101",
"output": "10001001111"
},
{
"input": "100000101101\n111010100011",
"output": "011010001110"
},
{
"input": "1000001111010\n1101100110001",
"output": "0101101001011"
},
{
"input": "01011111010111\n10001110111010",
"output": "11010001101101"
},
{
"input": "110010000111100\n001100101011010",
"output": "111110101100110"
},
{
"input": "0010010111110000\n0000000011010110",
"output": "0010010100100110"
},
{
"input": "00111110111110000\n01111100001100000",
"output": "01000010110010000"
},
{
"input": "101010101111010001\n001001111101111101",
"output": "100011010010101100"
},
{
"input": "0110010101111100000\n0011000101000000110",
"output": "0101010000111100110"
},
{
"input": "11110100011101010111\n00001000011011000000",
"output": "11111100000110010111"
},
{
"input": "101010101111101101001\n111010010010000011111",
"output": "010000111101101110110"
},
{
"input": "0000111111100011000010\n1110110110110000001010",
"output": "1110001001010011001000"
},
{
"input": "10010010101000110111000\n00101110100110111000111",
"output": "10111100001110001111111"
},
{
"input": "010010010010111100000111\n100100111111100011001110",
"output": "110110101101011111001001"
},
{
"input": "0101110100100111011010010\n0101100011010111001010001",
"output": "0000010111110000010000011"
},
{
"input": "10010010100011110111111011\n10000110101100000001000100",
"output": "00010100001111110110111111"
},
{
"input": "000001111000000100001000000\n011100111101111001110110001",
"output": "011101000101111101111110001"
},
{
"input": "0011110010001001011001011100\n0000101101000011101011001010",
"output": "0011011111001010110010010110"
},
{
"input": "11111000000000010011001101111\n11101110011001010100010000000",
"output": "00010110011001000111011101111"
},
{
"input": "011001110000110100001100101100\n001010000011110000001000101001",
"output": "010011110011000100000100000101"
},
{
"input": "1011111010001100011010110101111\n1011001110010000000101100010101",
"output": "0000110100011100011111010111010"
},
{
"input": "10111000100001000001010110000001\n10111000001100101011011001011000",
"output": "00000000101101101010001111011001"
},
{
"input": "000001010000100001000000011011100\n111111111001010100100001100000111",
"output": "111110101001110101100001111011011"
},
{
"input": "1101000000000010011011101100000110\n1110000001100010011010000011011110",
"output": "0011000001100000000001101111011000"
},
{
"input": "01011011000010100001100100011110001\n01011010111000001010010100001110000",
"output": "00000001111010101011110000010000001"
},
{
"input": "000011111000011001000110111100000100\n011011000110000111101011100111000111",
"output": "011000111110011110101101011011000011"
},
{
"input": "1001000010101110001000000011111110010\n0010001011010111000011101001010110000",
"output": "1011001001111001001011101010101000010"
},
{
"input": "00011101011001100101111111000000010101\n10010011011011001011111000000011101011",
"output": "10001110000010101110000111000011111110"
},
{
"input": "111011100110001001101111110010111001010\n111111101101111001110010000101101000100",
"output": "000100001011110000011101110111010001110"
},
{
"input": "1111001001101000001000000010010101001010\n0010111100111110001011000010111110111001",
"output": "1101110101010110000011000000101011110011"
},
{
"input": "00100101111000000101011111110010100011010\n11101110001010010101001000111110101010100",
"output": "11001011110010010000010111001100001001110"
},
{
"input": "101011001110110100101001000111010101101111\n100111100110101011010100111100111111010110",
"output": "001100101000011111111101111011101010111001"
},
{
"input": "1111100001100101000111101001001010011100001\n1000110011000011110010001011001110001000001",
"output": "0111010010100110110101100010000100010100000"
},
{
"input": "01100111011111010101000001101110000001110101\n10011001011111110000000101011001001101101100",
"output": "11111110000000100101000100110111001100011001"
},
{
"input": "110010100111000100100101100000011100000011001\n011001111011100110000110111001110110100111011",
"output": "101011011100100010100011011001101010100100010"
},
{
"input": "0001100111111011010110100100111000000111000110\n1100101011000000000001010010010111001100110001",
"output": "1101001100111011010111110110101111001011110111"
},
{
"input": "00000101110110110001110010100001110100000100000\n10010000110011110001101000111111101010011010001",
"output": "10010101000101000000011010011110011110011110001"
},
{
"input": "110000100101011100100011001111110011111110010001\n101011111001011100110110111101110011010110101100",
"output": "011011011100000000010101110010000000101000111101"
},
{
"input": "0101111101011111010101011101000011101100000000111\n0000101010110110001110101011011110111001010100100",
"output": "0101010111101001011011110110011101010101010100011"
},
{
"input": "11000100010101110011101000011111001010110111111100\n00001111000111001011111110000010101110111001000011",
"output": "11001011010010111000010110011101100100001110111111"
},
{
"input": "101000001101111101101111111000001110110010101101010\n010011100111100001100000010001100101000000111011011",
"output": "111011101010011100001111101001101011110010010110001"
},
{
"input": "0011111110010001010100010110111000110011001101010100\n0111000000100010101010000100101000000100101000111001",
"output": "0100111110110011111110010010010000110111100101101101"
},
{
"input": "11101010000110000011011010000001111101000111011111100\n10110011110001010100010110010010101001010111100100100",
"output": "01011001110111010111001100010011010100010000111011000"
},
{
"input": "011000100001000001101000010110100110011110100111111011\n111011001000001001110011001111011110111110110011011111",
"output": "100011101001001000011011011001111000100000010100100100"
},
{
"input": "0111010110010100000110111011010110100000000111110110000\n1011100100010001101100000100111111101001110010000100110",
"output": "1100110010000101101010111111101001001001110101110010110"
},
{
"input": "10101000100111000111010001011011011011110100110101100011\n11101111000000001100100011111000100100000110011001101110",
"output": "01000111100111001011110010100011111111110010101100001101"
},
{
"input": "000000111001010001000000110001001011100010011101010011011\n110001101000010010000101000100001111101001100100001010010",
"output": "110001010001000011000101110101000100001011111001011001001"
},
{
"input": "0101011100111010000111110010101101111111000000111100011100\n1011111110000010101110111001000011100000100111111111000111",
"output": "1110100010111000101001001011101110011111100111000011011011"
},
{
"input": "11001000001100100111100111100100101011000101001111001001101\n10111110100010000011010100110100100011101001100000001110110",
"output": "01110110101110100100110011010000001000101100101111000111011"
},
{
"input": "010111011011101000000110000110100110001110100001110110111011\n101011110011101011101101011111010100100001100111100100111011",
"output": "111100101000000011101011011001110010101111000110010010000000"
},
{
"input": "1001011110110110000100011001010110000100011010010111010101110\n1101111100001000010111110011010101111010010100000001000010111",
"output": "0100100010111110010011101010000011111110001110010110010111001"
},
{
"input": "10000010101111100111110101111000010100110111101101111111111010\n10110110101100101010011001011010100110111011101100011001100111",
"output": "00110100000011001101101100100010110010001100000001100110011101"
},
{
"input": "011111010011111000001010101001101001000010100010111110010100001\n011111001011000011111001000001111001010110001010111101000010011",
"output": "000000011000111011110011101000010000010100101000000011010110010"
},
{
"input": "1111000000110001011101000100100100001111011100001111001100011111\n1101100110000101100001100000001001011011111011010101000101001010",
"output": "0010100110110100111100100100101101010100100111011010001001010101"
},
{
"input": "01100000101010010011001110100110110010000110010011011001100100011\n10110110010110111100100111000111000110010000000101101110000010111",
"output": "11010110111100101111101001100001110100010110010110110111100110100"
},
{
"input": "001111111010000100001100001010011001111110011110010111110001100111\n110000101001011000100010101100100110000111100000001101001110010111",
"output": "111111010011011100101110100110111111111001111110011010111111110000"
},
{
"input": "1011101011101101011110101101011101011000010011100101010101000100110\n0001000001001111010111100100111101100000000001110001000110000000110",
"output": "1010101010100010001001001001100000111000010010010100010011000100000"
},
{
"input": "01000001011001010011011100010000100100110101111011011011110000001110\n01011110000110011011000000000011000111100001010000000011111001110000",
"output": "00011111011111001000011100010011100011010100101011011000001001111110"
},
{
"input": "110101010100110101000001111110110100010010000100111110010100110011100\n111010010111111011100110101011001011001110110111110100000110110100111",
"output": "001111000011001110100111010101111111011100110011001010010010000111011"
},
{
"input": "1001101011000001011111100110010010000011010001001111011100010100110001\n1111100111110101001111010001010000011001001001010110001111000000100101",
"output": "0110001100110100010000110111000010011010011000011001010011010100010100"
},
{
"input": "00000111110010110001110110001010010101000111011001111111100110011110010\n00010111110100000100110101000010010001100001100011100000001100010100010",
"output": "00010000000110110101000011001000000100100110111010011111101010001010000"
},
{
"input": "100101011100101101000011010001011001101110101110001100010001010111001110\n100001111100101011011111110000001111000111001011111110000010101110111001",
"output": "000100100000000110011100100001010110101001100101110010010011111001110111"
},
{
"input": "1101100001000111001101001011101000111000011110000001001101101001111011010\n0101011101010100011011010110101000010010110010011110101100000110110001000",
"output": "1000111100010011010110011101000000101010101100011111100001101111001010010"
},
{
"input": "01101101010011110101100001110101111011100010000010001101111000011110111111\n00101111001101001100111010000101110000100101101111100111101110010100011011",
"output": "01000010011110111001011011110000001011000111101101101010010110001010100100"
},
{
"input": "101100101100011001101111110110110010100110110010100001110010110011001101011\n000001011010101011110011111101001110000111000010001101000010010000010001101",
"output": "101101110110110010011100001011111100100001110000101100110000100011011100110"
},
{
"input": "0010001011001010001100000010010011110110011000100000000100110000101111001110\n1100110100111000110100001110111001011101001100001010100001010011100110110001",
"output": "1110111111110010111000001100101010101011010100101010100101100011001001111111"
},
{
"input": "00101101010000000101011001101011001100010001100000101011101110000001111001000\n10010110010111000000101101000011101011001010000011011101101011010000000011111",
"output": "10111011000111000101110100101000100111011011100011110110000101010001111010111"
},
{
"input": "111100000100100000101001100001001111001010001000001000000111010000010101101011\n001000100010100101111011111011010110101100001111011000010011011011100010010110",
"output": "110100100110000101010010011010011001100110000111010000010100001011110111111101"
},
{
"input": "0110001101100100001111110101101000100101010010101010011001101001001101110000000\n0111011000000010010111011110010000000001000110001000011001101000000001110100111",
"output": "0001010101100110011000101011111000100100010100100010000000000001001100000100111"
},
{
"input": "10001111111001000101001011110101111010100001011010101100111001010001010010001000\n10000111010010011110111000111010101100000011110001101111001000111010100000000001",
"output": "00001000101011011011110011001111010110100010101011000011110001101011110010001001"
},
{
"input": "100110001110110000100101001110000011110110000110000000100011110100110110011001101\n110001110101110000000100101001101011111100100100001001000110000001111100011110110",
"output": "010111111011000000100001100111101000001010100010001001100101110101001010000111011"
},
{
"input": "0000010100100000010110111100011111111010011101000000100000011001001101101100111010\n0100111110011101010110101011110110010111001111000110101100101110111100101000111111",
"output": "0100101010111101000000010111101001101101010010000110001100110111110001000100000101"
},
{
"input": "11000111001010100001110000001001011010010010110000001110100101000001010101100110111\n11001100100100100001101010110100000111100011101110011010110100001001000011011011010",
"output": "00001011101110000000011010111101011101110001011110010100010001001000010110111101101"
},
{
"input": "010110100010001000100010101001101010011010111110100001000100101000111011100010100001\n110000011111101101010011111000101010111010100001001100001001100101000000111000000000",
"output": "100110111101100101110001010001000000100000011111101101001101001101111011011010100001"
},
{
"input": "0000011110101110010101110110110101100001011001101010101001000010000010000000101001101\n1100111111011100000110000111101110011111100111110001011001000010011111100001001100011",
"output": "1100100001110010010011110001011011111110111110011011110000000000011101100001100101110"
},
{
"input": "10100000101101110001100010010010100101100011010010101000110011100000101010110010000000\n10001110011011010010111011011101101111000111110000111000011010010101001100000001010011",
"output": "00101110110110100011011001001111001010100100100010010000101001110101100110110011010011"
},
{
"input": "001110000011111101101010011111000101010111010100001001100001001100101000000111000000000\n111010000000000000101001110011001000111011001100101010011001000011101001001011110000011",
"output": "110100000011111101000011101100001101101100011000100011111000001111000001001100110000011"
},
{
"input": "1110111100111011010101011011001110001010010010110011110010011111000010011111010101100001\n1001010101011001001010100010101100000110111101011000100010101111111010111100001110010010",
"output": "0111101001100010011111111001100010001100101111101011010000110000111000100011011011110011"
},
{
"input": "11100010001100010011001100001100010011010001101110011110100101110010101101011101000111111\n01110000000110111010110100001010000101011110100101010011000110101110101101110111011110001",
"output": "10010010001010101001111000000110010110001111001011001101100011011100000000101010011001110"
},
{
"input": "001101011001100101101100110000111000101011001001100100000100101000100000110100010111111101\n101001111110000010111101111110001001111001111101111010000110111000100100110010010001011111",
"output": "100100100111100111010001001110110001010010110100011110000010010000000100000110000110100010"
},
{
"input": "1010110110010101000110010010110101011101010100011001101011000110000000100011100100011000000\n0011011111100010001111101101000111001011101110100000110111100100101111010110101111011100011",
"output": "1001101001110111001001111111110010010110111010111001011100100010101111110101001011000100011"
},
{
"input": "10010010000111010111011111110010100101100000001100011100111011100010000010010001011100001100\n00111010100010110010000100010111010001111110100100100011101000101111111111001101101100100100",
"output": "10101000100101100101011011100101110100011110101000111111010011001101111101011100110000101000"
},
{
"input": "010101110001010101100000010111010000000111110011001101100011001000000011001111110000000010100\n010010111011100101010101111110110000000111000100001101101001001000001100101110001010000100001",
"output": "000111001010110000110101101001100000000000110111000000001010000000001111100001111010000110101"
},
{
"input": "1100111110011001000111101001001011000110011010111111100010111111001100111111011101100111101011\n1100000011001000110100110111000001011001010111101000010010100011000001100100111101101000010110",
"output": "0000111101010001110011011110001010011111001101010111110000011100001101011011100000001111111101"
},
{
"input": "00011000100100110111100101100100000000010011110111110010101110110011100001010111010011110100101\n00011011111011111011100101100111100101001110010111000010000111000100100100000001110101111011011",
"output": "00000011011111001100000000000011100101011101100000110000101001110111000101010110100110001111110"
},
{
"input": "000101011001001100000111100010110101111011110101111101000110001101011010111110110011100100000001\n011000101010011111011000111000100000000011011000000001111110001000001111101010110000011100001111",
"output": "011101110011010011011111011010010101111000101101111100111000000101010101010100000011111000001110"
},
{
"input": "1000101001011010000100100100010010011101011001110101111011101111111110010101001101010001010101001\n0110110010011100011111011111110111000000010001110100001010111110101011010011111011111110000110000",
"output": "1110011011000110011011111011100101011101001000000001110001010001010101000110110110101111010011001"
},
{
"input": "01111010010101100111110111111011011010100001011101010000111100101101101110111011001100101011100111\n00001100110110100001111011000010001001001100000010111101000001111011100000010111010010000011000010",
"output": "01110110100011000110001100111001010011101101011111101101111101010110001110101100011110101000100101"
},
{
"input": "111101011101111000001011001101111010110111001101110100100011111011011101001101010101011010111000110\n101111100101101101001100110011000001111010011101110111110110101110011011110011111100001001110101101",
"output": "010010111000010101000111111110111011001101010000000011010101010101000110111110101001010011001101011"
},
{
"input": "1010000011010110011101001101110001110010000111011101110010110110111111001001110100101100010101010001\n0111101000111100101100000101111010100100001000011101010100110011100011010011010101000100101011100011",
"output": "1101101011101010110001001000001011010110001111000000100110000101011100011010100001101000111110110010"
},
{
"input": "0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001\n1111111010111111101011111110101111111010111111101011111110101111111010111111101011111110101111111010",
"output": "1111111010111111101011111110101111111010111111101011111110101111111010111111101011111110101111111011"
},
{
"input": "0\n0",
"output": "0"
},
{
"input": "0\n1",
"output": "1"
}
] | 1,612,327,785
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
a = input()
b = input()
c = len(a)
for i in range(0,c):
if (a[i]=="0" and b[i]=="0") or (a[i]=="1" and b[i]=="1":
a[i] = "0"
elif a[i]=="0" and b[i]=="1":
a[i] = "1"
elif a[i]=="1" and b[i]=="0":
a[i] = "1"
print(a)
|
Title: Ultra-Fast Mathematician
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Shapur was an extremely gifted student. He was great at everything including Combinatorics, Algebra, Number Theory, Geometry, Calculus, etc. He was not only smart but extraordinarily fast! He could manage to sum 1018 numbers in a single second.
One day in 230 AD Shapur was trying to find out if any one can possibly do calculations faster than him. As a result he made a very great contest and asked every one to come and take part.
In his contest he gave the contestants many different pairs of numbers. Each number is made from digits 0 or 1. The contestants should write a new number corresponding to the given pair of numbers. The rule is simple: The *i*-th digit of the answer is 1 if and only if the *i*-th digit of the two given numbers differ. In the other case the *i*-th digit of the answer is 0.
Shapur made many numbers and first tried his own speed. He saw that he can perform these operations on numbers of length ∞ (length of a number is number of digits in it) in a glance! He always gives correct answers so he expects the contestants to give correct answers, too. He is a good fellow so he won't give anyone very big numbers and he always gives one person numbers of same length.
Now you are going to take part in Shapur's contest. See if you are faster and more accurate.
Input Specification:
There are two lines in each input. Each of them contains a single number. It is guaranteed that the numbers are made from 0 and 1 only and that their length is same. The numbers may start with 0. The length of each number doesn't exceed 100.
Output Specification:
Write one line — the corresponding answer. Do not omit the leading 0s.
Demo Input:
['1010100\n0100101\n', '000\n111\n', '1110\n1010\n', '01110\n01100\n']
Demo Output:
['1110001\n', '111\n', '0100\n', '00010\n']
Note:
none
|
```python
a = input()
b = input()
c = len(a)
for i in range(0,c):
if (a[i]=="0" and b[i]=="0") or (a[i]=="1" and b[i]=="1":
a[i] = "0"
elif a[i]=="0" and b[i]=="1":
a[i] = "1"
elif a[i]=="1" and b[i]=="0":
a[i] = "1"
print(a)
```
| -1
|
677
|
A
|
Vanya and Fence
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Vanya and his friends are walking along the fence of height *h* and they do not want the guard to notice them. In order to achieve this the height of each of the friends should not exceed *h*. If the height of some person is greater than *h* he can bend down and then he surely won't be noticed by the guard. The height of the *i*-th person is equal to *a**i*.
Consider the width of the person walking as usual to be equal to 1, while the width of the bent person is equal to 2. Friends want to talk to each other while walking, so they would like to walk in a single row. What is the minimum width of the road, such that friends can walk in a row and remain unattended by the guard?
|
The first line of the input contains two integers *n* and *h* (1<=≤<=*n*<=≤<=1000, 1<=≤<=*h*<=≤<=1000) — the number of friends and the height of the fence, respectively.
The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=2*h*), the *i*-th of them is equal to the height of the *i*-th person.
|
Print a single integer — the minimum possible valid width of the road.
|
[
"3 7\n4 5 14\n",
"6 1\n1 1 1 1 1 1\n",
"6 5\n7 6 8 9 10 5\n"
] |
[
"4\n",
"6\n",
"11\n"
] |
In the first sample, only person number 3 must bend down, so the required width is equal to 1 + 1 + 2 = 4.
In the second sample, all friends are short enough and no one has to bend, so the width 1 + 1 + 1 + 1 + 1 + 1 = 6 is enough.
In the third sample, all the persons have to bend, except the last one. The required minimum width of the road is equal to 2 + 2 + 2 + 2 + 2 + 1 = 11.
| 500
|
[
{
"input": "3 7\n4 5 14",
"output": "4"
},
{
"input": "6 1\n1 1 1 1 1 1",
"output": "6"
},
{
"input": "6 5\n7 6 8 9 10 5",
"output": "11"
},
{
"input": "10 420\n214 614 297 675 82 740 174 23 255 15",
"output": "13"
},
{
"input": "10 561\n657 23 1096 487 785 66 481 554 1000 821",
"output": "15"
},
{
"input": "100 342\n478 143 359 336 162 333 385 515 117 496 310 538 469 539 258 676 466 677 1 296 150 560 26 213 627 221 255 126 617 174 279 178 24 435 70 145 619 46 669 566 300 67 576 251 58 176 441 564 569 194 24 669 73 262 457 259 619 78 400 579 222 626 269 47 80 315 160 194 455 186 315 424 197 246 683 220 68 682 83 233 290 664 273 598 362 305 674 614 321 575 362 120 14 534 62 436 294 351 485 396",
"output": "144"
},
{
"input": "100 290\n244 49 276 77 449 261 468 458 201 424 9 131 300 88 432 394 104 77 13 289 435 259 111 453 168 394 156 412 351 576 178 530 81 271 228 564 125 328 42 372 205 61 180 471 33 360 567 331 222 318 241 117 529 169 188 484 202 202 299 268 246 343 44 364 333 494 59 236 84 485 50 8 428 8 571 227 205 310 210 9 324 472 368 490 114 84 296 305 411 351 569 393 283 120 510 171 232 151 134 366",
"output": "145"
},
{
"input": "1 1\n1",
"output": "1"
},
{
"input": "1 1\n2",
"output": "2"
},
{
"input": "46 71\n30 26 56 138 123 77 60 122 73 45 79 10 130 3 14 1 38 46 128 50 82 16 32 68 28 98 62 106 2 49 131 11 114 39 139 70 40 50 45 137 33 30 35 136 135 19",
"output": "63"
},
{
"input": "20 723\n212 602 293 591 754 91 1135 640 80 495 845 928 1399 498 926 1431 1226 869 814 1386",
"output": "31"
},
{
"input": "48 864\n843 1020 751 1694 18 1429 1395 1174 272 1158 1628 1233 1710 441 765 561 778 748 1501 1200 563 1263 1398 1687 1518 1640 1591 839 500 466 1603 1587 1201 1209 432 868 1159 639 649 628 9 91 1036 147 896 1557 941 518",
"output": "75"
},
{
"input": "26 708\n549 241 821 734 945 1161 566 1268 216 30 1142 730 529 1014 255 168 796 1148 89 113 1328 286 743 871 1259 1397",
"output": "41"
},
{
"input": "75 940\n1620 1745 1599 441 64 1466 1496 1239 1716 1475 778 106 1136 1212 1261 444 781 257 1071 747 626 232 609 1544 682 1326 469 1361 1460 1450 1207 1319 922 625 1737 1057 1698 592 692 80 1016 541 1254 201 682 1007 847 206 1066 809 259 109 240 1611 219 1455 1326 1377 1827 786 42 1002 1382 1592 543 1866 1198 334 1524 1760 340 1566 955 257 1118",
"output": "116"
}
] | 1,695,334,770
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 29
| 46
| 0
|
n,height = map(int,input().split())
h = list(map(int,input().split()))
width=0
for i in range(n):
if h[i]>height:
width+=2
else:
width+=1
print(width)
|
Title: Vanya and Fence
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vanya and his friends are walking along the fence of height *h* and they do not want the guard to notice them. In order to achieve this the height of each of the friends should not exceed *h*. If the height of some person is greater than *h* he can bend down and then he surely won't be noticed by the guard. The height of the *i*-th person is equal to *a**i*.
Consider the width of the person walking as usual to be equal to 1, while the width of the bent person is equal to 2. Friends want to talk to each other while walking, so they would like to walk in a single row. What is the minimum width of the road, such that friends can walk in a row and remain unattended by the guard?
Input Specification:
The first line of the input contains two integers *n* and *h* (1<=≤<=*n*<=≤<=1000, 1<=≤<=*h*<=≤<=1000) — the number of friends and the height of the fence, respectively.
The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=2*h*), the *i*-th of them is equal to the height of the *i*-th person.
Output Specification:
Print a single integer — the minimum possible valid width of the road.
Demo Input:
['3 7\n4 5 14\n', '6 1\n1 1 1 1 1 1\n', '6 5\n7 6 8 9 10 5\n']
Demo Output:
['4\n', '6\n', '11\n']
Note:
In the first sample, only person number 3 must bend down, so the required width is equal to 1 + 1 + 2 = 4.
In the second sample, all friends are short enough and no one has to bend, so the width 1 + 1 + 1 + 1 + 1 + 1 = 6 is enough.
In the third sample, all the persons have to bend, except the last one. The required minimum width of the road is equal to 2 + 2 + 2 + 2 + 2 + 1 = 11.
|
```python
n,height = map(int,input().split())
h = list(map(int,input().split()))
width=0
for i in range(n):
if h[i]>height:
width+=2
else:
width+=1
print(width)
```
| 3
|
|
58
|
A
|
Chat room
|
PROGRAMMING
| 1,000
|
[
"greedy",
"strings"
] |
A. Chat room
|
1
|
256
|
Vasya has recently learned to type and log on to the Internet. He immediately entered a chat room and decided to say hello to everybody. Vasya typed the word *s*. It is considered that Vasya managed to say hello if several letters can be deleted from the typed word so that it resulted in the word "hello". For example, if Vasya types the word "ahhellllloou", it will be considered that he said hello, and if he types "hlelo", it will be considered that Vasya got misunderstood and he didn't manage to say hello. Determine whether Vasya managed to say hello by the given word *s*.
|
The first and only line contains the word *s*, which Vasya typed. This word consisits of small Latin letters, its length is no less that 1 and no more than 100 letters.
|
If Vasya managed to say hello, print "YES", otherwise print "NO".
|
[
"ahhellllloou\n",
"hlelo\n"
] |
[
"YES\n",
"NO\n"
] |
none
| 500
|
[
{
"input": "ahhellllloou",
"output": "YES"
},
{
"input": "hlelo",
"output": "NO"
},
{
"input": "helhcludoo",
"output": "YES"
},
{
"input": "hehwelloho",
"output": "YES"
},
{
"input": "pnnepelqomhhheollvlo",
"output": "YES"
},
{
"input": "tymbzjyqhymedasloqbq",
"output": "NO"
},
{
"input": "yehluhlkwo",
"output": "NO"
},
{
"input": "hatlevhhalrohairnolsvocafgueelrqmlqlleello",
"output": "YES"
},
{
"input": "hhhtehdbllnhwmbyhvelqqyoulretpbfokflhlhreeflxeftelziclrwllrpflflbdtotvlqgoaoqldlroovbfsq",
"output": "YES"
},
{
"input": "rzlvihhghnelqtwlexmvdjjrliqllolhyewgozkuovaiezgcilelqapuoeglnwmnlftxxiigzczlouooi",
"output": "YES"
},
{
"input": "pfhhwctyqdlkrwhebfqfelhyebwllhemtrmeblgrynmvyhioesqklclocxmlffuormljszllpoo",
"output": "YES"
},
{
"input": "lqllcolohwflhfhlnaow",
"output": "NO"
},
{
"input": "heheeellollvoo",
"output": "YES"
},
{
"input": "hellooo",
"output": "YES"
},
{
"input": "o",
"output": "NO"
},
{
"input": "hhqhzeclohlehljlhtesllylrolmomvuhcxsobtsckogdv",
"output": "YES"
},
{
"input": "yoegfuzhqsihygnhpnukluutocvvwuldiighpogsifealtgkfzqbwtmgghmythcxflebrkctlldlkzlagovwlstsghbouk",
"output": "YES"
},
{
"input": "uatqtgbvrnywfacwursctpagasnhydvmlinrcnqrry",
"output": "NO"
},
{
"input": "tndtbldbllnrwmbyhvqaqqyoudrstpbfokfoclnraefuxtftmgzicorwisrpfnfpbdtatvwqgyalqtdtrjqvbfsq",
"output": "NO"
},
{
"input": "rzlvirhgemelnzdawzpaoqtxmqucnahvqnwldklrmjiiyageraijfivigvozgwngiulttxxgzczptusoi",
"output": "YES"
},
{
"input": "kgyelmchocojsnaqdsyeqgnllytbqietpdlgknwwumqkxrexgdcnwoldicwzwofpmuesjuxzrasscvyuqwspm",
"output": "YES"
},
{
"input": "pnyvrcotjvgynbeldnxieghfltmexttuxzyac",
"output": "NO"
},
{
"input": "dtwhbqoumejligbenxvzhjlhosqojetcqsynlzyhfaevbdpekgbtjrbhlltbceobcok",
"output": "YES"
},
{
"input": "crrfpfftjwhhikwzeedrlwzblckkteseofjuxjrktcjfsylmlsvogvrcxbxtffujqshslemnixoeezivksouefeqlhhokwbqjz",
"output": "YES"
},
{
"input": "jhfbndhyzdvhbvhmhmefqllujdflwdpjbehedlsqfdsqlyelwjtyloxwsvasrbqosblzbowlqjmyeilcvotdlaouxhdpoeloaovb",
"output": "YES"
},
{
"input": "hwlghueoemiqtjhhpashjsouyegdlvoyzeunlroypoprnhlyiwiuxrghekaylndhrhllllwhbebezoglydcvykllotrlaqtvmlla",
"output": "YES"
},
{
"input": "wshiaunnqnqxodholbipwhhjmyeblhgpeleblklpzwhdunmpqkbuzloetmwwxmeltkrcomulxauzlwmlklldjodozxryghsnwgcz",
"output": "YES"
},
{
"input": "shvksednttggehroewuiptvvxtrzgidravtnjwuqrlnnkxbplctzkckinpkgjopjfoxdbojtcvsuvablcbkrzajrlhgobkcxeqti",
"output": "YES"
},
{
"input": "hyyhddqhxhekehkwfhlnlsihzefwchzerevcjtokefplholrbvxlltdlafjxrfhleglrvlolojoqaolagtbeyogxlbgfolllslli",
"output": "YES"
},
{
"input": "iaagrdhhelxpdegueiulflquvlzidoprzkehthkldaytrjwhyhprwjxlltinxvuilxohqgjqcvkkdcuoliekcnlilwgqlnlzouoo",
"output": "YES"
},
{
"input": "wfluaeseldgxyvxpwuhkptdmlflnlhktwxiabsvkolsquymrmhzczzoybvlilhmvsuunggvgxzgyyffk",
"output": "NO"
},
{
"input": "loee",
"output": "NO"
},
{
"input": "izdipwylefqmjbuoznfglgcfvedeouflkeehxbasaqmiooppfsqlhprospqgxvzrcpwlfdddngoqvpwvggsnvvxhmjoslwjudjlo",
"output": "NO"
},
{
"input": "pplynflbjlseflaegzqpdxswgunhnlglqhycrbcwdfhclmcrwekkzsoosmfblljeenwfjyifcvxihhhbyhmhlkvtskeglaovjnsi",
"output": "YES"
},
{
"input": "xqjqmenkodmlhzyzmmvofdngktygbbxbzpluzcohohmalkoeuwfikblltaaigv",
"output": "NO"
},
{
"input": "hello",
"output": "YES"
},
{
"input": "oohell",
"output": "NO"
},
{
"input": "hell",
"output": "NO"
},
{
"input": "eloellohoelo",
"output": "NO"
},
{
"input": "helllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllo",
"output": "YES"
}
] | 1,598,192,069
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 40
| 109
| 6,656,000
|
a='hello'
b=input()
i=0
for j in range(len(b)):
if(b[j]==a[i]):
i+=1
if(i==len(a)):
break
if(i==len(a)):
print("YES")
else:
print("NO")
|
Title: Chat room
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
Vasya has recently learned to type and log on to the Internet. He immediately entered a chat room and decided to say hello to everybody. Vasya typed the word *s*. It is considered that Vasya managed to say hello if several letters can be deleted from the typed word so that it resulted in the word "hello". For example, if Vasya types the word "ahhellllloou", it will be considered that he said hello, and if he types "hlelo", it will be considered that Vasya got misunderstood and he didn't manage to say hello. Determine whether Vasya managed to say hello by the given word *s*.
Input Specification:
The first and only line contains the word *s*, which Vasya typed. This word consisits of small Latin letters, its length is no less that 1 and no more than 100 letters.
Output Specification:
If Vasya managed to say hello, print "YES", otherwise print "NO".
Demo Input:
['ahhellllloou\n', 'hlelo\n']
Demo Output:
['YES\n', 'NO\n']
Note:
none
|
```python
a='hello'
b=input()
i=0
for j in range(len(b)):
if(b[j]==a[i]):
i+=1
if(i==len(a)):
break
if(i==len(a)):
print("YES")
else:
print("NO")
```
| 3.933102
|
369
|
A
|
Valera and Plates
|
PROGRAMMING
| 900
|
[
"greedy",
"implementation"
] | null | null |
Valera is a lazy student. He has *m* clean bowls and *k* clean plates.
Valera has made an eating plan for the next *n* days. As Valera is lazy, he will eat exactly one dish per day. At that, in order to eat a dish, he needs exactly one clean plate or bowl. We know that Valera can cook only two types of dishes. He can eat dishes of the first type from bowls and dishes of the second type from either bowls or plates.
When Valera finishes eating, he leaves a dirty plate/bowl behind. His life philosophy doesn't let him eat from dirty kitchenware. So sometimes he needs to wash his plate/bowl before eating. Find the minimum number of times Valera will need to wash a plate/bowl, if he acts optimally.
|
The first line of the input contains three integers *n*, *m*, *k* (1<=≤<=*n*,<=*m*,<=*k*<=≤<=1000) — the number of the planned days, the number of clean bowls and the number of clean plates.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=2). If *a**i* equals one, then on day *i* Valera will eat a first type dish. If *a**i* equals two, then on day *i* Valera will eat a second type dish.
|
Print a single integer — the minimum number of times Valera will need to wash a plate/bowl.
|
[
"3 1 1\n1 2 1\n",
"4 3 1\n1 1 1 1\n",
"3 1 2\n2 2 2\n",
"8 2 2\n1 2 1 2 1 2 1 2\n"
] |
[
"1\n",
"1\n",
"0\n",
"4\n"
] |
In the first sample Valera will wash a bowl only on the third day, so the answer is one.
In the second sample, Valera will have the first type of the dish during all four days, and since there are only three bowls, he will wash a bowl exactly once.
In the third sample, Valera will have the second type of dish for all three days, and as they can be eaten from either a plate or a bowl, he will never need to wash a plate/bowl.
| 500
|
[
{
"input": "3 1 1\n1 2 1",
"output": "1"
},
{
"input": "4 3 1\n1 1 1 1",
"output": "1"
},
{
"input": "3 1 2\n2 2 2",
"output": "0"
},
{
"input": "8 2 2\n1 2 1 2 1 2 1 2",
"output": "4"
},
{
"input": "2 100 100\n2 2",
"output": "0"
},
{
"input": "1 1 1\n2",
"output": "0"
},
{
"input": "233 100 1\n2 2 1 1 1 2 2 2 2 1 1 2 2 2 1 2 2 1 1 1 2 2 1 1 1 1 2 1 2 2 1 1 2 2 1 2 2 1 2 1 2 1 2 2 2 1 1 1 1 2 1 2 1 1 2 1 1 2 2 1 2 1 2 1 1 1 1 1 1 1 1 1 2 1 2 2 2 1 1 2 2 1 1 1 1 2 1 1 2 1 2 2 2 1 1 1 2 2 2 1 1 1 1 2 1 2 1 1 1 1 2 2 2 1 1 2 1 2 1 1 1 1 1 2 1 1 1 1 1 2 1 1 2 2 1 2 1 1 2 2 1 1 2 2 1 1 1 2 2 1 1 2 1 2 1 2 2 1 2 2 2 2 2 1 2 2 2 2 2 1 2 2 1 2 2 1 1 1 2 2 1 1 2 2 1 1 2 1 1 2 2 1 2 2 2 2 2 2 1 2 2 2 2 2 1 1 2 2 2 2 2 2 1 1 1 2 1 2 2 2 2 2 2 2 2 1 1 2 1 2 1 2 2",
"output": "132"
},
{
"input": "123 100 1\n2 2 2 1 1 2 2 2 2 1 1 2 2 2 1 2 2 2 2 1 2 2 2 1 1 1 2 2 2 2 1 2 2 2 2 2 2 1 2 1 2 1 2 2 2 1 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 2 1 1 1 1 1 1 1 1 1 2 2 2 2 2 1 1 2 2 1 1 1 1 2 1 2 2 1 2 2 2 1 1 1 2 2 2 1 2 2 2 2 1 2 2 2 2 1 2 2 2 1 1 2 1 2 1 2 1 1 1",
"output": "22"
},
{
"input": "188 100 1\n2 2 1 1 1 2 2 2 2 1 1 2 2 2 1 2 2 1 1 1 2 2 1 1 1 1 2 1 2 2 1 1 2 2 1 2 2 1 2 1 2 1 2 2 2 1 1 1 1 2 1 2 1 1 2 1 1 2 2 1 2 1 2 1 1 1 1 1 1 1 1 1 2 1 2 2 2 1 1 2 2 1 1 1 1 2 1 1 2 1 2 2 2 1 1 1 2 2 2 1 1 1 1 2 1 2 1 1 1 1 2 2 2 1 1 2 1 2 1 1 1 1 1 2 1 1 1 1 1 2 1 1 2 2 1 2 1 1 2 2 1 1 2 2 1 1 1 2 2 1 1 2 1 2 1 2 2 1 2 2 2 2 2 1 2 2 2 2 2 1 2 2 1 2 2 1 1 1 2 2 1 1 2 2 1 1 2 1",
"output": "87"
},
{
"input": "3 1 2\n1 1 1",
"output": "2"
},
{
"input": "3 2 2\n1 1 1",
"output": "1"
},
{
"input": "3 2 1\n1 1 1",
"output": "1"
},
{
"input": "3 1 1\n1 1 1",
"output": "2"
},
{
"input": "5 1 2\n2 2 2 2 2",
"output": "2"
},
{
"input": "5 2 2\n2 2 2 2 2",
"output": "1"
},
{
"input": "5 2 1\n2 2 2 2 2",
"output": "2"
},
{
"input": "5 1 1\n2 2 2 2 2",
"output": "3"
},
{
"input": "1 1 2\n2",
"output": "0"
},
{
"input": "1 2 2\n2",
"output": "0"
},
{
"input": "1 2 1\n2",
"output": "0"
},
{
"input": "1 1 1\n2",
"output": "0"
},
{
"input": "6 3 1\n1 1 2 2 2 2",
"output": "2"
},
{
"input": "100 40 20\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "40"
},
{
"input": "7 5 2\n2 2 1 1 1 1 1",
"output": "0"
},
{
"input": "10 4 4\n2 2 2 2 2 2 1 1 1 1",
"output": "2"
},
{
"input": "3 2 1\n2 1 1",
"output": "0"
},
{
"input": "7 6 1\n2 1 1 1 1 1 1",
"output": "0"
},
{
"input": "7 5 1\n1 1 1 2 2 2 2",
"output": "1"
},
{
"input": "5 3 1\n1 1 2 2 2",
"output": "1"
},
{
"input": "3 1 1\n2 2 2",
"output": "1"
},
{
"input": "5 2 2\n2 2 2 2 2",
"output": "1"
},
{
"input": "3 1 3\n1 1 1",
"output": "2"
},
{
"input": "5 2 1\n1 1 2 2 2",
"output": "2"
},
{
"input": "4 3 2\n2 1 1 1",
"output": "0"
},
{
"input": "4 2 1\n1 2 2 2",
"output": "1"
},
{
"input": "14 4 7\n1 1 1 2 2 2 2 2 2 2 2 2 2 2",
"output": "3"
},
{
"input": "12 10 4\n2 2 2 2 2 2 1 1 1 1 1 1",
"output": "0"
},
{
"input": "5 3 2\n2 2 1 1 1",
"output": "0"
}
] | 1,645,914,710
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 63
| 46
| 0
|
days, bowls, dishes = map(int, input().split())
meals = input().split(" ")
wash = 0
for meal in meals:
if int(meal) == 1:
if bowls <= 0:
wash += 1
else:
bowls -= 1
else:
if dishes > 0:
dishes -= 1
elif bowls > 0:
bowls -= 1
else:
wash += 1
print(wash)
|
Title: Valera and Plates
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera is a lazy student. He has *m* clean bowls and *k* clean plates.
Valera has made an eating plan for the next *n* days. As Valera is lazy, he will eat exactly one dish per day. At that, in order to eat a dish, he needs exactly one clean plate or bowl. We know that Valera can cook only two types of dishes. He can eat dishes of the first type from bowls and dishes of the second type from either bowls or plates.
When Valera finishes eating, he leaves a dirty plate/bowl behind. His life philosophy doesn't let him eat from dirty kitchenware. So sometimes he needs to wash his plate/bowl before eating. Find the minimum number of times Valera will need to wash a plate/bowl, if he acts optimally.
Input Specification:
The first line of the input contains three integers *n*, *m*, *k* (1<=≤<=*n*,<=*m*,<=*k*<=≤<=1000) — the number of the planned days, the number of clean bowls and the number of clean plates.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=2). If *a**i* equals one, then on day *i* Valera will eat a first type dish. If *a**i* equals two, then on day *i* Valera will eat a second type dish.
Output Specification:
Print a single integer — the minimum number of times Valera will need to wash a plate/bowl.
Demo Input:
['3 1 1\n1 2 1\n', '4 3 1\n1 1 1 1\n', '3 1 2\n2 2 2\n', '8 2 2\n1 2 1 2 1 2 1 2\n']
Demo Output:
['1\n', '1\n', '0\n', '4\n']
Note:
In the first sample Valera will wash a bowl only on the third day, so the answer is one.
In the second sample, Valera will have the first type of the dish during all four days, and since there are only three bowls, he will wash a bowl exactly once.
In the third sample, Valera will have the second type of dish for all three days, and as they can be eaten from either a plate or a bowl, he will never need to wash a plate/bowl.
|
```python
days, bowls, dishes = map(int, input().split())
meals = input().split(" ")
wash = 0
for meal in meals:
if int(meal) == 1:
if bowls <= 0:
wash += 1
else:
bowls -= 1
else:
if dishes > 0:
dishes -= 1
elif bowls > 0:
bowls -= 1
else:
wash += 1
print(wash)
```
| 3
|
|
792
|
A
|
New Bus Route
|
PROGRAMMING
| 1,100
|
[
"implementation",
"sortings"
] | null | null |
There are *n* cities situated along the main road of Berland. Cities are represented by their coordinates — integer numbers *a*1,<=*a*2,<=...,<=*a**n*. All coordinates are pairwise distinct.
It is possible to get from one city to another only by bus. But all buses and roads are very old, so the Minister of Transport decided to build a new bus route. The Minister doesn't want to spend large amounts of money — he wants to choose two cities in such a way that the distance between them is minimal possible. The distance between two cities is equal to the absolute value of the difference between their coordinates.
It is possible that there are multiple pairs of cities with minimal possible distance, so the Minister wants to know the quantity of such pairs.
Your task is to write a program that will calculate the minimal possible distance between two pairs of cities and the quantity of pairs which have this distance.
|
The first line contains one integer number *n* (2<=≤<=*n*<=≤<=2·105).
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109). All numbers *a**i* are pairwise distinct.
|
Print two integer numbers — the minimal distance and the quantity of pairs with this distance.
|
[
"4\n6 -3 0 4\n",
"3\n-2 0 2\n"
] |
[
"2 1\n",
"2 2\n"
] |
In the first example the distance between the first city and the fourth city is |4 - 6| = 2, and it is the only pair with this distance.
| 0
|
[
{
"input": "4\n6 -3 0 4",
"output": "2 1"
},
{
"input": "3\n-2 0 2",
"output": "2 2"
},
{
"input": "2\n1 2",
"output": "1 1"
},
{
"input": "2\n1000000000 -1000000000",
"output": "2000000000 1"
},
{
"input": "5\n-979619606 -979619602 -979619604 -979619605 -979619603",
"output": "1 4"
},
{
"input": "5\n-799147771 -799147773 -799147764 -799147774 -799147770",
"output": "1 2"
},
{
"input": "20\n553280626 553280623 553280627 553280624 553280625 553280618 553280620 553280629 553280637 553280631 553280628 553280636 553280635 553280632 553280634 553280622 553280633 553280621 553280630 553280619",
"output": "1 19"
},
{
"input": "20\n105619866 106083760 106090730 105809555 106115212 105155938 105979518 106075627 106145216 105637844 105925719 105498536 105927000 106155938 106134226 106125969 106130588 105464813 106145509 106114971",
"output": "241 1"
},
{
"input": "10\n570685866 570685854 570685858 570685850 570685856 570685864 570685860 570685852 570685862 570685868",
"output": "2 9"
},
{
"input": "2\n1 1000000000",
"output": "999999999 1"
},
{
"input": "6\n1 2 3 4 5 6",
"output": "1 5"
},
{
"input": "3\n7 10 12",
"output": "2 1"
},
{
"input": "5\n-7 -5 -4 -3 -1",
"output": "1 2"
},
{
"input": "4\n-6 -4 -2 1",
"output": "2 2"
},
{
"input": "4\n3 5 7 8",
"output": "1 1"
},
{
"input": "9\n-9 -8 -7 -6 -5 -4 -3 -2 -1",
"output": "1 8"
},
{
"input": "2\n15 13",
"output": "2 1"
},
{
"input": "2\n14 13",
"output": "1 1"
},
{
"input": "2\n12 13",
"output": "1 1"
},
{
"input": "2\n-1000000000 13265920",
"output": "1013265920 1"
},
{
"input": "2\n8 10",
"output": "2 1"
}
] | 1,668,350,859
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 3
| 77
| 0
|
n=int(input())
a=sorted(list(map(int,input().split())))
mn=10**9
for i in range(n-1):
mn=min(mn,a[i+1]-a[i])
ans=0
for i in range(n-1):
ans+=mn==a[i+1]-a[i]
print(mn,ans)
|
Title: New Bus Route
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are *n* cities situated along the main road of Berland. Cities are represented by their coordinates — integer numbers *a*1,<=*a*2,<=...,<=*a**n*. All coordinates are pairwise distinct.
It is possible to get from one city to another only by bus. But all buses and roads are very old, so the Minister of Transport decided to build a new bus route. The Minister doesn't want to spend large amounts of money — he wants to choose two cities in such a way that the distance between them is minimal possible. The distance between two cities is equal to the absolute value of the difference between their coordinates.
It is possible that there are multiple pairs of cities with minimal possible distance, so the Minister wants to know the quantity of such pairs.
Your task is to write a program that will calculate the minimal possible distance between two pairs of cities and the quantity of pairs which have this distance.
Input Specification:
The first line contains one integer number *n* (2<=≤<=*n*<=≤<=2·105).
The second line contains *n* integer numbers *a*1,<=*a*2,<=...,<=*a**n* (<=-<=109<=≤<=*a**i*<=≤<=109). All numbers *a**i* are pairwise distinct.
Output Specification:
Print two integer numbers — the minimal distance and the quantity of pairs with this distance.
Demo Input:
['4\n6 -3 0 4\n', '3\n-2 0 2\n']
Demo Output:
['2 1\n', '2 2\n']
Note:
In the first example the distance between the first city and the fourth city is |4 - 6| = 2, and it is the only pair with this distance.
|
```python
n=int(input())
a=sorted(list(map(int,input().split())))
mn=10**9
for i in range(n-1):
mn=min(mn,a[i+1]-a[i])
ans=0
for i in range(n-1):
ans+=mn==a[i+1]-a[i]
print(mn,ans)
```
| 0
|
|
483
|
A
|
Counterexample
|
PROGRAMMING
| 1,100
|
[
"brute force",
"implementation",
"math",
"number theory"
] | null | null |
Your friend has recently learned about coprime numbers. A pair of numbers {*a*,<=*b*} is called coprime if the maximum number that divides both *a* and *b* is equal to one.
Your friend often comes up with different statements. He has recently supposed that if the pair (*a*,<=*b*) is coprime and the pair (*b*,<=*c*) is coprime, then the pair (*a*,<=*c*) is coprime.
You want to find a counterexample for your friend's statement. Therefore, your task is to find three distinct numbers (*a*,<=*b*,<=*c*), for which the statement is false, and the numbers meet the condition *l*<=≤<=*a*<=<<=*b*<=<<=*c*<=≤<=*r*.
More specifically, you need to find three numbers (*a*,<=*b*,<=*c*), such that *l*<=≤<=*a*<=<<=*b*<=<<=*c*<=≤<=*r*, pairs (*a*,<=*b*) and (*b*,<=*c*) are coprime, and pair (*a*,<=*c*) is not coprime.
|
The single line contains two positive space-separated integers *l*, *r* (1<=≤<=*l*<=≤<=*r*<=≤<=1018; *r*<=-<=*l*<=≤<=50).
|
Print three positive space-separated integers *a*, *b*, *c* — three distinct numbers (*a*,<=*b*,<=*c*) that form the counterexample. If there are several solutions, you are allowed to print any of them. The numbers must be printed in ascending order.
If the counterexample does not exist, print the single number -1.
|
[
"2 4\n",
"10 11\n",
"900000000000000009 900000000000000029\n"
] |
[
"2 3 4\n",
"-1\n",
"900000000000000009 900000000000000010 900000000000000021\n"
] |
In the first sample pair (2, 4) is not coprime and pairs (2, 3) and (3, 4) are.
In the second sample you cannot form a group of three distinct integers, so the answer is -1.
In the third sample it is easy to see that numbers 900000000000000009 and 900000000000000021 are divisible by three.
| 500
|
[
{
"input": "2 4",
"output": "2 3 4"
},
{
"input": "10 11",
"output": "-1"
},
{
"input": "900000000000000009 900000000000000029",
"output": "900000000000000009 900000000000000010 900000000000000021"
},
{
"input": "640097987171091791 640097987171091835",
"output": "640097987171091792 640097987171091793 640097987171091794"
},
{
"input": "19534350415104721 19534350415104725",
"output": "19534350415104722 19534350415104723 19534350415104724"
},
{
"input": "933700505788726243 933700505788726280",
"output": "933700505788726244 933700505788726245 933700505788726246"
},
{
"input": "1 3",
"output": "-1"
},
{
"input": "1 4",
"output": "2 3 4"
},
{
"input": "1 1",
"output": "-1"
},
{
"input": "266540997167959130 266540997167959164",
"output": "266540997167959130 266540997167959131 266540997167959132"
},
{
"input": "267367244641009850 267367244641009899",
"output": "267367244641009850 267367244641009851 267367244641009852"
},
{
"input": "268193483524125978 268193483524125993",
"output": "268193483524125978 268193483524125979 268193483524125980"
},
{
"input": "269019726702209402 269019726702209432",
"output": "269019726702209402 269019726702209403 269019726702209404"
},
{
"input": "269845965585325530 269845965585325576",
"output": "269845965585325530 269845965585325531 269845965585325532"
},
{
"input": "270672213058376250 270672213058376260",
"output": "270672213058376250 270672213058376251 270672213058376252"
},
{
"input": "271498451941492378 271498451941492378",
"output": "-1"
},
{
"input": "272324690824608506 272324690824608523",
"output": "272324690824608506 272324690824608507 272324690824608508"
},
{
"input": "273150934002691930 273150934002691962",
"output": "273150934002691930 273150934002691931 273150934002691932"
},
{
"input": "996517375802030516 996517375802030524",
"output": "996517375802030516 996517375802030517 996517375802030518"
},
{
"input": "997343614685146644 997343614685146694",
"output": "997343614685146644 997343614685146645 997343614685146646"
},
{
"input": "998169857863230068 998169857863230083",
"output": "998169857863230068 998169857863230069 998169857863230070"
},
{
"input": "998996101041313492 998996101041313522",
"output": "998996101041313492 998996101041313493 998996101041313494"
},
{
"input": "999822344219396916 999822344219396961",
"output": "999822344219396916 999822344219396917 999822344219396918"
},
{
"input": "648583102513043 648583102513053",
"output": "648583102513044 648583102513045 648583102513046"
},
{
"input": "266540997167959130 266540997167959131",
"output": "-1"
},
{
"input": "267367244641009850 267367244641009850",
"output": "-1"
},
{
"input": "268193483524125978 268193483524125979",
"output": "-1"
},
{
"input": "269019726702209402 269019726702209402",
"output": "-1"
},
{
"input": "269845965585325530 269845965585325530",
"output": "-1"
},
{
"input": "270672213058376250 270672213058376254",
"output": "270672213058376250 270672213058376251 270672213058376252"
},
{
"input": "271498451941492378 271498451941492379",
"output": "-1"
},
{
"input": "272324690824608506 272324690824608508",
"output": "272324690824608506 272324690824608507 272324690824608508"
},
{
"input": "273150934002691930 273150934002691931",
"output": "-1"
},
{
"input": "996517375802030516 996517375802030518",
"output": "996517375802030516 996517375802030517 996517375802030518"
},
{
"input": "997343614685146644 997343614685146644",
"output": "-1"
},
{
"input": "2147483647 2147483649",
"output": "-1"
},
{
"input": "3 5",
"output": "-1"
},
{
"input": "1 7",
"output": "2 3 4"
},
{
"input": "9 12",
"output": "9 11 12"
},
{
"input": "4 4",
"output": "-1"
},
{
"input": "11 13",
"output": "-1"
},
{
"input": "2 2",
"output": "-1"
}
] | 1,592,314,346
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 93
| 307,200
|
import math
def gcd(a, b):
if b == 0:
return a
return gcd(b, a % b)
l,r = [int(x) for x in input("").split()]
exists = False
i,j,k = [0,0,0]
for i in range(l, r+1):
for j in range(l, r+1):
for k in range(l, r+1):
if i == j or i == k or j == k:
continue
if gcd(i, j) == 1 and gcd(j, k) == 1 and gcd(i, k) != 1:
print(i, j, k)
exit()
print(-1)
|
Title: Counterexample
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Your friend has recently learned about coprime numbers. A pair of numbers {*a*,<=*b*} is called coprime if the maximum number that divides both *a* and *b* is equal to one.
Your friend often comes up with different statements. He has recently supposed that if the pair (*a*,<=*b*) is coprime and the pair (*b*,<=*c*) is coprime, then the pair (*a*,<=*c*) is coprime.
You want to find a counterexample for your friend's statement. Therefore, your task is to find three distinct numbers (*a*,<=*b*,<=*c*), for which the statement is false, and the numbers meet the condition *l*<=≤<=*a*<=<<=*b*<=<<=*c*<=≤<=*r*.
More specifically, you need to find three numbers (*a*,<=*b*,<=*c*), such that *l*<=≤<=*a*<=<<=*b*<=<<=*c*<=≤<=*r*, pairs (*a*,<=*b*) and (*b*,<=*c*) are coprime, and pair (*a*,<=*c*) is not coprime.
Input Specification:
The single line contains two positive space-separated integers *l*, *r* (1<=≤<=*l*<=≤<=*r*<=≤<=1018; *r*<=-<=*l*<=≤<=50).
Output Specification:
Print three positive space-separated integers *a*, *b*, *c* — three distinct numbers (*a*,<=*b*,<=*c*) that form the counterexample. If there are several solutions, you are allowed to print any of them. The numbers must be printed in ascending order.
If the counterexample does not exist, print the single number -1.
Demo Input:
['2 4\n', '10 11\n', '900000000000000009 900000000000000029\n']
Demo Output:
['2 3 4\n', '-1\n', '900000000000000009 900000000000000010 900000000000000021\n']
Note:
In the first sample pair (2, 4) is not coprime and pairs (2, 3) and (3, 4) are.
In the second sample you cannot form a group of three distinct integers, so the answer is -1.
In the third sample it is easy to see that numbers 900000000000000009 and 900000000000000021 are divisible by three.
|
```python
import math
def gcd(a, b):
if b == 0:
return a
return gcd(b, a % b)
l,r = [int(x) for x in input("").split()]
exists = False
i,j,k = [0,0,0]
for i in range(l, r+1):
for j in range(l, r+1):
for k in range(l, r+1):
if i == j or i == k or j == k:
continue
if gcd(i, j) == 1 and gcd(j, k) == 1 and gcd(i, k) != 1:
print(i, j, k)
exit()
print(-1)
```
| 0
|
|
550
|
A
|
Two Substrings
|
PROGRAMMING
| 1,500
|
[
"brute force",
"dp",
"greedy",
"implementation",
"strings"
] | null | null |
You are given string *s*. Your task is to determine if the given string *s* contains two non-overlapping substrings "AB" and "BA" (the substrings can go in any order).
|
The only line of input contains a string *s* of length between 1 and 105 consisting of uppercase Latin letters.
|
Print "YES" (without the quotes), if string *s* contains two non-overlapping substrings "AB" and "BA", and "NO" otherwise.
|
[
"ABA\n",
"BACFAB\n",
"AXBYBXA\n"
] |
[
"NO\n",
"YES\n",
"NO\n"
] |
In the first sample test, despite the fact that there are substrings "AB" and "BA", their occurrences overlap, so the answer is "NO".
In the second sample test there are the following occurrences of the substrings: BACFAB.
In the third sample test there is no substring "AB" nor substring "BA".
| 1,000
|
[
{
"input": "ABA",
"output": "NO"
},
{
"input": "BACFAB",
"output": "YES"
},
{
"input": "AXBYBXA",
"output": "NO"
},
{
"input": "ABABAB",
"output": "YES"
},
{
"input": "BBBBBBBBBB",
"output": "NO"
},
{
"input": "ABBA",
"output": "YES"
},
{
"input": "ABAXXXAB",
"output": "YES"
},
{
"input": "TESTABAXXABTEST",
"output": "YES"
},
{
"input": "A",
"output": "NO"
},
{
"input": "B",
"output": "NO"
},
{
"input": "X",
"output": "NO"
},
{
"input": "BA",
"output": "NO"
},
{
"input": "AB",
"output": "NO"
},
{
"input": "AA",
"output": "NO"
},
{
"input": "BB",
"output": "NO"
},
{
"input": "BAB",
"output": "NO"
},
{
"input": "AAB",
"output": "NO"
},
{
"input": "BAA",
"output": "NO"
},
{
"input": "ABB",
"output": "NO"
},
{
"input": "BBA",
"output": "NO"
},
{
"input": "AAA",
"output": "NO"
},
{
"input": "BBB",
"output": "NO"
},
{
"input": "AXBXBXA",
"output": "NO"
},
{
"input": "SKDSKDJABSDBADKFJDK",
"output": "YES"
},
{
"input": "ABAXXBBXXAA",
"output": "NO"
},
{
"input": "ABAB",
"output": "NO"
},
{
"input": "BABA",
"output": "NO"
},
{
"input": "AAAB",
"output": "NO"
},
{
"input": "AAAA",
"output": "NO"
},
{
"input": "AABA",
"output": "NO"
},
{
"input": "ABAA",
"output": "NO"
},
{
"input": "BAAA",
"output": "NO"
},
{
"input": "AABB",
"output": "NO"
},
{
"input": "BAAB",
"output": "YES"
},
{
"input": "BBAA",
"output": "NO"
},
{
"input": "BBBA",
"output": "NO"
},
{
"input": "BBAB",
"output": "NO"
},
{
"input": "BABB",
"output": "NO"
},
{
"input": "ABBB",
"output": "NO"
},
{
"input": "BBBB",
"output": "NO"
},
{
"input": "BABAB",
"output": "YES"
},
{
"input": "ABABA",
"output": "YES"
},
{
"input": "AAABAAACBBBC",
"output": "NO"
},
{
"input": "AABBBACBBBBBBAACBCCACBBAABBBBBCAACABAACABCACCBCBCCCBCBCABCBBCCBCBBAACBACAABACBBCACCBCCACCABBCBABBAAC",
"output": "YES"
},
{
"input": "CBBABDDBBADAC",
"output": "YES"
},
{
"input": "ABYFAB",
"output": "NO"
},
{
"input": "BABXXAB",
"output": "YES"
},
{
"input": "ABAXAB",
"output": "YES"
},
{
"input": "ABABXAB",
"output": "YES"
},
{
"input": "ABXABXABXABXABXBAXBAXBAXBA",
"output": "YES"
},
{
"input": "QQQQQQQQQABABQQQQQQQQ",
"output": "NO"
}
] | 1,697,207,548
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 85
| 46
| 102,400
|
string = input()
check_ab = string.find("AB")
check_ba = string.find("BA")
if (check_ab != -1 and string.find("BA", check_ab + 2) != -1) or (check_ba != -1 and string.find("AB", check_ba + 2) != -1):
print("YES")
else:
print("NO")
|
Title: Two Substrings
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given string *s*. Your task is to determine if the given string *s* contains two non-overlapping substrings "AB" and "BA" (the substrings can go in any order).
Input Specification:
The only line of input contains a string *s* of length between 1 and 105 consisting of uppercase Latin letters.
Output Specification:
Print "YES" (without the quotes), if string *s* contains two non-overlapping substrings "AB" and "BA", and "NO" otherwise.
Demo Input:
['ABA\n', 'BACFAB\n', 'AXBYBXA\n']
Demo Output:
['NO\n', 'YES\n', 'NO\n']
Note:
In the first sample test, despite the fact that there are substrings "AB" and "BA", their occurrences overlap, so the answer is "NO".
In the second sample test there are the following occurrences of the substrings: BACFAB.
In the third sample test there is no substring "AB" nor substring "BA".
|
```python
string = input()
check_ab = string.find("AB")
check_ba = string.find("BA")
if (check_ab != -1 and string.find("BA", check_ab + 2) != -1) or (check_ba != -1 and string.find("AB", check_ba + 2) != -1):
print("YES")
else:
print("NO")
```
| 3
|
|
369
|
A
|
Valera and Plates
|
PROGRAMMING
| 900
|
[
"greedy",
"implementation"
] | null | null |
Valera is a lazy student. He has *m* clean bowls and *k* clean plates.
Valera has made an eating plan for the next *n* days. As Valera is lazy, he will eat exactly one dish per day. At that, in order to eat a dish, he needs exactly one clean plate or bowl. We know that Valera can cook only two types of dishes. He can eat dishes of the first type from bowls and dishes of the second type from either bowls or plates.
When Valera finishes eating, he leaves a dirty plate/bowl behind. His life philosophy doesn't let him eat from dirty kitchenware. So sometimes he needs to wash his plate/bowl before eating. Find the minimum number of times Valera will need to wash a plate/bowl, if he acts optimally.
|
The first line of the input contains three integers *n*, *m*, *k* (1<=≤<=*n*,<=*m*,<=*k*<=≤<=1000) — the number of the planned days, the number of clean bowls and the number of clean plates.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=2). If *a**i* equals one, then on day *i* Valera will eat a first type dish. If *a**i* equals two, then on day *i* Valera will eat a second type dish.
|
Print a single integer — the minimum number of times Valera will need to wash a plate/bowl.
|
[
"3 1 1\n1 2 1\n",
"4 3 1\n1 1 1 1\n",
"3 1 2\n2 2 2\n",
"8 2 2\n1 2 1 2 1 2 1 2\n"
] |
[
"1\n",
"1\n",
"0\n",
"4\n"
] |
In the first sample Valera will wash a bowl only on the third day, so the answer is one.
In the second sample, Valera will have the first type of the dish during all four days, and since there are only three bowls, he will wash a bowl exactly once.
In the third sample, Valera will have the second type of dish for all three days, and as they can be eaten from either a plate or a bowl, he will never need to wash a plate/bowl.
| 500
|
[
{
"input": "3 1 1\n1 2 1",
"output": "1"
},
{
"input": "4 3 1\n1 1 1 1",
"output": "1"
},
{
"input": "3 1 2\n2 2 2",
"output": "0"
},
{
"input": "8 2 2\n1 2 1 2 1 2 1 2",
"output": "4"
},
{
"input": "2 100 100\n2 2",
"output": "0"
},
{
"input": "1 1 1\n2",
"output": "0"
},
{
"input": "233 100 1\n2 2 1 1 1 2 2 2 2 1 1 2 2 2 1 2 2 1 1 1 2 2 1 1 1 1 2 1 2 2 1 1 2 2 1 2 2 1 2 1 2 1 2 2 2 1 1 1 1 2 1 2 1 1 2 1 1 2 2 1 2 1 2 1 1 1 1 1 1 1 1 1 2 1 2 2 2 1 1 2 2 1 1 1 1 2 1 1 2 1 2 2 2 1 1 1 2 2 2 1 1 1 1 2 1 2 1 1 1 1 2 2 2 1 1 2 1 2 1 1 1 1 1 2 1 1 1 1 1 2 1 1 2 2 1 2 1 1 2 2 1 1 2 2 1 1 1 2 2 1 1 2 1 2 1 2 2 1 2 2 2 2 2 1 2 2 2 2 2 1 2 2 1 2 2 1 1 1 2 2 1 1 2 2 1 1 2 1 1 2 2 1 2 2 2 2 2 2 1 2 2 2 2 2 1 1 2 2 2 2 2 2 1 1 1 2 1 2 2 2 2 2 2 2 2 1 1 2 1 2 1 2 2",
"output": "132"
},
{
"input": "123 100 1\n2 2 2 1 1 2 2 2 2 1 1 2 2 2 1 2 2 2 2 1 2 2 2 1 1 1 2 2 2 2 1 2 2 2 2 2 2 1 2 1 2 1 2 2 2 1 2 1 2 2 1 2 2 1 2 2 1 2 2 1 2 2 2 1 1 1 1 1 1 1 1 1 2 2 2 2 2 1 1 2 2 1 1 1 1 2 1 2 2 1 2 2 2 1 1 1 2 2 2 1 2 2 2 2 1 2 2 2 2 1 2 2 2 1 1 2 1 2 1 2 1 1 1",
"output": "22"
},
{
"input": "188 100 1\n2 2 1 1 1 2 2 2 2 1 1 2 2 2 1 2 2 1 1 1 2 2 1 1 1 1 2 1 2 2 1 1 2 2 1 2 2 1 2 1 2 1 2 2 2 1 1 1 1 2 1 2 1 1 2 1 1 2 2 1 2 1 2 1 1 1 1 1 1 1 1 1 2 1 2 2 2 1 1 2 2 1 1 1 1 2 1 1 2 1 2 2 2 1 1 1 2 2 2 1 1 1 1 2 1 2 1 1 1 1 2 2 2 1 1 2 1 2 1 1 1 1 1 2 1 1 1 1 1 2 1 1 2 2 1 2 1 1 2 2 1 1 2 2 1 1 1 2 2 1 1 2 1 2 1 2 2 1 2 2 2 2 2 1 2 2 2 2 2 1 2 2 1 2 2 1 1 1 2 2 1 1 2 2 1 1 2 1",
"output": "87"
},
{
"input": "3 1 2\n1 1 1",
"output": "2"
},
{
"input": "3 2 2\n1 1 1",
"output": "1"
},
{
"input": "3 2 1\n1 1 1",
"output": "1"
},
{
"input": "3 1 1\n1 1 1",
"output": "2"
},
{
"input": "5 1 2\n2 2 2 2 2",
"output": "2"
},
{
"input": "5 2 2\n2 2 2 2 2",
"output": "1"
},
{
"input": "5 2 1\n2 2 2 2 2",
"output": "2"
},
{
"input": "5 1 1\n2 2 2 2 2",
"output": "3"
},
{
"input": "1 1 2\n2",
"output": "0"
},
{
"input": "1 2 2\n2",
"output": "0"
},
{
"input": "1 2 1\n2",
"output": "0"
},
{
"input": "1 1 1\n2",
"output": "0"
},
{
"input": "6 3 1\n1 1 2 2 2 2",
"output": "2"
},
{
"input": "100 40 20\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "40"
},
{
"input": "7 5 2\n2 2 1 1 1 1 1",
"output": "0"
},
{
"input": "10 4 4\n2 2 2 2 2 2 1 1 1 1",
"output": "2"
},
{
"input": "3 2 1\n2 1 1",
"output": "0"
},
{
"input": "7 6 1\n2 1 1 1 1 1 1",
"output": "0"
},
{
"input": "7 5 1\n1 1 1 2 2 2 2",
"output": "1"
},
{
"input": "5 3 1\n1 1 2 2 2",
"output": "1"
},
{
"input": "3 1 1\n2 2 2",
"output": "1"
},
{
"input": "5 2 2\n2 2 2 2 2",
"output": "1"
},
{
"input": "3 1 3\n1 1 1",
"output": "2"
},
{
"input": "5 2 1\n1 1 2 2 2",
"output": "2"
},
{
"input": "4 3 2\n2 1 1 1",
"output": "0"
},
{
"input": "4 2 1\n1 2 2 2",
"output": "1"
},
{
"input": "14 4 7\n1 1 1 2 2 2 2 2 2 2 2 2 2 2",
"output": "3"
},
{
"input": "12 10 4\n2 2 2 2 2 2 1 1 1 1 1 1",
"output": "0"
},
{
"input": "5 3 2\n2 2 1 1 1",
"output": "0"
}
] | 1,552,587,359
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 93
| 0
|
N, Bowl, Plates = list(map(int, input().split()))
X = list(map(int, input().split()))
Count = 0
for i in range(len(X)):
Plates -= (1 if X[i] == 2 else 0)
Bowl -= (1 if Plates < 0 or X[i] == 1 else 0)
Count += (1 if Bowl < 0 else 0)
print(Count)
|
Title: Valera and Plates
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera is a lazy student. He has *m* clean bowls and *k* clean plates.
Valera has made an eating plan for the next *n* days. As Valera is lazy, he will eat exactly one dish per day. At that, in order to eat a dish, he needs exactly one clean plate or bowl. We know that Valera can cook only two types of dishes. He can eat dishes of the first type from bowls and dishes of the second type from either bowls or plates.
When Valera finishes eating, he leaves a dirty plate/bowl behind. His life philosophy doesn't let him eat from dirty kitchenware. So sometimes he needs to wash his plate/bowl before eating. Find the minimum number of times Valera will need to wash a plate/bowl, if he acts optimally.
Input Specification:
The first line of the input contains three integers *n*, *m*, *k* (1<=≤<=*n*,<=*m*,<=*k*<=≤<=1000) — the number of the planned days, the number of clean bowls and the number of clean plates.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=2). If *a**i* equals one, then on day *i* Valera will eat a first type dish. If *a**i* equals two, then on day *i* Valera will eat a second type dish.
Output Specification:
Print a single integer — the minimum number of times Valera will need to wash a plate/bowl.
Demo Input:
['3 1 1\n1 2 1\n', '4 3 1\n1 1 1 1\n', '3 1 2\n2 2 2\n', '8 2 2\n1 2 1 2 1 2 1 2\n']
Demo Output:
['1\n', '1\n', '0\n', '4\n']
Note:
In the first sample Valera will wash a bowl only on the third day, so the answer is one.
In the second sample, Valera will have the first type of the dish during all four days, and since there are only three bowls, he will wash a bowl exactly once.
In the third sample, Valera will have the second type of dish for all three days, and as they can be eaten from either a plate or a bowl, he will never need to wash a plate/bowl.
|
```python
N, Bowl, Plates = list(map(int, input().split()))
X = list(map(int, input().split()))
Count = 0
for i in range(len(X)):
Plates -= (1 if X[i] == 2 else 0)
Bowl -= (1 if Plates < 0 or X[i] == 1 else 0)
Count += (1 if Bowl < 0 else 0)
print(Count)
```
| 0
|
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Alice and Bob begin their day with a quick game. They first choose a starting number *X*0<=≥<=3 and try to reach one million by the process described below.
Alice goes first and then they take alternating turns. In the *i*-th turn, the player whose turn it is selects a prime number smaller than the current number, and announces the smallest multiple of this prime number that is not smaller than the current number.
Formally, he or she selects a prime *p*<=<<=*X**i*<=-<=1 and then finds the minimum *X**i*<=≥<=*X**i*<=-<=1 such that *p* divides *X**i*. Note that if the selected prime *p* already divides *X**i*<=-<=1, then the number does not change.
Eve has witnessed the state of the game after two turns. Given *X*2, help her determine what is the smallest possible starting number *X*0. Note that the players don't necessarily play optimally. You should consider all possible game evolutions.
|
The input contains a single integer *X*2 (4<=≤<=*X*2<=≤<=106). It is guaranteed that the integer *X*2 is composite, that is, is not prime.
|
Output a single integer — the minimum possible *X*0.
|
[
"14\n",
"20\n",
"8192\n"
] |
[
"6\n",
"15\n",
"8191\n"
] |
In the first test, the smallest possible starting number is *X*<sub class="lower-index">0</sub> = 6. One possible course of the game is as follows:
- Alice picks prime 5 and announces *X*<sub class="lower-index">1</sub> = 10 - Bob picks prime 7 and announces *X*<sub class="lower-index">2</sub> = 14.
In the second case, let *X*<sub class="lower-index">0</sub> = 15.
- Alice picks prime 2 and announces *X*<sub class="lower-index">1</sub> = 16 - Bob picks prime 5 and announces *X*<sub class="lower-index">2</sub> = 20.
| 0
|
[
{
"input": "14",
"output": "6"
},
{
"input": "20",
"output": "15"
},
{
"input": "8192",
"output": "8191"
},
{
"input": "1000000",
"output": "998677"
},
{
"input": "959806",
"output": "239958"
},
{
"input": "1452",
"output": "1206"
},
{
"input": "4",
"output": "3"
},
{
"input": "6",
"output": "3"
},
{
"input": "8",
"output": "7"
},
{
"input": "9",
"output": "7"
},
{
"input": "10",
"output": "4"
},
{
"input": "12",
"output": "6"
},
{
"input": "15",
"output": "8"
},
{
"input": "16",
"output": "11"
},
{
"input": "110880",
"output": "55440"
},
{
"input": "166320",
"output": "110879"
},
{
"input": "221760",
"output": "110880"
},
{
"input": "277200",
"output": "138600"
},
{
"input": "332640",
"output": "166320"
},
{
"input": "498960",
"output": "332639"
},
{
"input": "554400",
"output": "415798"
},
{
"input": "665280",
"output": "498958"
},
{
"input": "720720",
"output": "540538"
},
{
"input": "510510",
"output": "255248"
},
{
"input": "570570",
"output": "285282"
},
{
"input": "690690",
"output": "460455"
},
{
"input": "959818",
"output": "239958"
},
{
"input": "959878",
"output": "239978"
},
{
"input": "959902",
"output": "239978"
},
{
"input": "974847",
"output": "324954"
},
{
"input": "974859",
"output": "324978"
},
{
"input": "974931",
"output": "324980"
},
{
"input": "885481",
"output": "442272"
},
{
"input": "896809",
"output": "447944"
},
{
"input": "908209",
"output": "453632"
},
{
"input": "935089",
"output": "467064"
},
{
"input": "720721",
"output": "355298"
},
{
"input": "690691",
"output": "342864"
},
{
"input": "959903",
"output": "479702"
},
{
"input": "974932",
"output": "470060"
},
{
"input": "935090",
"output": "463950"
},
{
"input": "524288",
"output": "524287"
},
{
"input": "524289",
"output": "174768"
},
{
"input": "524286",
"output": "262110"
},
{
"input": "531441",
"output": "526737"
},
{
"input": "531442",
"output": "262490"
},
{
"input": "531440",
"output": "265704"
},
{
"input": "81",
"output": "76"
},
{
"input": "999958",
"output": "250008"
},
{
"input": "2048",
"output": "1959"
}
] | 1,521,493,792
| 5,392
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 3
| 639
| 11,059,200
|
def find_primes(primes,num):
lis = []
for x in range(2,int(num**0.5)+1):
if num%x == 0 and primes[x] == False:
lis.append(x)
if num%int(num/x) == 0 and primes[int(num/x)] == False:
lis.append(int(num/x))
return lis
def make_prime():
x = [False] * 10 ** 6
x[0] = True
x[1] = True
for i in range(2,(10**3)+1):
for j in range(i*i,(10**6),i):
x[j]=True
return x
bob_ann = int(input())
primes = make_prime()
bob_primes = find_primes(primes,bob_ann)
#print(bob_primes)
set1 = set()
for prime in bob_primes:
for x in range(bob_ann-prime+1,bob_ann+1):
if primes[x] == True:
set1.add(x)
alice_ann = sorted(set1)
#print(alice_ann)
results = 10**6
for ann in alice_ann:
prime1 = max(find_primes(primes,ann))
#print(prime1)
temp = ann - prime1 + 1
if results > temp:
results = temp
print(results)
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Alice and Bob begin their day with a quick game. They first choose a starting number *X*0<=≥<=3 and try to reach one million by the process described below.
Alice goes first and then they take alternating turns. In the *i*-th turn, the player whose turn it is selects a prime number smaller than the current number, and announces the smallest multiple of this prime number that is not smaller than the current number.
Formally, he or she selects a prime *p*<=<<=*X**i*<=-<=1 and then finds the minimum *X**i*<=≥<=*X**i*<=-<=1 such that *p* divides *X**i*. Note that if the selected prime *p* already divides *X**i*<=-<=1, then the number does not change.
Eve has witnessed the state of the game after two turns. Given *X*2, help her determine what is the smallest possible starting number *X*0. Note that the players don't necessarily play optimally. You should consider all possible game evolutions.
Input Specification:
The input contains a single integer *X*2 (4<=≤<=*X*2<=≤<=106). It is guaranteed that the integer *X*2 is composite, that is, is not prime.
Output Specification:
Output a single integer — the minimum possible *X*0.
Demo Input:
['14\n', '20\n', '8192\n']
Demo Output:
['6\n', '15\n', '8191\n']
Note:
In the first test, the smallest possible starting number is *X*<sub class="lower-index">0</sub> = 6. One possible course of the game is as follows:
- Alice picks prime 5 and announces *X*<sub class="lower-index">1</sub> = 10 - Bob picks prime 7 and announces *X*<sub class="lower-index">2</sub> = 14.
In the second case, let *X*<sub class="lower-index">0</sub> = 15.
- Alice picks prime 2 and announces *X*<sub class="lower-index">1</sub> = 16 - Bob picks prime 5 and announces *X*<sub class="lower-index">2</sub> = 20.
|
```python
def find_primes(primes,num):
lis = []
for x in range(2,int(num**0.5)+1):
if num%x == 0 and primes[x] == False:
lis.append(x)
if num%int(num/x) == 0 and primes[int(num/x)] == False:
lis.append(int(num/x))
return lis
def make_prime():
x = [False] * 10 ** 6
x[0] = True
x[1] = True
for i in range(2,(10**3)+1):
for j in range(i*i,(10**6),i):
x[j]=True
return x
bob_ann = int(input())
primes = make_prime()
bob_primes = find_primes(primes,bob_ann)
#print(bob_primes)
set1 = set()
for prime in bob_primes:
for x in range(bob_ann-prime+1,bob_ann+1):
if primes[x] == True:
set1.add(x)
alice_ann = sorted(set1)
#print(alice_ann)
results = 10**6
for ann in alice_ann:
prime1 = max(find_primes(primes,ann))
#print(prime1)
temp = ann - prime1 + 1
if results > temp:
results = temp
print(results)
```
| -1
|
|
263
|
A
|
Beautiful Matrix
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
You've got a 5<=×<=5 matrix, consisting of 24 zeroes and a single number one. Let's index the matrix rows by numbers from 1 to 5 from top to bottom, let's index the matrix columns by numbers from 1 to 5 from left to right. In one move, you are allowed to apply one of the two following transformations to the matrix:
1. Swap two neighboring matrix rows, that is, rows with indexes *i* and *i*<=+<=1 for some integer *i* (1<=≤<=*i*<=<<=5). 1. Swap two neighboring matrix columns, that is, columns with indexes *j* and *j*<=+<=1 for some integer *j* (1<=≤<=*j*<=<<=5).
You think that a matrix looks beautiful, if the single number one of the matrix is located in its middle (in the cell that is on the intersection of the third row and the third column). Count the minimum number of moves needed to make the matrix beautiful.
|
The input consists of five lines, each line contains five integers: the *j*-th integer in the *i*-th line of the input represents the element of the matrix that is located on the intersection of the *i*-th row and the *j*-th column. It is guaranteed that the matrix consists of 24 zeroes and a single number one.
|
Print a single integer — the minimum number of moves needed to make the matrix beautiful.
|
[
"0 0 0 0 0\n0 0 0 0 1\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n",
"0 0 0 0 0\n0 0 0 0 0\n0 1 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n"
] |
[
"3\n",
"1\n"
] |
none
| 500
|
[
{
"input": "0 0 0 0 0\n0 0 0 0 1\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 1 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "1"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 1 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "0"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 1",
"output": "4"
},
{
"input": "0 1 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "3"
},
{
"input": "1 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "4"
},
{
"input": "0 0 1 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 1 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 1\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "4"
},
{
"input": "0 0 0 0 0\n1 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 0\n0 1 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 1 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "1"
},
{
"input": "0 0 0 0 0\n0 0 0 1 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n1 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 1 0\n0 0 0 0 0\n0 0 0 0 0",
"output": "1"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 1\n0 0 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n1 0 0 0 0\n0 0 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 1 0 0 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 1 0 0\n0 0 0 0 0",
"output": "1"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 1 0\n0 0 0 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 1\n0 0 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n1 0 0 0 0",
"output": "4"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 1 0 0 0",
"output": "3"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 1 0 0",
"output": "2"
},
{
"input": "0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 1 0",
"output": "3"
}
] | 1,694,510,768
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 25
| 62
| 0
|
for i in range(5):
a=list(map(int,input().split()))
if 1 in a:
b=a
p=i+1
for m in range(5):
if b[m]==1:
n=m+1
answer=abs(p-3)+abs(n-3)
print(answer)
|
Title: Beautiful Matrix
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You've got a 5<=×<=5 matrix, consisting of 24 zeroes and a single number one. Let's index the matrix rows by numbers from 1 to 5 from top to bottom, let's index the matrix columns by numbers from 1 to 5 from left to right. In one move, you are allowed to apply one of the two following transformations to the matrix:
1. Swap two neighboring matrix rows, that is, rows with indexes *i* and *i*<=+<=1 for some integer *i* (1<=≤<=*i*<=<<=5). 1. Swap two neighboring matrix columns, that is, columns with indexes *j* and *j*<=+<=1 for some integer *j* (1<=≤<=*j*<=<<=5).
You think that a matrix looks beautiful, if the single number one of the matrix is located in its middle (in the cell that is on the intersection of the third row and the third column). Count the minimum number of moves needed to make the matrix beautiful.
Input Specification:
The input consists of five lines, each line contains five integers: the *j*-th integer in the *i*-th line of the input represents the element of the matrix that is located on the intersection of the *i*-th row and the *j*-th column. It is guaranteed that the matrix consists of 24 zeroes and a single number one.
Output Specification:
Print a single integer — the minimum number of moves needed to make the matrix beautiful.
Demo Input:
['0 0 0 0 0\n0 0 0 0 1\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n', '0 0 0 0 0\n0 0 0 0 0\n0 1 0 0 0\n0 0 0 0 0\n0 0 0 0 0\n']
Demo Output:
['3\n', '1\n']
Note:
none
|
```python
for i in range(5):
a=list(map(int,input().split()))
if 1 in a:
b=a
p=i+1
for m in range(5):
if b[m]==1:
n=m+1
answer=abs(p-3)+abs(n-3)
print(answer)
```
| 3
|
|
69
|
A
|
Young Physicist
|
PROGRAMMING
| 1,000
|
[
"implementation",
"math"
] |
A. Young Physicist
|
2
|
256
|
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
|
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
|
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
|
[
"3\n4 1 7\n-2 4 -1\n1 -5 -3\n",
"3\n3 -1 7\n-5 2 -4\n2 -1 -3\n"
] |
[
"NO",
"YES"
] |
none
| 500
|
[
{
"input": "3\n4 1 7\n-2 4 -1\n1 -5 -3",
"output": "NO"
},
{
"input": "3\n3 -1 7\n-5 2 -4\n2 -1 -3",
"output": "YES"
},
{
"input": "10\n21 32 -46\n43 -35 21\n42 2 -50\n22 40 20\n-27 -9 38\n-4 1 1\n-40 6 -31\n-13 -2 34\n-21 34 -12\n-32 -29 41",
"output": "NO"
},
{
"input": "10\n25 -33 43\n-27 -42 28\n-35 -20 19\n41 -42 -1\n49 -39 -4\n-49 -22 7\n-19 29 41\n8 -27 -43\n8 34 9\n-11 -3 33",
"output": "NO"
},
{
"input": "10\n-6 21 18\n20 -11 -8\n37 -11 41\n-5 8 33\n29 23 32\n30 -33 -11\n39 -49 -36\n28 34 -49\n22 29 -34\n-18 -6 7",
"output": "NO"
},
{
"input": "10\n47 -2 -27\n0 26 -14\n5 -12 33\n2 18 3\n45 -30 -49\n4 -18 8\n-46 -44 -41\n-22 -10 -40\n-35 -21 26\n33 20 38",
"output": "NO"
},
{
"input": "13\n-3 -36 -46\n-11 -50 37\n42 -11 -15\n9 42 44\n-29 -12 24\n3 9 -40\n-35 13 50\n14 43 18\n-13 8 24\n-48 -15 10\n50 9 -50\n21 0 -50\n0 0 -6",
"output": "YES"
},
{
"input": "14\n43 23 17\n4 17 44\n5 -5 -16\n-43 -7 -6\n47 -48 12\n50 47 -45\n2 14 43\n37 -30 15\n4 -17 -11\n17 9 -45\n-50 -3 -8\n-50 0 0\n-50 0 0\n-16 0 0",
"output": "YES"
},
{
"input": "13\n29 49 -11\n38 -11 -20\n25 1 -40\n-11 28 11\n23 -19 1\n45 -41 -17\n-3 0 -19\n-13 -33 49\n-30 0 28\n34 17 45\n-50 9 -27\n-50 0 0\n-37 0 0",
"output": "YES"
},
{
"input": "12\n3 28 -35\n-32 -44 -17\n9 -25 -6\n-42 -22 20\n-19 15 38\n-21 38 48\n-1 -37 -28\n-10 -13 -50\n-5 21 29\n34 28 50\n50 11 -49\n34 0 0",
"output": "YES"
},
{
"input": "37\n-64 -79 26\n-22 59 93\n-5 39 -12\n77 -9 76\n55 -86 57\n83 100 -97\n-70 94 84\n-14 46 -94\n26 72 35\n14 78 -62\n17 82 92\n-57 11 91\n23 15 92\n-80 -1 1\n12 39 18\n-23 -99 -75\n-34 50 19\n-39 84 -7\n45 -30 -39\n-60 49 37\n45 -16 -72\n33 -51 -56\n-48 28 5\n97 91 88\n45 -82 -11\n-21 -15 -90\n-53 73 -26\n-74 85 -90\n-40 23 38\n100 -13 49\n32 -100 -100\n0 -100 -70\n0 -100 0\n0 -100 0\n0 -100 0\n0 -100 0\n0 -37 0",
"output": "YES"
},
{
"input": "4\n68 3 100\n68 21 -100\n-100 -24 0\n-36 0 0",
"output": "YES"
},
{
"input": "33\n-1 -46 -12\n45 -16 -21\n-11 45 -21\n-60 -42 -93\n-22 -45 93\n37 96 85\n-76 26 83\n-4 9 55\n7 -52 -9\n66 8 -85\n-100 -54 11\n-29 59 74\n-24 12 2\n-56 81 85\n-92 69 -52\n-26 -97 91\n54 59 -51\n58 21 -57\n7 68 56\n-47 -20 -51\n-59 77 -13\n-85 27 91\n79 60 -56\n66 -80 5\n21 -99 42\n-31 -29 98\n66 93 76\n-49 45 61\n100 -100 -100\n100 -100 -100\n66 -75 -100\n0 0 -100\n0 0 -87",
"output": "YES"
},
{
"input": "3\n1 2 3\n3 2 1\n0 0 0",
"output": "NO"
},
{
"input": "2\n5 -23 12\n0 0 0",
"output": "NO"
},
{
"input": "1\n0 0 0",
"output": "YES"
},
{
"input": "1\n1 -2 0",
"output": "NO"
},
{
"input": "2\n-23 77 -86\n23 -77 86",
"output": "YES"
},
{
"input": "26\n86 7 20\n-57 -64 39\n-45 6 -93\n-44 -21 100\n-11 -49 21\n73 -71 -80\n-2 -89 56\n-65 -2 7\n5 14 84\n57 41 13\n-12 69 54\n40 -25 27\n-17 -59 0\n64 -91 -30\n-53 9 42\n-54 -8 14\n-35 82 27\n-48 -59 -80\n88 70 79\n94 57 97\n44 63 25\n84 -90 -40\n-100 100 -100\n-92 100 -100\n0 10 -100\n0 0 -82",
"output": "YES"
},
{
"input": "42\n11 27 92\n-18 -56 -57\n1 71 81\n33 -92 30\n82 83 49\n-87 -61 -1\n-49 45 49\n73 26 15\n-22 22 -77\n29 -93 87\n-68 44 -90\n-4 -84 20\n85 67 -6\n-39 26 77\n-28 -64 20\n65 -97 24\n-72 -39 51\n35 -75 -91\n39 -44 -8\n-25 -27 -57\n91 8 -46\n-98 -94 56\n94 -60 59\n-9 -95 18\n-53 -37 98\n-8 -94 -84\n-52 55 60\n15 -14 37\n65 -43 -25\n94 12 66\n-8 -19 -83\n29 81 -78\n-58 57 33\n24 86 -84\n-53 32 -88\n-14 7 3\n89 97 -53\n-5 -28 -91\n-100 100 -6\n-84 100 0\n0 100 0\n0 70 0",
"output": "YES"
},
{
"input": "3\n96 49 -12\n2 -66 28\n-98 17 -16",
"output": "YES"
},
{
"input": "5\n70 -46 86\n-100 94 24\n-27 63 -63\n57 -100 -47\n0 -11 0",
"output": "YES"
},
{
"input": "18\n-86 -28 70\n-31 -89 42\n31 -48 -55\n95 -17 -43\n24 -95 -85\n-21 -14 31\n68 -18 81\n13 31 60\n-15 28 99\n-42 15 9\n28 -61 -62\n-16 71 29\n-28 75 -48\n-77 -67 36\n-100 83 89\n100 100 -100\n57 34 -100\n0 0 -53",
"output": "YES"
},
{
"input": "44\n52 -54 -29\n-82 -5 -94\n-54 43 43\n91 16 71\n7 80 -91\n3 15 29\n-99 -6 -77\n-3 -77 -64\n73 67 34\n25 -10 -18\n-29 91 63\n-72 86 -16\n-68 85 -81\n-3 36 44\n-74 -14 -80\n34 -96 -97\n-76 -78 -33\n-24 44 -58\n98 12 77\n95 -63 -6\n-51 3 -90\n-92 -10 72\n7 3 -68\n57 -53 71\n29 57 -48\n35 -60 10\n79 -70 -61\n-20 77 55\n-86 -15 -35\n84 -88 -18\n100 -42 77\n-20 46 8\n-41 -43 -65\n38 -98 -23\n-100 65 45\n-7 -91 -63\n46 88 -85\n48 59 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 1",
"output": "YES"
},
{
"input": "18\n-14 -64 -91\n-8 -66 -86\n-23 92 -40\n6 -3 -53\n57 41 78\n-79 42 -22\n-88 -17 45\n4 -45 44\n83 -18 -25\n34 86 -92\n75 -30 12\n44 99 11\n-67 -13 72\n22 83 -56\n-37 71 72\n-9 -100 100\n0 -100 31\n0 -58 0",
"output": "YES"
},
{
"input": "23\n-70 37 78\n42 84 6\n28 -94 -24\n-49 76 95\n-67 18 84\n-53 78 -5\n65 -63 -64\n-66 -64 -69\n81 -93 95\n10 52 -79\n-89 -61 -64\n-64 -47 43\n-81 -35 55\n80 82 73\n-60 -81 -18\n49 -10 -19\n-58 70 12\n-24 -15 -93\n98 -93 -54\n-28 -75 11\n100 100 -63\n100 100 0\n56 34 0",
"output": "YES"
},
{
"input": "3\n0 2 -2\n1 -1 3\n-3 0 0",
"output": "NO"
}
] | 1,595,853,969
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 81
| 218
| 6,963,200
|
import sys, os.path
if os.path.exists('input.txt'):
sys.stdin = open('input.txt', 'r')
sys.stdout = open('output.txt', 'w')
n=int(input())
x=[]
y=[]
z=[]
for i in range(n):
a,b,c=map(int,input().split())
x.append(a)
y.append(b)
z.append(c)
if sum(x)==0 and sum(y)==0 and sum(z)==0:
print("YES")
else:
print("NO")
|
Title: Young Physicist
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
Input Specification:
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
Output Specification:
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
Demo Input:
['3\n4 1 7\n-2 4 -1\n1 -5 -3\n', '3\n3 -1 7\n-5 2 -4\n2 -1 -3\n']
Demo Output:
['NO', 'YES']
Note:
none
|
```python
import sys, os.path
if os.path.exists('input.txt'):
sys.stdin = open('input.txt', 'r')
sys.stdout = open('output.txt', 'w')
n=int(input())
x=[]
y=[]
z=[]
for i in range(n):
a,b,c=map(int,input().split())
x.append(a)
y.append(b)
z.append(c)
if sum(x)==0 and sum(y)==0 and sum(z)==0:
print("YES")
else:
print("NO")
```
| 3.93253
|
79
|
B
|
Colorful Field
|
PROGRAMMING
| 1,400
|
[
"implementation",
"sortings"
] |
B. Colorful Field
|
2
|
256
|
Fox Ciel saw a large field while she was on a bus. The field was a *n*<=×<=*m* rectangle divided into 1<=×<=1 cells. Some cells were wasteland, and other each cell contained crop plants: either carrots or kiwis or grapes.
After seeing the field carefully, Ciel found that the crop plants of each cell were planted in following procedure:
- Assume that the rows are numbered 1 to *n* from top to bottom and the columns are numbered 1 to *m* from left to right, and a cell in row *i* and column *j* is represented as (*i*,<=*j*). - First, each field is either cultivated or waste. Crop plants will be planted in the cultivated cells in the order of (1,<=1)<=→<=...<=→<=(1,<=*m*)<=→<=(2,<=1)<=→<=...<=→<=(2,<=*m*)<=→<=...<=→<=(*n*,<=1)<=→<=...<=→<=(*n*,<=*m*). Waste cells will be ignored. - Crop plants (either carrots or kiwis or grapes) will be planted in each cell one after another cyclically. Carrots will be planted in the first cell, then kiwis in the second one, grapes in the third one, carrots in the forth one, kiwis in the fifth one, and so on.
The following figure will show you the example of this procedure. Here, a white square represents a cultivated cell, and a black square represents a waste cell.
Now she is wondering how to determine the crop plants in some certain cells.
|
In the first line there are four positive integers *n*,<=*m*,<=*k*,<=*t* (1<=≤<=*n*<=≤<=4·104,<=1<=≤<=*m*<=≤<=4·104,<=1<=≤<=*k*<=≤<=103,<=1<=≤<=*t*<=≤<=103), each of which represents the height of the field, the width of the field, the number of waste cells and the number of queries that ask the kind of crop plants in a certain cell.
Following each *k* lines contains two integers *a*,<=*b* (1<=≤<=*a*<=≤<=*n*,<=1<=≤<=*b*<=≤<=*m*), which denotes a cell (*a*,<=*b*) is waste. It is guaranteed that the same cell will not appear twice in this section.
Following each *t* lines contains two integers *i*,<=*j* (1<=≤<=*i*<=≤<=*n*,<=1<=≤<=*j*<=≤<=*m*), which is a query that asks you the kind of crop plants of a cell (*i*,<=*j*).
|
For each query, if the cell is waste, print Waste. Otherwise, print the name of crop plants in the cell: either Carrots or Kiwis or Grapes.
|
[
"4 5 5 6\n4 3\n1 3\n3 3\n2 5\n3 2\n1 3\n1 4\n2 3\n2 4\n1 1\n1 1\n"
] |
[
"Waste\nGrapes\nCarrots\nKiwis\nCarrots\nCarrots\n"
] |
The sample corresponds to the figure in the statement.
| 1,000
|
[
{
"input": "4 5 5 6\n4 3\n1 3\n3 3\n2 5\n3 2\n1 3\n1 4\n2 3\n2 4\n1 1\n1 1",
"output": "Waste\nGrapes\nCarrots\nKiwis\nCarrots\nCarrots"
},
{
"input": "2 3 2 2\n1 1\n2 2\n2 1\n2 2",
"output": "Grapes\nWaste"
},
{
"input": "31 31 31 4\n4 9\n16 27\n11 29\n8 28\n11 2\n10 7\n22 6\n1 25\n14 8\n9 7\n9 1\n2 3\n5 2\n21 16\n20 19\n23 14\n27 6\n25 21\n14 1\n18 14\n7 2\n19 12\n30 27\n4 27\n24 12\n25 20\n26 22\n21 17\n11 6\n5 28\n28 24\n17 30\n2 5\n30 10\n4 21",
"output": "Kiwis\nCarrots\nGrapes\nGrapes"
},
{
"input": "39898 39898 3 1\n4567 8901\n12345 23456\n24680 35679\n29292 12121",
"output": "Grapes"
},
{
"input": "1 1 1 1\n1 1\n1 1",
"output": "Waste"
},
{
"input": "1 2 1 2\n1 1\n1 2\n1 1",
"output": "Carrots\nWaste"
},
{
"input": "1 6 3 12\n1 2\n1 4\n1 6\n1 1\n1 2\n1 6\n1 2\n1 5\n1 3\n1 4\n1 5\n1 5\n1 4\n1 6\n1 3",
"output": "Carrots\nWaste\nWaste\nWaste\nGrapes\nKiwis\nWaste\nGrapes\nGrapes\nWaste\nWaste\nKiwis"
},
{
"input": "1 10 1 3\n1 5\n1 5\n1 5\n1 5",
"output": "Waste\nWaste\nWaste"
},
{
"input": "5 5 1 3\n2 2\n2 2\n2 2\n2 2",
"output": "Waste\nWaste\nWaste"
},
{
"input": "3 3 3 5\n1 1\n2 2\n3 3\n1 1\n2 2\n2 2\n2 2\n3 3",
"output": "Waste\nWaste\nWaste\nWaste\nWaste"
},
{
"input": "1 10 2 4\n1 9\n1 5\n1 5\n1 6\n1 9\n1 10",
"output": "Waste\nKiwis\nWaste\nKiwis"
},
{
"input": "5 2 2 1\n3 2\n4 2\n5 2",
"output": "Kiwis"
}
] | 1,685,548,127
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 1
| 92
| 0
|
import sys
from bisect import bisect_left
input = sys.stdin.readline
def solve(n, m, k, t, holes, queries):
holes.sort()
ans = ["Carrots", "Kiwis", "Grapes"]
for q in queries:
idx = bisect_left(holes, q)
if holes[idx] == q:
print("Waste")
continue
pos = q[0] * m + q[1] - idx
print(ans[pos % 3])
def main():
n, m, k, t = list(map(int, input().split()))
holes = [tuple(map(int, input().split())) for _ in range(k)]
queries = [tuple(map(int, input().split())) for _ in range(t)]
solve(n, m, k, t, holes, queries)
main()
|
Title: Colorful Field
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Fox Ciel saw a large field while she was on a bus. The field was a *n*<=×<=*m* rectangle divided into 1<=×<=1 cells. Some cells were wasteland, and other each cell contained crop plants: either carrots or kiwis or grapes.
After seeing the field carefully, Ciel found that the crop plants of each cell were planted in following procedure:
- Assume that the rows are numbered 1 to *n* from top to bottom and the columns are numbered 1 to *m* from left to right, and a cell in row *i* and column *j* is represented as (*i*,<=*j*). - First, each field is either cultivated or waste. Crop plants will be planted in the cultivated cells in the order of (1,<=1)<=→<=...<=→<=(1,<=*m*)<=→<=(2,<=1)<=→<=...<=→<=(2,<=*m*)<=→<=...<=→<=(*n*,<=1)<=→<=...<=→<=(*n*,<=*m*). Waste cells will be ignored. - Crop plants (either carrots or kiwis or grapes) will be planted in each cell one after another cyclically. Carrots will be planted in the first cell, then kiwis in the second one, grapes in the third one, carrots in the forth one, kiwis in the fifth one, and so on.
The following figure will show you the example of this procedure. Here, a white square represents a cultivated cell, and a black square represents a waste cell.
Now she is wondering how to determine the crop plants in some certain cells.
Input Specification:
In the first line there are four positive integers *n*,<=*m*,<=*k*,<=*t* (1<=≤<=*n*<=≤<=4·104,<=1<=≤<=*m*<=≤<=4·104,<=1<=≤<=*k*<=≤<=103,<=1<=≤<=*t*<=≤<=103), each of which represents the height of the field, the width of the field, the number of waste cells and the number of queries that ask the kind of crop plants in a certain cell.
Following each *k* lines contains two integers *a*,<=*b* (1<=≤<=*a*<=≤<=*n*,<=1<=≤<=*b*<=≤<=*m*), which denotes a cell (*a*,<=*b*) is waste. It is guaranteed that the same cell will not appear twice in this section.
Following each *t* lines contains two integers *i*,<=*j* (1<=≤<=*i*<=≤<=*n*,<=1<=≤<=*j*<=≤<=*m*), which is a query that asks you the kind of crop plants of a cell (*i*,<=*j*).
Output Specification:
For each query, if the cell is waste, print Waste. Otherwise, print the name of crop plants in the cell: either Carrots or Kiwis or Grapes.
Demo Input:
['4 5 5 6\n4 3\n1 3\n3 3\n2 5\n3 2\n1 3\n1 4\n2 3\n2 4\n1 1\n1 1\n']
Demo Output:
['Waste\nGrapes\nCarrots\nKiwis\nCarrots\nCarrots\n']
Note:
The sample corresponds to the figure in the statement.
|
```python
import sys
from bisect import bisect_left
input = sys.stdin.readline
def solve(n, m, k, t, holes, queries):
holes.sort()
ans = ["Carrots", "Kiwis", "Grapes"]
for q in queries:
idx = bisect_left(holes, q)
if holes[idx] == q:
print("Waste")
continue
pos = q[0] * m + q[1] - idx
print(ans[pos % 3])
def main():
n, m, k, t = list(map(int, input().split()))
holes = [tuple(map(int, input().split())) for _ in range(k)]
queries = [tuple(map(int, input().split())) for _ in range(t)]
solve(n, m, k, t, holes, queries)
main()
```
| 0
|
25
|
A
|
IQ test
|
PROGRAMMING
| 1,300
|
[
"brute force"
] |
A. IQ test
|
2
|
256
|
Bob is preparing to pass IQ test. The most frequent task in this test is to find out which one of the given *n* numbers differs from the others. Bob observed that one number usually differs from the others in evenness. Help Bob — to check his answers, he needs a program that among the given *n* numbers finds one that is different in evenness.
|
The first line contains integer *n* (3<=≤<=*n*<=≤<=100) — amount of numbers in the task. The second line contains *n* space-separated natural numbers, not exceeding 100. It is guaranteed, that exactly one of these numbers differs from the others in evenness.
|
Output index of number that differs from the others in evenness. Numbers are numbered from 1 in the input order.
|
[
"5\n2 4 7 8 10\n",
"4\n1 2 1 1\n"
] |
[
"3\n",
"2\n"
] |
none
| 0
|
[
{
"input": "5\n2 4 7 8 10",
"output": "3"
},
{
"input": "4\n1 2 1 1",
"output": "2"
},
{
"input": "3\n1 2 2",
"output": "1"
},
{
"input": "3\n100 99 100",
"output": "2"
},
{
"input": "3\n5 3 2",
"output": "3"
},
{
"input": "4\n43 28 1 91",
"output": "2"
},
{
"input": "4\n75 13 94 77",
"output": "3"
},
{
"input": "4\n97 8 27 3",
"output": "2"
},
{
"input": "10\n95 51 12 91 85 3 1 31 25 7",
"output": "3"
},
{
"input": "20\n88 96 66 51 14 88 2 92 18 72 18 88 20 30 4 82 90 100 24 46",
"output": "4"
},
{
"input": "30\n20 94 56 50 10 98 52 32 14 22 24 60 4 8 98 46 34 68 82 82 98 90 50 20 78 49 52 94 64 36",
"output": "26"
},
{
"input": "50\n79 27 77 57 37 45 27 49 65 33 57 21 71 19 75 85 65 61 23 97 85 9 23 1 9 3 99 77 77 21 79 69 15 37 15 7 93 81 13 89 91 31 45 93 15 97 55 80 85 83",
"output": "48"
},
{
"input": "60\n46 11 73 65 3 69 3 53 43 53 97 47 55 93 31 75 35 3 9 73 23 31 3 81 91 79 61 21 15 11 11 11 81 7 83 75 39 87 83 59 89 55 93 27 49 67 67 29 1 93 11 17 9 19 35 21 63 31 31 25",
"output": "1"
},
{
"input": "70\n28 42 42 92 64 54 22 38 38 78 62 38 4 38 14 66 4 92 66 58 94 26 4 44 41 88 48 82 44 26 74 44 48 4 16 92 34 38 26 64 94 4 30 78 50 54 12 90 8 16 80 98 28 100 74 50 36 42 92 18 76 98 8 22 2 50 58 50 64 46",
"output": "25"
},
{
"input": "100\n43 35 79 53 13 91 91 45 65 83 57 9 42 39 85 45 71 51 61 59 31 13 63 39 25 21 79 39 91 67 21 61 97 75 93 83 29 79 59 97 11 37 63 51 39 55 91 23 21 17 47 23 35 75 49 5 69 99 5 7 41 17 25 89 15 79 21 63 53 81 43 91 59 91 69 99 85 15 91 51 49 37 65 7 89 81 21 93 61 63 97 93 45 17 13 69 57 25 75 73",
"output": "13"
},
{
"input": "100\n50 24 68 60 70 30 52 22 18 74 68 98 20 82 4 46 26 68 100 78 84 58 74 98 38 88 68 86 64 80 82 100 20 22 98 98 52 6 94 10 48 68 2 18 38 22 22 82 44 20 66 72 36 58 64 6 36 60 4 96 76 64 12 90 10 58 64 60 74 28 90 26 24 60 40 58 2 16 76 48 58 36 82 60 24 44 4 78 28 38 8 12 40 16 38 6 66 24 31 76",
"output": "99"
},
{
"input": "100\n47 48 94 48 14 18 94 36 96 22 12 30 94 20 48 98 40 58 2 94 8 36 98 18 98 68 2 60 76 38 18 100 8 72 100 68 2 86 92 72 58 16 48 14 6 58 72 76 6 88 80 66 20 28 74 62 86 68 90 86 2 56 34 38 56 90 4 8 76 44 32 86 12 98 38 34 54 92 70 94 10 24 82 66 90 58 62 2 32 58 100 22 58 72 2 22 68 72 42 14",
"output": "1"
},
{
"input": "99\n38 20 68 60 84 16 28 88 60 48 80 28 4 92 70 60 46 46 20 34 12 100 76 2 40 10 8 86 6 80 50 66 12 34 14 28 26 70 46 64 34 96 10 90 98 96 56 88 50 74 70 94 2 94 24 66 68 46 22 30 6 10 64 32 88 14 98 100 64 58 50 18 50 50 8 38 8 16 54 2 60 54 62 84 92 98 4 72 66 26 14 88 99 16 10 6 88 56 22",
"output": "93"
},
{
"input": "99\n50 83 43 89 53 47 69 1 5 37 63 87 95 15 55 95 75 89 33 53 89 75 93 75 11 85 49 29 11 97 49 67 87 11 25 37 97 73 67 49 87 43 53 97 43 29 53 33 45 91 37 73 39 49 59 5 21 43 87 35 5 63 89 57 63 47 29 99 19 85 13 13 3 13 43 19 5 9 61 51 51 57 15 89 13 97 41 13 99 79 13 27 97 95 73 33 99 27 23",
"output": "1"
},
{
"input": "98\n61 56 44 30 58 14 20 24 88 28 46 56 96 52 58 42 94 50 46 30 46 80 72 88 68 16 6 60 26 90 10 98 76 20 56 40 30 16 96 20 88 32 62 30 74 58 36 76 60 4 24 36 42 54 24 92 28 14 2 74 86 90 14 52 34 82 40 76 8 64 2 56 10 8 78 16 70 86 70 42 70 74 22 18 76 98 88 28 62 70 36 72 20 68 34 48 80 98",
"output": "1"
},
{
"input": "98\n66 26 46 42 78 32 76 42 26 82 8 12 4 10 24 26 64 44 100 46 94 64 30 18 88 28 8 66 30 82 82 28 74 52 62 80 80 60 94 86 64 32 44 88 92 20 12 74 94 28 34 58 4 22 16 10 94 76 82 58 40 66 22 6 30 32 92 54 16 76 74 98 18 48 48 30 92 2 16 42 84 74 30 60 64 52 50 26 16 86 58 96 79 60 20 62 82 94",
"output": "93"
},
{
"input": "95\n9 31 27 93 17 77 75 9 9 53 89 39 51 99 5 1 11 39 27 49 91 17 27 79 81 71 37 75 35 13 93 4 99 55 85 11 23 57 5 43 5 61 15 35 23 91 3 81 99 85 43 37 39 27 5 67 7 33 75 59 13 71 51 27 15 93 51 63 91 53 43 99 25 47 17 71 81 15 53 31 59 83 41 23 73 25 91 91 13 17 25 13 55 57 29",
"output": "32"
},
{
"input": "100\n91 89 81 45 53 1 41 3 77 93 55 97 55 97 87 27 69 95 73 41 93 21 75 35 53 56 5 51 87 59 91 67 33 3 99 45 83 17 97 47 75 97 7 89 17 99 23 23 81 25 55 97 27 35 69 5 77 35 93 19 55 59 37 21 31 37 49 41 91 53 73 69 7 37 37 39 17 71 7 97 55 17 47 23 15 73 31 39 57 37 9 5 61 41 65 57 77 79 35 47",
"output": "26"
},
{
"input": "99\n38 56 58 98 80 54 26 90 14 16 78 92 52 74 40 30 84 14 44 80 16 90 98 68 26 24 78 72 42 16 84 40 14 44 2 52 50 2 12 96 58 66 8 80 44 52 34 34 72 98 74 4 66 74 56 21 8 38 76 40 10 22 48 32 98 34 12 62 80 68 64 82 22 78 58 74 20 22 48 56 12 38 32 72 6 16 74 24 94 84 26 38 18 24 76 78 98 94 72",
"output": "56"
},
{
"input": "100\n44 40 6 40 56 90 98 8 36 64 76 86 98 76 36 92 6 30 98 70 24 98 96 60 24 82 88 68 86 96 34 42 58 10 40 26 56 10 88 58 70 32 24 28 14 82 52 12 62 36 70 60 52 34 74 30 78 76 10 16 42 94 66 90 70 38 52 12 58 22 98 96 14 68 24 70 4 30 84 98 8 50 14 52 66 34 100 10 28 100 56 48 38 12 38 14 91 80 70 86",
"output": "97"
},
{
"input": "100\n96 62 64 20 90 46 56 90 68 36 30 56 70 28 16 64 94 34 6 32 34 50 94 22 90 32 40 2 72 10 88 38 28 92 20 26 56 80 4 100 100 90 16 74 74 84 8 2 30 20 80 32 16 46 92 56 42 12 96 64 64 42 64 58 50 42 74 28 2 4 36 32 70 50 54 92 70 16 45 76 28 16 18 50 48 2 62 94 4 12 52 52 4 100 70 60 82 62 98 42",
"output": "79"
},
{
"input": "99\n14 26 34 68 90 58 50 36 8 16 18 6 2 74 54 20 36 84 32 50 52 2 26 24 3 64 20 10 54 26 66 44 28 72 4 96 78 90 96 86 68 28 94 4 12 46 100 32 22 36 84 32 44 94 76 94 4 52 12 30 74 4 34 64 58 72 44 16 70 56 54 8 14 74 8 6 58 62 98 54 14 40 80 20 36 72 28 98 20 58 40 52 90 64 22 48 54 70 52",
"output": "25"
},
{
"input": "95\n82 86 30 78 6 46 80 66 74 72 16 24 18 52 52 38 60 36 86 26 62 28 22 46 96 26 94 84 20 46 66 88 76 32 12 86 74 18 34 88 4 48 94 6 58 6 100 82 4 24 88 32 54 98 34 48 6 76 42 88 42 28 100 4 22 2 10 66 82 54 98 20 60 66 38 98 32 47 86 58 6 100 12 46 2 42 8 84 78 28 24 70 34 28 86",
"output": "78"
},
{
"input": "90\n40 50 8 42 76 24 58 42 26 68 20 48 54 12 34 84 14 36 32 88 6 50 96 56 20 92 48 16 40 34 96 46 20 84 30 50 20 98 8 44 96 42 8 76 70 38 84 30 40 88 84 72 2 22 52 58 16 62 100 66 80 40 50 32 14 62 88 72 22 99 76 50 84 82 8 82 98 46 26 40 2 98 18 78 30 72 70 18 34 68",
"output": "70"
},
{
"input": "80\n81 43 87 1 55 43 53 61 27 19 43 13 89 9 33 83 75 55 97 71 91 37 95 5 21 69 81 93 95 69 31 83 55 7 97 7 79 57 8 61 27 85 49 1 15 97 63 79 29 73 41 85 5 41 31 93 67 11 63 59 15 99 91 77 43 69 23 23 81 73 19 1 67 51 1 75 99 67 3 81",
"output": "39"
},
{
"input": "98\n13 83 61 27 35 1 85 95 97 73 95 65 73 45 5 43 27 83 91 19 11 3 85 59 9 39 69 23 45 7 51 85 5 71 5 95 1 51 75 3 43 57 3 11 33 71 21 99 47 41 87 39 71 87 31 85 91 49 83 5 49 85 47 91 55 99 33 23 31 23 23 73 29 77 55 31 25 5 81 49 91 15 15 39 87 5 9 40 69 47 29 33 11 21 49 79 51 83",
"output": "88"
},
{
"input": "3\n100 100 1",
"output": "3"
}
] | 1,636,977,741
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
#include <iostream>
using namespace std;
int main()
{
int n,e=0,o=0;
cin>>n;
int a[n];
for (int i=0; i<n; i++)
{
cin>>a[i];
if (a[i]%2==0)
{
e++;
}
else
{
o++;
}
}
if (e>o)
{
for (int i=2; i<n; i++)
{
if (a[i]%2!=0)
{
cout<<i+1;
break;
}
}
}
else
{
for (int i=0; i<n; i++)
{
if (a[i]%2!=0)
{
cout<<i+1;
break;
}
}
}
return 0;
}
|
Title: IQ test
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Bob is preparing to pass IQ test. The most frequent task in this test is to find out which one of the given *n* numbers differs from the others. Bob observed that one number usually differs from the others in evenness. Help Bob — to check his answers, he needs a program that among the given *n* numbers finds one that is different in evenness.
Input Specification:
The first line contains integer *n* (3<=≤<=*n*<=≤<=100) — amount of numbers in the task. The second line contains *n* space-separated natural numbers, not exceeding 100. It is guaranteed, that exactly one of these numbers differs from the others in evenness.
Output Specification:
Output index of number that differs from the others in evenness. Numbers are numbered from 1 in the input order.
Demo Input:
['5\n2 4 7 8 10\n', '4\n1 2 1 1\n']
Demo Output:
['3\n', '2\n']
Note:
none
|
```python
#include <iostream>
using namespace std;
int main()
{
int n,e=0,o=0;
cin>>n;
int a[n];
for (int i=0; i<n; i++)
{
cin>>a[i];
if (a[i]%2==0)
{
e++;
}
else
{
o++;
}
}
if (e>o)
{
for (int i=2; i<n; i++)
{
if (a[i]%2!=0)
{
cout<<i+1;
break;
}
}
}
else
{
for (int i=0; i<n; i++)
{
if (a[i]%2!=0)
{
cout<<i+1;
break;
}
}
}
return 0;
}
```
| -1
|
144
|
A
|
Arrival of the General
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
A Ministry for Defense sent a general to inspect the Super Secret Military Squad under the command of the Colonel SuperDuper. Having learned the news, the colonel ordered to all *n* squad soldiers to line up on the parade ground.
By the military charter the soldiers should stand in the order of non-increasing of their height. But as there's virtually no time to do that, the soldiers lined up in the arbitrary order. However, the general is rather short-sighted and he thinks that the soldiers lined up correctly if the first soldier in the line has the maximum height and the last soldier has the minimum height. Please note that the way other solders are positioned does not matter, including the case when there are several soldiers whose height is maximum or minimum. Only the heights of the first and the last soldier are important.
For example, the general considers the sequence of heights (4, 3, 4, 2, 1, 1) correct and the sequence (4, 3, 1, 2, 2) wrong.
Within one second the colonel can swap any two neighboring soldiers. Help him count the minimum time needed to form a line-up which the general will consider correct.
|
The first input line contains the only integer *n* (2<=≤<=*n*<=≤<=100) which represents the number of soldiers in the line. The second line contains integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100) the values of the soldiers' heights in the order of soldiers' heights' increasing in the order from the beginning of the line to its end. The numbers are space-separated. Numbers *a*1,<=*a*2,<=...,<=*a**n* are not necessarily different.
|
Print the only integer — the minimum number of seconds the colonel will need to form a line-up the general will like.
|
[
"4\n33 44 11 22\n",
"7\n10 10 58 31 63 40 76\n"
] |
[
"2\n",
"10\n"
] |
In the first sample the colonel will need to swap the first and second soldier and then the third and fourth soldier. That will take 2 seconds. The resulting position of the soldiers is (44, 33, 22, 11).
In the second sample the colonel may swap the soldiers in the following sequence:
1. (10, 10, 58, 31, 63, 40, 76) 1. (10, 58, 10, 31, 63, 40, 76) 1. (10, 58, 10, 31, 63, 76, 40) 1. (10, 58, 10, 31, 76, 63, 40) 1. (10, 58, 31, 10, 76, 63, 40) 1. (10, 58, 31, 76, 10, 63, 40) 1. (10, 58, 31, 76, 63, 10, 40) 1. (10, 58, 76, 31, 63, 10, 40) 1. (10, 76, 58, 31, 63, 10, 40) 1. (76, 10, 58, 31, 63, 10, 40) 1. (76, 10, 58, 31, 63, 40, 10)
| 500
|
[
{
"input": "4\n33 44 11 22",
"output": "2"
},
{
"input": "7\n10 10 58 31 63 40 76",
"output": "10"
},
{
"input": "2\n88 89",
"output": "1"
},
{
"input": "5\n100 95 100 100 88",
"output": "0"
},
{
"input": "7\n48 48 48 48 45 45 45",
"output": "0"
},
{
"input": "10\n68 47 67 29 63 71 71 65 54 56",
"output": "10"
},
{
"input": "15\n77 68 96 60 92 75 61 60 66 79 80 65 60 95 92",
"output": "4"
},
{
"input": "3\n1 2 1",
"output": "1"
},
{
"input": "20\n30 30 30 14 30 14 30 30 30 14 30 14 14 30 14 14 30 14 14 14",
"output": "0"
},
{
"input": "35\n37 41 46 39 47 39 44 47 44 42 44 43 47 39 46 39 38 42 39 37 40 44 41 42 41 42 39 42 36 36 42 36 42 42 42",
"output": "7"
},
{
"input": "40\n99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 99 98 99 99 99 99 99 99 99 99 100 99 99 99 99 99 99",
"output": "47"
},
{
"input": "50\n48 52 44 54 53 56 62 49 39 41 53 39 40 64 53 50 62 48 40 52 51 48 40 52 61 62 62 61 48 64 55 57 56 40 48 58 41 60 60 56 64 50 64 45 48 45 46 63 59 57",
"output": "50"
},
{
"input": "57\n7 24 17 19 6 19 10 11 12 22 14 5 5 11 13 10 24 19 24 24 24 11 21 20 4 14 24 24 18 13 24 3 20 3 3 3 3 9 3 9 22 22 16 3 3 3 15 11 3 3 8 17 10 13 3 14 13",
"output": "3"
},
{
"input": "65\n58 50 35 44 35 37 36 58 38 36 58 56 56 49 48 56 58 43 40 44 52 44 58 58 57 50 43 35 55 39 38 49 53 56 50 42 41 56 34 57 49 38 34 51 56 38 58 40 53 46 48 34 38 43 49 49 58 56 41 43 44 34 38 48 36",
"output": "3"
},
{
"input": "69\n70 48 49 48 49 71 48 53 55 69 48 53 54 58 53 63 48 48 69 67 72 75 71 75 74 74 57 63 65 60 48 48 65 48 48 51 50 49 62 53 76 68 76 56 76 76 64 76 76 57 61 76 73 51 59 76 65 50 69 50 76 67 76 63 62 74 74 58 73",
"output": "73"
},
{
"input": "75\n70 65 64 71 71 64 71 64 68 71 65 64 65 68 71 66 66 69 68 63 69 65 71 69 68 68 71 67 71 65 65 65 71 71 65 69 63 66 62 67 64 63 62 64 67 65 62 69 62 64 69 62 67 64 67 70 64 63 64 64 69 62 62 64 70 62 62 68 67 69 62 64 66 70 68",
"output": "7"
},
{
"input": "84\n92 95 84 85 94 80 90 86 80 92 95 84 86 83 86 83 93 91 95 92 84 88 82 84 84 84 80 94 93 80 94 80 95 83 85 80 95 95 80 84 86 92 83 81 90 87 81 89 92 93 80 87 90 85 93 85 93 94 93 89 94 83 93 91 80 83 90 94 95 80 95 92 85 84 93 94 94 82 91 95 95 89 85 94",
"output": "15"
},
{
"input": "90\n86 87 72 77 82 71 75 78 61 67 79 90 64 94 94 74 85 87 73 76 71 71 60 69 77 73 76 80 82 57 62 57 57 83 76 72 75 87 72 94 77 85 59 82 86 69 62 80 95 73 83 94 79 85 91 68 85 74 93 95 68 75 89 93 83 78 95 78 83 77 81 85 66 92 63 65 75 78 67 91 77 74 59 86 77 76 90 67 70 64",
"output": "104"
},
{
"input": "91\n94 98 96 94 95 98 98 95 98 94 94 98 95 95 99 97 97 94 95 98 94 98 96 98 96 98 97 95 94 94 94 97 94 96 98 98 98 94 96 95 94 95 97 97 97 98 94 98 96 95 98 96 96 98 94 97 96 98 97 95 97 98 94 95 94 94 97 94 96 97 97 93 94 95 95 94 96 98 97 96 94 98 98 96 96 96 96 96 94 96 97",
"output": "33"
},
{
"input": "92\n44 28 32 29 41 41 36 39 40 39 41 35 41 28 35 27 41 34 28 38 43 43 41 38 27 26 28 36 30 29 39 32 35 35 32 30 39 30 37 27 41 41 28 30 43 31 35 33 36 28 44 40 41 35 31 42 37 38 37 34 39 40 27 40 33 33 44 43 34 33 34 34 35 38 38 37 30 39 35 41 45 42 41 32 33 33 31 30 43 41 43 43",
"output": "145"
},
{
"input": "93\n46 32 52 36 39 30 57 63 63 30 32 44 27 59 46 38 40 45 44 62 35 36 51 48 39 58 36 51 51 51 48 58 59 36 29 35 31 49 64 60 34 38 42 56 33 42 52 31 63 34 45 51 35 45 33 53 33 62 31 38 66 29 51 54 28 61 32 45 57 41 36 34 47 36 31 28 67 48 52 46 32 40 64 58 27 53 43 57 34 66 43 39 26",
"output": "76"
},
{
"input": "94\n56 55 54 31 32 42 46 29 24 54 40 40 20 45 35 56 32 33 51 39 26 56 21 56 51 27 29 39 56 52 54 43 43 55 48 51 44 49 52 49 23 19 19 28 20 26 45 33 35 51 42 36 25 25 38 23 21 35 54 50 41 20 37 28 42 20 22 43 37 34 55 21 24 38 19 41 45 34 19 33 44 54 38 31 23 53 35 32 47 40 39 31 20 34",
"output": "15"
},
{
"input": "95\n57 71 70 77 64 64 76 81 81 58 63 75 81 77 71 71 71 60 70 70 69 67 62 64 78 64 69 62 76 76 57 70 68 77 70 68 73 77 79 73 60 57 69 60 74 65 58 75 75 74 73 73 65 75 72 57 81 62 62 70 67 58 76 57 79 81 68 64 58 77 70 59 79 64 80 58 71 59 81 71 80 64 78 80 78 65 70 68 78 80 57 63 64 76 81",
"output": "11"
},
{
"input": "96\n96 95 95 95 96 97 95 97 96 95 98 96 97 95 98 96 98 96 98 96 98 95 96 95 95 95 97 97 95 95 98 98 95 96 96 95 97 96 98 96 95 97 97 95 97 97 95 94 96 96 97 96 97 97 96 94 94 97 95 95 95 96 95 96 95 97 97 95 97 96 95 94 97 97 97 96 97 95 96 94 94 95 97 94 94 97 97 97 95 97 97 95 94 96 95 95",
"output": "13"
},
{
"input": "97\n14 15 12 12 13 15 12 15 12 12 12 12 12 14 15 15 13 12 15 15 12 12 12 13 14 15 15 13 14 15 14 14 14 14 12 13 12 13 13 12 15 12 13 13 15 12 15 13 12 13 13 13 14 13 12 15 14 13 14 15 13 14 14 13 14 12 15 12 14 12 13 14 15 14 13 15 13 12 15 15 15 13 15 15 13 14 16 16 16 13 15 13 15 14 15 15 15",
"output": "104"
},
{
"input": "98\n37 69 35 70 58 69 36 47 41 63 60 54 49 35 55 50 35 53 52 43 35 41 40 49 38 35 48 70 42 35 35 65 56 54 44 59 59 48 51 49 59 67 35 60 69 35 58 50 35 44 48 69 41 58 44 45 35 47 70 61 49 47 37 39 35 51 44 70 72 65 36 41 63 63 48 66 45 50 50 71 37 52 72 67 72 39 72 39 36 64 48 72 69 49 45 72 72 67",
"output": "100"
},
{
"input": "99\n31 31 16 15 19 31 19 22 29 27 12 22 28 30 25 33 26 25 19 22 34 21 17 33 31 22 16 26 22 30 31 17 13 33 13 17 28 25 18 33 27 22 31 22 13 27 20 22 23 15 24 32 29 13 16 20 32 33 14 33 19 27 16 28 25 17 17 28 18 26 32 33 19 23 30 13 14 23 24 28 14 28 22 20 30 14 24 23 17 29 18 28 29 21 28 18 16 24 32",
"output": "107"
},
{
"input": "100\n37 54 39 29 32 49 21 13 34 21 16 42 34 27 16 26 7 34 51 9 11 27 16 40 36 7 48 52 30 42 42 52 51 11 32 26 6 7 28 54 48 51 6 54 42 20 51 48 46 4 4 31 47 6 9 16 8 23 36 50 49 30 47 37 45 24 48 26 8 50 18 24 27 13 39 7 37 34 5 43 42 19 34 23 52 38 35 6 29 11 53 49 21 29 36 22 45 33 51 22",
"output": "50"
},
{
"input": "100\n41 5 20 23 5 47 28 28 64 5 12 14 34 56 22 48 6 52 39 55 62 40 24 54 39 28 56 27 35 51 14 24 38 10 55 20 39 62 52 2 30 55 49 48 15 23 59 44 31 28 66 29 62 59 31 13 28 12 50 45 41 47 29 27 64 66 14 39 62 22 44 63 24 5 63 17 42 7 25 41 49 33 31 51 63 3 37 66 19 9 2 40 16 45 56 21 34 29 39 61",
"output": "59"
},
{
"input": "100\n66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 66 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95 95",
"output": "99"
},
{
"input": "100\n81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 81 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10",
"output": "0"
},
{
"input": "3\n2 1 2",
"output": "1"
},
{
"input": "2\n100 99",
"output": "0"
},
{
"input": "100\n1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100",
"output": "197"
},
{
"input": "100\n87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87 87",
"output": "0"
},
{
"input": "100\n100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1",
"output": "0"
},
{
"input": "2\n1 1",
"output": "0"
},
{
"input": "3\n2 2 2",
"output": "0"
},
{
"input": "3\n1 3 2",
"output": "2"
}
] | 1,697,969,543
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 1
| 92
| 0
|
# Read the number of soldiers
n = int(input())
# Read the heights of the soldiers
heights = list(map(int, input().split()))
# Initialize variables to count the number of soldiers out of position
out_of_position_start = 0
out_of_position_end = 0
# Initialize variables to keep track of the expected heights for the first and last soldiers
expected_start_height = heights[0]
expected_end_height = heights[-1]
# Count the number of soldiers out of position at the start of the lineup
for i in range(n):
if heights[i] != expected_start_height:
break
out_of_position_start += 1
# Count the number of soldiers out of position at the end of the lineup
for i in range(n - 1, -1, -1):
if heights[i] != expected_end_height:
break
out_of_position_end += 1
# Calculate the minimum number of seconds needed to form a correct lineup
min_seconds = max(0, n - (out_of_position_start + out_of_position_end))
print(min_seconds)
|
Title: Arrival of the General
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A Ministry for Defense sent a general to inspect the Super Secret Military Squad under the command of the Colonel SuperDuper. Having learned the news, the colonel ordered to all *n* squad soldiers to line up on the parade ground.
By the military charter the soldiers should stand in the order of non-increasing of their height. But as there's virtually no time to do that, the soldiers lined up in the arbitrary order. However, the general is rather short-sighted and he thinks that the soldiers lined up correctly if the first soldier in the line has the maximum height and the last soldier has the minimum height. Please note that the way other solders are positioned does not matter, including the case when there are several soldiers whose height is maximum or minimum. Only the heights of the first and the last soldier are important.
For example, the general considers the sequence of heights (4, 3, 4, 2, 1, 1) correct and the sequence (4, 3, 1, 2, 2) wrong.
Within one second the colonel can swap any two neighboring soldiers. Help him count the minimum time needed to form a line-up which the general will consider correct.
Input Specification:
The first input line contains the only integer *n* (2<=≤<=*n*<=≤<=100) which represents the number of soldiers in the line. The second line contains integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100) the values of the soldiers' heights in the order of soldiers' heights' increasing in the order from the beginning of the line to its end. The numbers are space-separated. Numbers *a*1,<=*a*2,<=...,<=*a**n* are not necessarily different.
Output Specification:
Print the only integer — the minimum number of seconds the colonel will need to form a line-up the general will like.
Demo Input:
['4\n33 44 11 22\n', '7\n10 10 58 31 63 40 76\n']
Demo Output:
['2\n', '10\n']
Note:
In the first sample the colonel will need to swap the first and second soldier and then the third and fourth soldier. That will take 2 seconds. The resulting position of the soldiers is (44, 33, 22, 11).
In the second sample the colonel may swap the soldiers in the following sequence:
1. (10, 10, 58, 31, 63, 40, 76) 1. (10, 58, 10, 31, 63, 40, 76) 1. (10, 58, 10, 31, 63, 76, 40) 1. (10, 58, 10, 31, 76, 63, 40) 1. (10, 58, 31, 10, 76, 63, 40) 1. (10, 58, 31, 76, 10, 63, 40) 1. (10, 58, 31, 76, 63, 10, 40) 1. (10, 58, 76, 31, 63, 10, 40) 1. (10, 76, 58, 31, 63, 10, 40) 1. (76, 10, 58, 31, 63, 10, 40) 1. (76, 10, 58, 31, 63, 40, 10)
|
```python
# Read the number of soldiers
n = int(input())
# Read the heights of the soldiers
heights = list(map(int, input().split()))
# Initialize variables to count the number of soldiers out of position
out_of_position_start = 0
out_of_position_end = 0
# Initialize variables to keep track of the expected heights for the first and last soldiers
expected_start_height = heights[0]
expected_end_height = heights[-1]
# Count the number of soldiers out of position at the start of the lineup
for i in range(n):
if heights[i] != expected_start_height:
break
out_of_position_start += 1
# Count the number of soldiers out of position at the end of the lineup
for i in range(n - 1, -1, -1):
if heights[i] != expected_end_height:
break
out_of_position_end += 1
# Calculate the minimum number of seconds needed to form a correct lineup
min_seconds = max(0, n - (out_of_position_start + out_of_position_end))
print(min_seconds)
```
| 0
|
|
862
|
A
|
Mahmoud and Ehab and the MEX
|
PROGRAMMING
| 1,000
|
[
"greedy",
"implementation"
] | null | null |
Dr. Evil kidnapped Mahmoud and Ehab in the evil land because of their performance in the Evil Olympiad in Informatics (EOI). He decided to give them some problems to let them go.
Dr. Evil is interested in sets, He has a set of *n* integers. Dr. Evil calls a set of integers evil if the MEX of it is exactly *x*. the MEX of a set of integers is the minimum non-negative integer that doesn't exist in it. For example, the MEX of the set {0,<=2,<=4} is 1 and the MEX of the set {1,<=2,<=3} is 0 .
Dr. Evil is going to make his set evil. To do this he can perform some operations. During each operation he can add some non-negative integer to his set or erase some element from it. What is the minimal number of operations Dr. Evil has to perform to make his set evil?
|
The first line contains two integers *n* and *x* (1<=≤<=*n*<=≤<=100, 0<=≤<=*x*<=≤<=100) — the size of the set Dr. Evil owns, and the desired MEX.
The second line contains *n* distinct non-negative integers not exceeding 100 that represent the set.
|
The only line should contain one integer — the minimal number of operations Dr. Evil should perform.
|
[
"5 3\n0 4 5 6 7\n",
"1 0\n0\n",
"5 0\n1 2 3 4 5\n"
] |
[
"2\n",
"1\n",
"0\n"
] |
For the first test case Dr. Evil should add 1 and 2 to the set performing 2 operations.
For the second test case Dr. Evil should erase 0 from the set. After that, the set becomes empty, so the MEX of it is 0.
In the third test case the set is already evil.
| 500
|
[
{
"input": "5 3\n0 4 5 6 7",
"output": "2"
},
{
"input": "1 0\n0",
"output": "1"
},
{
"input": "5 0\n1 2 3 4 5",
"output": "0"
},
{
"input": "10 5\n57 1 47 9 93 37 76 70 78 15",
"output": "4"
},
{
"input": "10 5\n99 98 93 97 95 100 92 94 91 96",
"output": "5"
},
{
"input": "10 5\n1 2 3 4 59 45 0 58 51 91",
"output": "0"
},
{
"input": "100 100\n79 13 21 11 3 87 28 40 29 4 96 34 8 78 61 46 33 45 99 30 92 67 22 97 39 86 73 31 74 44 62 55 57 2 54 63 80 69 25 48 77 98 17 93 15 16 89 12 43 23 37 95 14 38 83 90 49 56 72 10 20 0 50 71 70 88 19 1 76 81 52 41 82 68 85 47 6 7 35 60 18 64 75 84 27 9 65 91 94 42 53 24 66 26 59 36 51 32 5 58",
"output": "0"
},
{
"input": "100 50\n95 78 46 92 80 18 79 58 30 72 19 89 39 29 44 65 15 100 59 8 96 9 62 67 41 42 82 14 57 32 71 77 40 5 7 51 28 53 85 23 16 35 3 91 6 11 75 61 17 66 13 47 36 56 10 22 83 60 48 24 26 97 4 33 76 86 70 0 34 64 52 43 21 49 55 74 1 73 81 25 54 63 94 84 20 68 87 12 31 88 38 93 37 90 98 69 99 45 27 2",
"output": "0"
},
{
"input": "100 33\n28 11 79 92 88 62 77 72 7 41 96 97 67 84 44 8 81 35 38 1 64 68 46 17 98 83 31 12 74 21 2 22 47 6 36 75 65 61 37 26 25 45 59 48 100 51 93 76 78 49 3 57 16 4 87 29 55 82 70 39 53 0 60 15 24 71 58 20 66 89 95 42 13 43 63 90 85 52 50 30 54 40 56 23 27 34 32 18 10 19 69 9 99 73 91 14 5 80 94 86",
"output": "0"
},
{
"input": "99 33\n25 76 41 95 55 20 47 59 58 84 87 92 16 27 35 65 72 63 93 54 36 96 15 86 5 69 24 46 67 73 48 60 40 6 61 74 97 10 100 8 52 26 77 18 7 62 37 2 14 66 11 56 68 91 0 64 75 99 30 21 53 1 89 81 3 98 12 88 39 38 29 83 22 90 9 28 45 43 78 44 32 57 4 50 70 17 13 51 80 85 71 94 82 19 34 42 23 79 49",
"output": "1"
},
{
"input": "100 100\n65 56 84 46 44 33 99 74 62 72 93 67 43 92 75 88 38 34 66 12 55 76 58 90 78 8 14 45 97 59 48 32 64 18 39 89 31 51 54 81 29 36 70 77 40 22 49 27 3 1 73 13 98 42 87 37 2 57 4 6 50 25 23 79 28 86 68 61 80 17 19 10 15 63 52 11 35 60 21 16 24 85 30 91 7 5 69 20 71 82 53 94 41 95 96 9 26 83 0 47",
"output": "0"
},
{
"input": "100 100\n58 88 12 71 22 1 40 19 73 20 67 48 57 17 69 36 100 35 33 37 72 55 52 8 89 85 47 42 78 70 81 86 11 9 68 99 6 16 21 61 53 98 23 62 32 59 51 0 87 24 50 30 65 10 80 95 7 92 25 74 60 79 91 5 13 31 75 38 90 94 46 66 93 34 14 41 28 2 76 84 43 96 3 56 49 82 27 77 64 63 4 45 18 29 54 39 15 26 83 44",
"output": "2"
},
{
"input": "89 100\n58 96 17 41 86 34 28 84 18 40 8 77 87 89 68 79 33 35 53 49 0 6 22 12 72 90 48 55 21 50 56 62 75 2 37 95 69 74 14 20 44 46 27 32 31 59 63 60 10 85 71 70 38 52 94 30 61 51 80 26 36 23 39 47 76 45 100 57 15 78 97 66 54 13 99 16 93 73 24 4 83 5 98 81 92 25 29 88 65",
"output": "13"
},
{
"input": "100 50\n7 95 24 76 81 78 60 69 83 84 100 1 65 31 48 92 73 39 18 89 38 97 10 42 8 55 98 51 21 90 62 77 16 91 0 94 4 37 19 17 67 35 45 41 56 20 15 85 75 28 59 27 12 54 61 68 36 5 79 93 66 11 70 49 50 34 30 25 96 46 64 14 32 22 47 40 58 23 43 9 87 82 26 53 80 52 3 86 13 99 33 71 6 88 57 74 2 44 72 63",
"output": "2"
},
{
"input": "77 0\n27 8 20 92 21 41 53 98 17 65 67 35 81 11 55 49 61 44 2 66 51 89 40 28 52 62 86 91 64 24 18 5 94 82 96 99 71 6 39 83 26 29 16 30 45 97 80 90 69 12 13 33 76 73 46 19 78 56 88 38 42 34 57 77 47 4 59 58 7 100 95 72 9 74 15 43 54",
"output": "0"
},
{
"input": "100 50\n55 36 0 32 81 6 17 43 24 13 30 19 8 59 71 45 15 74 3 41 99 42 86 47 2 94 35 1 66 95 38 49 4 27 96 89 34 44 92 25 51 39 54 28 80 77 20 14 48 40 68 56 31 63 33 78 69 37 18 26 83 70 23 82 91 65 67 52 61 53 7 22 60 21 12 73 72 87 75 100 90 29 64 79 98 85 5 62 93 84 50 46 97 58 57 16 9 10 76 11",
"output": "1"
},
{
"input": "77 0\n12 8 19 87 9 54 55 86 97 7 27 85 25 48 94 73 26 1 13 57 72 69 76 39 38 91 75 40 42 28 93 21 70 84 65 11 60 90 20 95 66 89 59 47 34 99 6 61 52 100 50 3 77 81 82 53 15 24 0 45 44 14 68 96 58 5 18 35 10 98 29 74 92 49 83 71 17",
"output": "1"
},
{
"input": "100 70\n25 94 66 65 10 99 89 6 70 31 7 40 20 92 64 27 21 72 77 98 17 43 47 44 48 81 38 56 100 39 90 22 88 76 3 83 86 29 33 55 82 79 49 11 2 16 12 78 85 69 32 97 26 15 53 24 23 91 51 67 34 35 52 5 62 50 95 18 71 13 75 8 30 42 93 36 45 60 63 46 57 41 87 0 84 54 74 37 4 58 28 19 96 61 80 9 1 14 73 68",
"output": "2"
},
{
"input": "89 19\n14 77 85 81 79 38 91 45 55 51 50 11 62 67 73 76 2 27 16 23 3 29 65 98 78 17 4 58 22 20 34 66 64 31 72 5 32 44 12 75 80 47 18 25 99 0 61 56 71 84 48 88 10 7 86 8 49 24 43 21 37 28 33 54 46 57 40 89 36 97 6 96 39 95 26 74 1 69 9 100 52 30 83 87 68 60 92 90 35",
"output": "2"
},
{
"input": "89 100\n69 61 56 45 11 41 42 32 28 29 0 76 7 65 13 35 36 82 10 39 26 34 38 40 92 12 17 54 24 46 88 70 66 27 100 52 85 62 22 48 86 68 21 49 53 94 67 20 1 90 77 84 31 87 58 47 95 33 4 72 93 83 8 51 91 80 99 43 71 19 44 59 98 97 64 9 81 16 79 63 25 37 3 75 2 55 50 6 18",
"output": "13"
},
{
"input": "77 0\n38 76 24 74 42 88 29 75 96 46 90 32 59 97 98 60 41 57 80 37 100 49 25 63 95 31 61 68 53 78 27 66 84 48 94 83 30 26 36 99 71 62 45 47 70 28 35 54 34 85 79 43 91 72 86 33 67 92 77 65 69 52 82 55 87 64 56 40 50 44 51 73 89 81 58 93 39",
"output": "0"
},
{
"input": "89 100\n38 90 80 64 35 44 56 11 15 89 23 12 49 70 72 60 63 85 92 10 45 83 8 88 41 33 16 6 61 76 62 71 87 13 25 77 74 0 1 37 96 93 7 94 21 82 34 78 4 73 65 20 81 95 50 32 48 17 69 55 68 5 51 27 53 43 91 67 59 46 86 84 99 24 22 3 97 98 40 36 26 58 57 9 42 30 52 2 47",
"output": "11"
},
{
"input": "77 0\n55 71 78 86 68 35 53 10 59 32 81 19 74 97 62 61 93 87 96 44 25 18 43 82 84 16 34 48 92 39 64 36 49 91 45 76 95 31 57 29 75 79 13 2 14 24 52 23 33 20 47 99 63 15 5 80 58 67 12 3 85 6 1 27 73 90 4 42 37 70 8 11 89 77 9 22 94",
"output": "0"
},
{
"input": "77 0\n12 75 31 71 44 8 3 82 21 77 50 29 57 74 40 10 15 42 84 2 100 9 28 72 92 0 49 11 90 55 17 36 19 54 68 52 4 69 97 91 5 39 59 45 89 62 53 83 16 94 76 60 95 47 30 51 7 48 20 70 67 32 58 78 63 34 56 93 99 88 24 1 66 22 25 14 13",
"output": "1"
},
{
"input": "100 70\n91 82 8 85 26 25 95 97 40 87 81 93 7 73 38 94 64 96 74 18 90 19 65 68 72 61 23 43 36 41 60 88 30 33 71 24 52 39 15 3 16 89 86 79 55 4 9 58 67 44 46 29 6 48 84 69 27 21 78 54 51 57 80 53 76 50 47 77 45 12 34 10 100 0 17 31 56 99 98 11 92 5 2 42 32 59 66 62 37 63 28 75 35 1 22 13 83 49 20 14",
"output": "0"
},
{
"input": "77 0\n51 5 81 62 30 22 11 0 83 16 79 85 52 70 69 10 8 47 58 3 24 34 44 14 82 66 99 17 28 31 64 67 23 49 94 45 4 12 27 15 21 6 43 72 87 2 63 92 35 39 59 9 90 78 93 20 65 36 60 89 50 41 61 84 77 86 76 100 38 68 53 97 96 95 7 19 88",
"output": "1"
},
{
"input": "1 100\n0",
"output": "99"
},
{
"input": "1 0\n100",
"output": "0"
},
{
"input": "1 100\n100",
"output": "101"
},
{
"input": "2 100\n0 100",
"output": "100"
},
{
"input": "5 5\n1 2 3 4 5",
"output": "2"
},
{
"input": "5 3\n0 3 4 5 6",
"output": "3"
},
{
"input": "7 10\n0 1 2 3 4 5 10",
"output": "5"
},
{
"input": "2 2\n0 2",
"output": "2"
},
{
"input": "2 1\n1 2",
"output": "2"
},
{
"input": "5 1\n1 2 3 4 5",
"output": "2"
},
{
"input": "5 2\n1 2 3 4 5",
"output": "2"
},
{
"input": "5 6\n0 1 2 3 4",
"output": "1"
},
{
"input": "3 2\n3 4 5",
"output": "2"
}
] | 1,630,861,664
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 4
| 61
| 6,963,200
|
a,mex=map(int,input().split())
c=list(map(int,input().split()))
c=sorted(c)
l=0
i=0
for j in range(a):
if c[j]!=i:
while i+1<mex and c[j]!=i:
l+=1
i+=1
elif c[j]==mex:
l+=1
print(l)
|
Title: Mahmoud and Ehab and the MEX
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Dr. Evil kidnapped Mahmoud and Ehab in the evil land because of their performance in the Evil Olympiad in Informatics (EOI). He decided to give them some problems to let them go.
Dr. Evil is interested in sets, He has a set of *n* integers. Dr. Evil calls a set of integers evil if the MEX of it is exactly *x*. the MEX of a set of integers is the minimum non-negative integer that doesn't exist in it. For example, the MEX of the set {0,<=2,<=4} is 1 and the MEX of the set {1,<=2,<=3} is 0 .
Dr. Evil is going to make his set evil. To do this he can perform some operations. During each operation he can add some non-negative integer to his set or erase some element from it. What is the minimal number of operations Dr. Evil has to perform to make his set evil?
Input Specification:
The first line contains two integers *n* and *x* (1<=≤<=*n*<=≤<=100, 0<=≤<=*x*<=≤<=100) — the size of the set Dr. Evil owns, and the desired MEX.
The second line contains *n* distinct non-negative integers not exceeding 100 that represent the set.
Output Specification:
The only line should contain one integer — the minimal number of operations Dr. Evil should perform.
Demo Input:
['5 3\n0 4 5 6 7\n', '1 0\n0\n', '5 0\n1 2 3 4 5\n']
Demo Output:
['2\n', '1\n', '0\n']
Note:
For the first test case Dr. Evil should add 1 and 2 to the set performing 2 operations.
For the second test case Dr. Evil should erase 0 from the set. After that, the set becomes empty, so the MEX of it is 0.
In the third test case the set is already evil.
|
```python
a,mex=map(int,input().split())
c=list(map(int,input().split()))
c=sorted(c)
l=0
i=0
for j in range(a):
if c[j]!=i:
while i+1<mex and c[j]!=i:
l+=1
i+=1
elif c[j]==mex:
l+=1
print(l)
```
| 0
|
|
996
|
A
|
Hit the Lottery
|
PROGRAMMING
| 800
|
[
"dp",
"greedy"
] | null | null |
Allen has a LOT of money. He has $n$ dollars in the bank. For security reasons, he wants to withdraw it in cash (we will not disclose the reasons here). The denominations for dollar bills are $1$, $5$, $10$, $20$, $100$. What is the minimum number of bills Allen could receive after withdrawing his entire balance?
|
The first and only line of input contains a single integer $n$ ($1 \le n \le 10^9$).
|
Output the minimum number of bills that Allen could receive.
|
[
"125\n",
"43\n",
"1000000000\n"
] |
[
"3\n",
"5\n",
"10000000\n"
] |
In the first sample case, Allen can withdraw this with a $100$ dollar bill, a $20$ dollar bill, and a $5$ dollar bill. There is no way for Allen to receive $125$ dollars in one or two bills.
In the second sample case, Allen can withdraw two $20$ dollar bills and three $1$ dollar bills.
In the third sample case, Allen can withdraw $100000000$ (ten million!) $100$ dollar bills.
| 500
|
[
{
"input": "125",
"output": "3"
},
{
"input": "43",
"output": "5"
},
{
"input": "1000000000",
"output": "10000000"
},
{
"input": "4",
"output": "4"
},
{
"input": "5",
"output": "1"
},
{
"input": "1",
"output": "1"
},
{
"input": "74",
"output": "8"
},
{
"input": "31",
"output": "3"
},
{
"input": "59",
"output": "8"
},
{
"input": "79",
"output": "9"
},
{
"input": "7",
"output": "3"
},
{
"input": "55",
"output": "4"
},
{
"input": "40",
"output": "2"
},
{
"input": "719",
"output": "13"
},
{
"input": "847",
"output": "13"
},
{
"input": "225",
"output": "4"
},
{
"input": "4704",
"output": "51"
},
{
"input": "1132",
"output": "15"
},
{
"input": "7811",
"output": "80"
},
{
"input": "7981",
"output": "84"
},
{
"input": "82655",
"output": "830"
},
{
"input": "6364",
"output": "70"
},
{
"input": "74611",
"output": "748"
},
{
"input": "45391",
"output": "459"
},
{
"input": "620448",
"output": "6210"
},
{
"input": "265145",
"output": "2654"
},
{
"input": "671704",
"output": "6721"
},
{
"input": "365173",
"output": "3658"
},
{
"input": "7130872",
"output": "71314"
},
{
"input": "9628747",
"output": "96292"
},
{
"input": "8898399",
"output": "88993"
},
{
"input": "9497953",
"output": "94985"
},
{
"input": "19070947",
"output": "190714"
},
{
"input": "20185520",
"output": "201856"
},
{
"input": "91402248",
"output": "914028"
},
{
"input": "27035533",
"output": "270360"
},
{
"input": "22717528",
"output": "227180"
},
{
"input": "24403439",
"output": "244041"
},
{
"input": "163565555",
"output": "1635659"
},
{
"input": "152541908",
"output": "1525423"
},
{
"input": "668439837",
"output": "6684403"
},
{
"input": "20",
"output": "1"
},
{
"input": "999999999",
"output": "10000009"
},
{
"input": "10",
"output": "1"
},
{
"input": "7",
"output": "3"
},
{
"input": "6",
"output": "2"
},
{
"input": "99999999",
"output": "1000009"
},
{
"input": "1000001",
"output": "10001"
},
{
"input": "2521",
"output": "27"
}
] | 1,699,534,617
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 2
| 1,000
| 0
|
n=int(input())
ans=0
while(n>=100):
n-=100
ans+=1
while(n>=20):
n-=20
ans+=1
while(n>=10):
n-=10
ans+=1
while(n>=5):
n-=5
ans+=1
print(ans+n)
|
Title: Hit the Lottery
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Allen has a LOT of money. He has $n$ dollars in the bank. For security reasons, he wants to withdraw it in cash (we will not disclose the reasons here). The denominations for dollar bills are $1$, $5$, $10$, $20$, $100$. What is the minimum number of bills Allen could receive after withdrawing his entire balance?
Input Specification:
The first and only line of input contains a single integer $n$ ($1 \le n \le 10^9$).
Output Specification:
Output the minimum number of bills that Allen could receive.
Demo Input:
['125\n', '43\n', '1000000000\n']
Demo Output:
['3\n', '5\n', '10000000\n']
Note:
In the first sample case, Allen can withdraw this with a $100$ dollar bill, a $20$ dollar bill, and a $5$ dollar bill. There is no way for Allen to receive $125$ dollars in one or two bills.
In the second sample case, Allen can withdraw two $20$ dollar bills and three $1$ dollar bills.
In the third sample case, Allen can withdraw $100000000$ (ten million!) $100$ dollar bills.
|
```python
n=int(input())
ans=0
while(n>=100):
n-=100
ans+=1
while(n>=20):
n-=20
ans+=1
while(n>=10):
n-=10
ans+=1
while(n>=5):
n-=5
ans+=1
print(ans+n)
```
| 0
|
|
981
|
A
|
Antipalindrome
|
PROGRAMMING
| 900
|
[
"brute force",
"implementation",
"strings"
] | null | null |
A string is a palindrome if it reads the same from the left to the right and from the right to the left. For example, the strings "kek", "abacaba", "r" and "papicipap" are palindromes, while the strings "abb" and "iq" are not.
A substring $s[l \ldots r]$ ($1<=\leq<=l<=\leq<=r<=\leq<=|s|$) of a string $s<==<=s_{1}s_{2} \ldots s_{|s|}$ is the string $s_{l}s_{l<=+<=1} \ldots s_{r}$.
Anna does not like palindromes, so she makes her friends call her Ann. She also changes all the words she reads in a similar way. Namely, each word $s$ is changed into its longest substring that is not a palindrome. If all the substrings of $s$ are palindromes, she skips the word at all.
Some time ago Ann read the word $s$. What is the word she changed it into?
|
The first line contains a non-empty string $s$ with length at most $50$ characters, containing lowercase English letters only.
|
If there is such a substring in $s$ that is not a palindrome, print the maximum length of such a substring. Otherwise print $0$.
Note that there can be multiple longest substrings that are not palindromes, but their length is unique.
|
[
"mew\n",
"wuffuw\n",
"qqqqqqqq\n"
] |
[
"3\n",
"5\n",
"0\n"
] |
"mew" is not a palindrome, so the longest substring of it that is not a palindrome, is the string "mew" itself. Thus, the answer for the first example is $3$.
The string "uffuw" is one of the longest non-palindrome substrings (of length $5$) of the string "wuffuw", so the answer for the second example is $5$.
All substrings of the string "qqqqqqqq" consist of equal characters so they are palindromes. This way, there are no non-palindrome substrings. Thus, the answer for the third example is $0$.
| 500
|
[
{
"input": "mew",
"output": "3"
},
{
"input": "wuffuw",
"output": "5"
},
{
"input": "qqqqqqqq",
"output": "0"
},
{
"input": "ijvji",
"output": "4"
},
{
"input": "iiiiiii",
"output": "0"
},
{
"input": "wobervhvvkihcuyjtmqhaaigvvgiaahqmtjyuchikvvhvrebow",
"output": "49"
},
{
"input": "wwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwww",
"output": "0"
},
{
"input": "wobervhvvkihcuyjtmqhaaigvahheoqleromusrartldojsjvy",
"output": "50"
},
{
"input": "ijvxljt",
"output": "7"
},
{
"input": "fyhcncnchyf",
"output": "10"
},
{
"input": "ffffffffffff",
"output": "0"
},
{
"input": "fyhcncfsepqj",
"output": "12"
},
{
"input": "ybejrrlbcinttnicblrrjeby",
"output": "23"
},
{
"input": "yyyyyyyyyyyyyyyyyyyyyyyyy",
"output": "0"
},
{
"input": "ybejrrlbcintahovgjddrqatv",
"output": "25"
},
{
"input": "oftmhcmclgyqaojljoaqyglcmchmtfo",
"output": "30"
},
{
"input": "oooooooooooooooooooooooooooooooo",
"output": "0"
},
{
"input": "oftmhcmclgyqaojllbotztajglsmcilv",
"output": "32"
},
{
"input": "gxandbtgpbknxvnkjaajknvxnkbpgtbdnaxg",
"output": "35"
},
{
"input": "gggggggggggggggggggggggggggggggggggg",
"output": "0"
},
{
"input": "gxandbtgpbknxvnkjaygommzqitqzjfalfkk",
"output": "36"
},
{
"input": "fcliblymyqckxvieotjooojtoeivxkcqymylbilcf",
"output": "40"
},
{
"input": "fffffffffffffffffffffffffffffffffffffffffff",
"output": "0"
},
{
"input": "fcliblymyqckxvieotjootiqwtyznhhvuhbaixwqnsy",
"output": "43"
},
{
"input": "rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr",
"output": "0"
},
{
"input": "rajccqwqnqmshmerpvjyfepxwpxyldzpzhctqjnstxyfmlhiy",
"output": "49"
},
{
"input": "a",
"output": "0"
},
{
"input": "abca",
"output": "4"
},
{
"input": "aaaaabaaaaa",
"output": "10"
},
{
"input": "aba",
"output": "2"
},
{
"input": "asaa",
"output": "4"
},
{
"input": "aabaa",
"output": "4"
},
{
"input": "aabbaa",
"output": "5"
},
{
"input": "abcdaaa",
"output": "7"
},
{
"input": "aaholaa",
"output": "7"
},
{
"input": "abcdefghijka",
"output": "12"
},
{
"input": "aaadcba",
"output": "7"
},
{
"input": "aaaabaaaa",
"output": "8"
},
{
"input": "abaa",
"output": "4"
},
{
"input": "abcbaa",
"output": "6"
},
{
"input": "ab",
"output": "2"
},
{
"input": "l",
"output": "0"
},
{
"input": "aaaabcaaaa",
"output": "10"
},
{
"input": "abbaaaaaabba",
"output": "11"
},
{
"input": "abaaa",
"output": "5"
},
{
"input": "baa",
"output": "3"
},
{
"input": "aaaaaaabbba",
"output": "11"
},
{
"input": "ccbcc",
"output": "4"
},
{
"input": "bbbaaab",
"output": "7"
},
{
"input": "abaaaaaaaa",
"output": "10"
},
{
"input": "abaaba",
"output": "5"
},
{
"input": "aabsdfaaaa",
"output": "10"
},
{
"input": "aaaba",
"output": "5"
},
{
"input": "aaabaaa",
"output": "6"
},
{
"input": "baaabbb",
"output": "7"
},
{
"input": "ccbbabbcc",
"output": "8"
},
{
"input": "cabc",
"output": "4"
},
{
"input": "aabcd",
"output": "5"
},
{
"input": "abcdea",
"output": "6"
},
{
"input": "bbabb",
"output": "4"
},
{
"input": "aaaaabababaaaaa",
"output": "14"
},
{
"input": "bbabbb",
"output": "6"
},
{
"input": "aababd",
"output": "6"
},
{
"input": "abaaaa",
"output": "6"
},
{
"input": "aaaaaaaabbba",
"output": "12"
},
{
"input": "aabca",
"output": "5"
},
{
"input": "aaabccbaaa",
"output": "9"
},
{
"input": "aaaaaaaaaaaaaaaaaaaab",
"output": "21"
},
{
"input": "babb",
"output": "4"
},
{
"input": "abcaa",
"output": "5"
},
{
"input": "qwqq",
"output": "4"
},
{
"input": "aaaaaaaaaaabbbbbbbbbbbbbbbaaaaaaaaaaaaaaaaaaaaaa",
"output": "48"
},
{
"input": "aaab",
"output": "4"
},
{
"input": "aaaaaabaaaaa",
"output": "12"
},
{
"input": "wwuww",
"output": "4"
},
{
"input": "aaaaabcbaaaaa",
"output": "12"
},
{
"input": "aaabbbaaa",
"output": "8"
},
{
"input": "aabcbaa",
"output": "6"
},
{
"input": "abccdefccba",
"output": "11"
},
{
"input": "aabbcbbaa",
"output": "8"
},
{
"input": "aaaabbaaaa",
"output": "9"
},
{
"input": "aabcda",
"output": "6"
},
{
"input": "abbca",
"output": "5"
},
{
"input": "aaaaaabbaaa",
"output": "11"
},
{
"input": "sssssspssssss",
"output": "12"
},
{
"input": "sdnmsdcs",
"output": "8"
},
{
"input": "aaabbbccbbbaaa",
"output": "13"
},
{
"input": "cbdbdc",
"output": "6"
},
{
"input": "abb",
"output": "3"
},
{
"input": "abcdefaaaa",
"output": "10"
},
{
"input": "abbbaaa",
"output": "7"
},
{
"input": "v",
"output": "0"
},
{
"input": "abccbba",
"output": "7"
},
{
"input": "axyza",
"output": "5"
},
{
"input": "abcdefgaaaa",
"output": "11"
},
{
"input": "aaabcdaaa",
"output": "9"
},
{
"input": "aaaacaaaa",
"output": "8"
},
{
"input": "aaaaaaaaaaaaaaaaaaaabaaaaaaaaaaaaaaaaaaaaa",
"output": "42"
},
{
"input": "abbbaa",
"output": "6"
},
{
"input": "abcdee",
"output": "6"
},
{
"input": "oom",
"output": "3"
},
{
"input": "aabcaa",
"output": "6"
},
{
"input": "abba",
"output": "3"
},
{
"input": "aaca",
"output": "4"
},
{
"input": "aacbca",
"output": "6"
},
{
"input": "ababa",
"output": "4"
},
{
"input": "abcda",
"output": "5"
},
{
"input": "cccaaccc",
"output": "7"
},
{
"input": "aaabcda",
"output": "7"
},
{
"input": "aa",
"output": "0"
},
{
"input": "aabaaaa",
"output": "7"
},
{
"input": "abbaaaa",
"output": "7"
},
{
"input": "aaabcbaaa",
"output": "8"
},
{
"input": "aabba",
"output": "5"
},
{
"input": "xyxx",
"output": "4"
},
{
"input": "aaaaaaaaaaaabc",
"output": "14"
},
{
"input": "bbaaaabb",
"output": "7"
},
{
"input": "aaabaa",
"output": "6"
},
{
"input": "sssssabsssss",
"output": "12"
},
{
"input": "bbbaaaabbb",
"output": "9"
},
{
"input": "abbbbaaaa",
"output": "9"
},
{
"input": "wwufuww",
"output": "6"
},
{
"input": "oowoo",
"output": "4"
},
{
"input": "cccaccc",
"output": "6"
},
{
"input": "aaa",
"output": "0"
},
{
"input": "bbbcc",
"output": "5"
},
{
"input": "abcdef",
"output": "6"
},
{
"input": "abbba",
"output": "4"
},
{
"input": "aab",
"output": "3"
},
{
"input": "aaba",
"output": "4"
},
{
"input": "azbyaaa",
"output": "7"
},
{
"input": "oooooiooooo",
"output": "10"
},
{
"input": "aabbbbbaaaaaa",
"output": "13"
}
] | 1,527,433,118
| 518
|
Python 3
|
COMPILATION_ERROR
|
PRETESTS
| 0
| 0
| 0
|
#include <iostream>
#include <cstring>
#include <algorithm>
#include <vector>
#include <string>
#include <cmath>
#include <queue>
#include <numeric>
#include <climits>
#include <utility>
std::vector<int> ReadVector(size_t size) {
std::vector<int> vector(size);
for (auto& element : vector) {
std::cin >> element;
}
return vector;
}
bool is_pal(const std::string& a) {
for (size_t i = 0; i < a.size() / 2; ++i) {
if (a[i] != a[a.size() - i - 1]) {
return false;
}
}
return true;
}
class Solver {
public:
int64_t INF;
Solver() {}
void read() {
}
void solve() {
std::string a;
std::cin >> a;
auto max = 0;
for (int i = 0; i < a.size(); ++i) {
for (int j = i + 1; j <= a.size(); ++j) {
if (!is_pal({a.begin() + i, a.begin() + j})) {
max = std::max(max, j - i);
}
}
}
std::cout << max << std::endl;
}
};
int main() {
std::ios_base::sync_with_stdio(false);
std::cin.tie(nullptr);
#ifdef SAW_AI
freopen("input", "r", stdin);
#endif
Solver solver;
solver.solve();
return 0;
}
|
Title: Antipalindrome
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A string is a palindrome if it reads the same from the left to the right and from the right to the left. For example, the strings "kek", "abacaba", "r" and "papicipap" are palindromes, while the strings "abb" and "iq" are not.
A substring $s[l \ldots r]$ ($1<=\leq<=l<=\leq<=r<=\leq<=|s|$) of a string $s<==<=s_{1}s_{2} \ldots s_{|s|}$ is the string $s_{l}s_{l<=+<=1} \ldots s_{r}$.
Anna does not like palindromes, so she makes her friends call her Ann. She also changes all the words she reads in a similar way. Namely, each word $s$ is changed into its longest substring that is not a palindrome. If all the substrings of $s$ are palindromes, she skips the word at all.
Some time ago Ann read the word $s$. What is the word she changed it into?
Input Specification:
The first line contains a non-empty string $s$ with length at most $50$ characters, containing lowercase English letters only.
Output Specification:
If there is such a substring in $s$ that is not a palindrome, print the maximum length of such a substring. Otherwise print $0$.
Note that there can be multiple longest substrings that are not palindromes, but their length is unique.
Demo Input:
['mew\n', 'wuffuw\n', 'qqqqqqqq\n']
Demo Output:
['3\n', '5\n', '0\n']
Note:
"mew" is not a palindrome, so the longest substring of it that is not a palindrome, is the string "mew" itself. Thus, the answer for the first example is $3$.
The string "uffuw" is one of the longest non-palindrome substrings (of length $5$) of the string "wuffuw", so the answer for the second example is $5$.
All substrings of the string "qqqqqqqq" consist of equal characters so they are palindromes. This way, there are no non-palindrome substrings. Thus, the answer for the third example is $0$.
|
```python
#include <iostream>
#include <cstring>
#include <algorithm>
#include <vector>
#include <string>
#include <cmath>
#include <queue>
#include <numeric>
#include <climits>
#include <utility>
std::vector<int> ReadVector(size_t size) {
std::vector<int> vector(size);
for (auto& element : vector) {
std::cin >> element;
}
return vector;
}
bool is_pal(const std::string& a) {
for (size_t i = 0; i < a.size() / 2; ++i) {
if (a[i] != a[a.size() - i - 1]) {
return false;
}
}
return true;
}
class Solver {
public:
int64_t INF;
Solver() {}
void read() {
}
void solve() {
std::string a;
std::cin >> a;
auto max = 0;
for (int i = 0; i < a.size(); ++i) {
for (int j = i + 1; j <= a.size(); ++j) {
if (!is_pal({a.begin() + i, a.begin() + j})) {
max = std::max(max, j - i);
}
}
}
std::cout << max << std::endl;
}
};
int main() {
std::ios_base::sync_with_stdio(false);
std::cin.tie(nullptr);
#ifdef SAW_AI
freopen("input", "r", stdin);
#endif
Solver solver;
solver.solve();
return 0;
}
```
| -1
|
|
3
|
A
|
Shortest path of the king
|
PROGRAMMING
| 1,000
|
[
"greedy",
"shortest paths"
] |
A. Shortest path of the king
|
1
|
64
|
The king is left alone on the chessboard. In spite of this loneliness, he doesn't lose heart, because he has business of national importance. For example, he has to pay an official visit to square *t*. As the king is not in habit of wasting his time, he wants to get from his current position *s* to square *t* in the least number of moves. Help him to do this.
In one move the king can get to the square that has a common side or a common vertex with the square the king is currently in (generally there are 8 different squares he can move to).
|
The first line contains the chessboard coordinates of square *s*, the second line — of square *t*.
Chessboard coordinates consist of two characters, the first one is a lowercase Latin letter (from a to h), the second one is a digit from 1 to 8.
|
In the first line print *n* — minimum number of the king's moves. Then in *n* lines print the moves themselves. Each move is described with one of the 8: L, R, U, D, LU, LD, RU or RD.
L, R, U, D stand respectively for moves left, right, up and down (according to the picture), and 2-letter combinations stand for diagonal moves. If the answer is not unique, print any of them.
|
[
"a8\nh1\n"
] |
[
"7\nRD\nRD\nRD\nRD\nRD\nRD\nRD\n"
] |
none
| 0
|
[
{
"input": "a8\nh1",
"output": "7\nRD\nRD\nRD\nRD\nRD\nRD\nRD"
},
{
"input": "b2\nb4",
"output": "2\nU\nU"
},
{
"input": "a5\na5",
"output": "0"
},
{
"input": "h1\nb2",
"output": "6\nLU\nL\nL\nL\nL\nL"
},
{
"input": "c5\nh2",
"output": "5\nRD\nRD\nRD\nR\nR"
},
{
"input": "e1\nf2",
"output": "1\nRU"
},
{
"input": "g4\nd2",
"output": "3\nLD\nLD\nL"
},
{
"input": "a8\nb2",
"output": "6\nRD\nD\nD\nD\nD\nD"
},
{
"input": "d4\nh2",
"output": "4\nRD\nRD\nR\nR"
},
{
"input": "c5\na2",
"output": "3\nLD\nLD\nD"
},
{
"input": "h5\nf8",
"output": "3\nLU\nLU\nU"
},
{
"input": "e6\nb6",
"output": "3\nL\nL\nL"
},
{
"input": "a6\ng4",
"output": "6\nRD\nRD\nR\nR\nR\nR"
},
{
"input": "f7\nc2",
"output": "5\nLD\nLD\nLD\nD\nD"
},
{
"input": "b7\nh8",
"output": "6\nRU\nR\nR\nR\nR\nR"
},
{
"input": "g7\nd6",
"output": "3\nLD\nL\nL"
},
{
"input": "c8\na3",
"output": "5\nLD\nLD\nD\nD\nD"
},
{
"input": "h8\nf1",
"output": "7\nLD\nLD\nD\nD\nD\nD\nD"
},
{
"input": "d1\nb7",
"output": "6\nLU\nLU\nU\nU\nU\nU"
},
{
"input": "a7\ne5",
"output": "4\nRD\nRD\nR\nR"
},
{
"input": "d6\nb1",
"output": "5\nLD\nLD\nD\nD\nD"
},
{
"input": "f5\ng5",
"output": "1\nR"
},
{
"input": "h4\nd1",
"output": "4\nLD\nLD\nLD\nL"
},
{
"input": "b3\na5",
"output": "2\nLU\nU"
},
{
"input": "d2\nf1",
"output": "2\nRD\nR"
},
{
"input": "f1\nc5",
"output": "4\nLU\nLU\nLU\nU"
},
{
"input": "a8\nh1",
"output": "7\nRD\nRD\nRD\nRD\nRD\nRD\nRD"
},
{
"input": "c7\ne5",
"output": "2\nRD\nRD"
},
{
"input": "e7\nb1",
"output": "6\nLD\nLD\nLD\nD\nD\nD"
},
{
"input": "g8\na8",
"output": "6\nL\nL\nL\nL\nL\nL"
},
{
"input": "g6\nf2",
"output": "4\nLD\nD\nD\nD"
},
{
"input": "g4\nc4",
"output": "4\nL\nL\nL\nL"
},
{
"input": "g2\na6",
"output": "6\nLU\nLU\nLU\nLU\nL\nL"
},
{
"input": "f8\nf8",
"output": "0"
},
{
"input": "f5\nd2",
"output": "3\nLD\nLD\nD"
}
] | 1,649,816,335
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 35
| 92
| 0
|
start = input().strip()
end = input().strip()
start = [{"a":1, "b":2, "c":3, "d":4, "e":5, "f":6, "g":7, "h":8}[start[0]], int(start[1])]
end = [{"a":1, "b":2, "c":3, "d":4, "e":5, "f":6, "g":7, "h":8}[end[0]], int(end[1])]
print(max(abs(start[0]-end[0]), abs(start[1]-end[1])), end="")
while start != end:
print()
if start[0] < end[0]:
start[0] += 1
print("R", end="")
if start[0] > end[0]:
start[0] -= 1
print("L", end="")
if start[1] < end[1]:
start[1] += 1
print("U", end="")
if start[1] > end[1]:
start[1] -= 1
print("D", end="")
|
Title: Shortest path of the king
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
The king is left alone on the chessboard. In spite of this loneliness, he doesn't lose heart, because he has business of national importance. For example, he has to pay an official visit to square *t*. As the king is not in habit of wasting his time, he wants to get from his current position *s* to square *t* in the least number of moves. Help him to do this.
In one move the king can get to the square that has a common side or a common vertex with the square the king is currently in (generally there are 8 different squares he can move to).
Input Specification:
The first line contains the chessboard coordinates of square *s*, the second line — of square *t*.
Chessboard coordinates consist of two characters, the first one is a lowercase Latin letter (from a to h), the second one is a digit from 1 to 8.
Output Specification:
In the first line print *n* — minimum number of the king's moves. Then in *n* lines print the moves themselves. Each move is described with one of the 8: L, R, U, D, LU, LD, RU or RD.
L, R, U, D stand respectively for moves left, right, up and down (according to the picture), and 2-letter combinations stand for diagonal moves. If the answer is not unique, print any of them.
Demo Input:
['a8\nh1\n']
Demo Output:
['7\nRD\nRD\nRD\nRD\nRD\nRD\nRD\n']
Note:
none
|
```python
start = input().strip()
end = input().strip()
start = [{"a":1, "b":2, "c":3, "d":4, "e":5, "f":6, "g":7, "h":8}[start[0]], int(start[1])]
end = [{"a":1, "b":2, "c":3, "d":4, "e":5, "f":6, "g":7, "h":8}[end[0]], int(end[1])]
print(max(abs(start[0]-end[0]), abs(start[1]-end[1])), end="")
while start != end:
print()
if start[0] < end[0]:
start[0] += 1
print("R", end="")
if start[0] > end[0]:
start[0] -= 1
print("L", end="")
if start[1] < end[1]:
start[1] += 1
print("U", end="")
if start[1] > end[1]:
start[1] -= 1
print("D", end="")
```
| 3.954
|
961
|
B
|
Lecture Sleep
|
PROGRAMMING
| 1,200
|
[
"data structures",
"dp",
"implementation",
"two pointers"
] | null | null |
Your friend Mishka and you attend a calculus lecture. Lecture lasts *n* minutes. Lecturer tells *a**i* theorems during the *i*-th minute.
Mishka is really interested in calculus, though it is so hard to stay awake for all the time of lecture. You are given an array *t* of Mishka's behavior. If Mishka is asleep during the *i*-th minute of the lecture then *t**i* will be equal to 0, otherwise it will be equal to 1. When Mishka is awake he writes down all the theorems he is being told — *a**i* during the *i*-th minute. Otherwise he writes nothing.
You know some secret technique to keep Mishka awake for *k* minutes straight. However you can use it only once. You can start using it at the beginning of any minute between 1 and *n*<=-<=*k*<=+<=1. If you use it on some minute *i* then Mishka will be awake during minutes *j* such that and will write down all the theorems lecturer tells.
You task is to calculate the maximum number of theorems Mishka will be able to write down if you use your technique only once to wake him up.
|
The first line of the input contains two integer numbers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=105) — the duration of the lecture in minutes and the number of minutes you can keep Mishka awake.
The second line of the input contains *n* integer numbers *a*1,<=*a*2,<=... *a**n* (1<=≤<=*a**i*<=≤<=104) — the number of theorems lecturer tells during the *i*-th minute.
The third line of the input contains *n* integer numbers *t*1,<=*t*2,<=... *t**n* (0<=≤<=*t**i*<=≤<=1) — type of Mishka's behavior at the *i*-th minute of the lecture.
|
Print only one integer — the maximum number of theorems Mishka will be able to write down if you use your technique only once to wake him up.
|
[
"6 3\n1 3 5 2 5 4\n1 1 0 1 0 0\n"
] |
[
"16\n"
] |
In the sample case the better way is to use the secret technique at the beginning of the third minute. Then the number of theorems Mishka will be able to write down will be equal to 16.
| 0
|
[
{
"input": "6 3\n1 3 5 2 5 4\n1 1 0 1 0 0",
"output": "16"
},
{
"input": "5 3\n1 9999 10000 10000 10000\n0 0 0 0 0",
"output": "30000"
},
{
"input": "3 3\n10 10 10\n1 1 0",
"output": "30"
},
{
"input": "1 1\n423\n0",
"output": "423"
},
{
"input": "6 6\n1 3 5 2 5 4\n1 1 0 1 0 0",
"output": "20"
},
{
"input": "5 2\n1 2 3 4 20\n0 0 0 1 0",
"output": "24"
},
{
"input": "3 1\n1 2 3\n0 0 1",
"output": "5"
},
{
"input": "4 2\n4 5 6 8\n1 0 1 0",
"output": "18"
},
{
"input": "6 3\n1 3 5 2 1 15\n1 1 0 1 0 0",
"output": "22"
},
{
"input": "5 5\n1 2 3 4 5\n1 1 1 0 1",
"output": "15"
},
{
"input": "3 3\n3 3 3\n1 0 1",
"output": "9"
},
{
"input": "5 5\n500 44 3 4 50\n1 0 0 0 0",
"output": "601"
},
{
"input": "2 2\n3 2\n1 0",
"output": "5"
},
{
"input": "7 6\n4 9 1 7 1 8 4\n0 0 0 1 0 1 0",
"output": "30"
},
{
"input": "4 3\n6 5 9 6\n1 1 0 1",
"output": "26"
},
{
"input": "2 1\n3 2\n0 0",
"output": "3"
},
{
"input": "1 1\n10\n0",
"output": "10"
},
{
"input": "2 1\n3 2\n1 0",
"output": "5"
},
{
"input": "4 2\n3 6 7 2\n0 0 1 1",
"output": "18"
},
{
"input": "10 5\n3 5 9 2 5 9 3 8 8 1\n0 1 1 1 0 1 0 0 0 0",
"output": "49"
},
{
"input": "10 4\n9 5 6 4 3 9 5 1 10 7\n0 0 0 0 0 0 1 0 0 1",
"output": "36"
},
{
"input": "9 8\n3 3 7 7 1 9 10 7 1\n1 1 1 1 1 1 1 1 1",
"output": "48"
},
{
"input": "2 1\n3 4\n0 0",
"output": "4"
},
{
"input": "2 1\n3 2\n0 1",
"output": "5"
},
{
"input": "10 1\n6 6 8 7 6 6 3 2 5 6\n0 0 1 0 0 1 0 1 1 1",
"output": "34"
},
{
"input": "3 2\n10 10 6\n0 0 0",
"output": "20"
},
{
"input": "6 3\n1 3 5 2 5 4\n1 1 1 1 1 1",
"output": "20"
},
{
"input": "10 5\n1 1 1 1 1 1 1 1 10000 1\n1 1 1 1 1 1 1 1 0 1",
"output": "10009"
}
] | 1,586,485,640
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 3
| 1,000
| 7,065,600
|
time_lecture, awake_time = [int(num) for num in input().split()]
theorems = [int(num) for num in input().split()]
awakeness = [int(num) for num in input().split()]
written = 0
maximum = 0
val_theorems = [theorems[i] if awakeness[i] == 1 else 0 for i in range(len(theorems))]
written = sum(val_theorems)
val_theorems = [theorems[i] if awakeness[i] == 0 else 0 for i in range(len(theorems))]
maximum = max([sum(val_theorems[i:i+awake_time]) for i in range(len(theorems))])
print(written+maximum)
|
Title: Lecture Sleep
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Your friend Mishka and you attend a calculus lecture. Lecture lasts *n* minutes. Lecturer tells *a**i* theorems during the *i*-th minute.
Mishka is really interested in calculus, though it is so hard to stay awake for all the time of lecture. You are given an array *t* of Mishka's behavior. If Mishka is asleep during the *i*-th minute of the lecture then *t**i* will be equal to 0, otherwise it will be equal to 1. When Mishka is awake he writes down all the theorems he is being told — *a**i* during the *i*-th minute. Otherwise he writes nothing.
You know some secret technique to keep Mishka awake for *k* minutes straight. However you can use it only once. You can start using it at the beginning of any minute between 1 and *n*<=-<=*k*<=+<=1. If you use it on some minute *i* then Mishka will be awake during minutes *j* such that and will write down all the theorems lecturer tells.
You task is to calculate the maximum number of theorems Mishka will be able to write down if you use your technique only once to wake him up.
Input Specification:
The first line of the input contains two integer numbers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=105) — the duration of the lecture in minutes and the number of minutes you can keep Mishka awake.
The second line of the input contains *n* integer numbers *a*1,<=*a*2,<=... *a**n* (1<=≤<=*a**i*<=≤<=104) — the number of theorems lecturer tells during the *i*-th minute.
The third line of the input contains *n* integer numbers *t*1,<=*t*2,<=... *t**n* (0<=≤<=*t**i*<=≤<=1) — type of Mishka's behavior at the *i*-th minute of the lecture.
Output Specification:
Print only one integer — the maximum number of theorems Mishka will be able to write down if you use your technique only once to wake him up.
Demo Input:
['6 3\n1 3 5 2 5 4\n1 1 0 1 0 0\n']
Demo Output:
['16\n']
Note:
In the sample case the better way is to use the secret technique at the beginning of the third minute. Then the number of theorems Mishka will be able to write down will be equal to 16.
|
```python
time_lecture, awake_time = [int(num) for num in input().split()]
theorems = [int(num) for num in input().split()]
awakeness = [int(num) for num in input().split()]
written = 0
maximum = 0
val_theorems = [theorems[i] if awakeness[i] == 1 else 0 for i in range(len(theorems))]
written = sum(val_theorems)
val_theorems = [theorems[i] if awakeness[i] == 0 else 0 for i in range(len(theorems))]
maximum = max([sum(val_theorems[i:i+awake_time]) for i in range(len(theorems))])
print(written+maximum)
```
| 0
|
|
749
|
A
|
Bachgold Problem
|
PROGRAMMING
| 800
|
[
"greedy",
"implementation",
"math",
"number theory"
] | null | null |
Bachgold problem is very easy to formulate. Given a positive integer *n* represent it as a sum of maximum possible number of prime numbers. One can prove that such representation exists for any integer greater than 1.
Recall that integer *k* is called prime if it is greater than 1 and has exactly two positive integer divisors — 1 and *k*.
|
The only line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100<=000).
|
The first line of the output contains a single integer *k* — maximum possible number of primes in representation.
The second line should contain *k* primes with their sum equal to *n*. You can print them in any order. If there are several optimal solution, print any of them.
|
[
"5\n",
"6\n"
] |
[
"2\n2 3\n",
"3\n2 2 2\n"
] |
none
| 500
|
[
{
"input": "5",
"output": "2\n2 3"
},
{
"input": "6",
"output": "3\n2 2 2"
},
{
"input": "2",
"output": "1\n2"
},
{
"input": "3",
"output": "1\n3"
},
{
"input": "99999",
"output": "49999\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "100000",
"output": "50000\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "7",
"output": "3\n2 2 3"
},
{
"input": "4",
"output": "2\n2 2"
},
{
"input": "8",
"output": "4\n2 2 2 2"
},
{
"input": "9",
"output": "4\n2 2 2 3"
},
{
"input": "99995",
"output": "49997\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99996",
"output": "49998\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "10",
"output": "5\n2 2 2 2 2"
},
{
"input": "11",
"output": "5\n2 2 2 2 3"
},
{
"input": "99997",
"output": "49998\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99998",
"output": "49999\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "12",
"output": "6\n2 2 2 2 2 2"
},
{
"input": "13",
"output": "6\n2 2 2 2 2 3"
},
{
"input": "99993",
"output": "49996\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99994",
"output": "49997\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "14",
"output": "7\n2 2 2 2 2 2 2"
},
{
"input": "15",
"output": "7\n2 2 2 2 2 2 3"
},
{
"input": "53",
"output": "26\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "57",
"output": "28\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "61",
"output": "30\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "774",
"output": "387\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "202",
"output": "101\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2"
},
{
"input": "530",
"output": "265\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "7166",
"output": "3583\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "9294",
"output": "4647\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "2422",
"output": "1211\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "15326",
"output": "7663\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "11454",
"output": "5727\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "14878",
"output": "7439\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "90672",
"output": "45336\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99544",
"output": "49772\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "90472",
"output": "45236\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "23",
"output": "11\n2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "93",
"output": "46\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "19",
"output": "9\n2 2 2 2 2 2 2 2 3"
},
{
"input": "11110",
"output": "5555\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
}
] | 1,695,844,993
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 0
| 15
| 0
|
def prime_checker(n):
if n == 1 or n == 0:
return f"{n} is not a prime number"
prime = True
for i in range(2, n):
if n%i == 0:
prime = False
break
return prime
n = int(input())
if n%2 == 0:
print(int(n/2))
print("2 " * int(n/2))
else:
temp = n-1
while not (prime_checker(n - temp) and temp%2!=0):
temp -= 1
print("temp = ",temp)
print("2 "*int(temp/2), end="")
print(n - temp + 1)
|
Title: Bachgold Problem
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Bachgold problem is very easy to formulate. Given a positive integer *n* represent it as a sum of maximum possible number of prime numbers. One can prove that such representation exists for any integer greater than 1.
Recall that integer *k* is called prime if it is greater than 1 and has exactly two positive integer divisors — 1 and *k*.
Input Specification:
The only line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100<=000).
Output Specification:
The first line of the output contains a single integer *k* — maximum possible number of primes in representation.
The second line should contain *k* primes with their sum equal to *n*. You can print them in any order. If there are several optimal solution, print any of them.
Demo Input:
['5\n', '6\n']
Demo Output:
['2\n2 3\n', '3\n2 2 2\n']
Note:
none
|
```python
def prime_checker(n):
if n == 1 or n == 0:
return f"{n} is not a prime number"
prime = True
for i in range(2, n):
if n%i == 0:
prime = False
break
return prime
n = int(input())
if n%2 == 0:
print(int(n/2))
print("2 " * int(n/2))
else:
temp = n-1
while not (prime_checker(n - temp) and temp%2!=0):
temp -= 1
print("temp = ",temp)
print("2 "*int(temp/2), end="")
print(n - temp + 1)
```
| 0
|
|
554
|
A
|
Kyoya and Photobooks
|
PROGRAMMING
| 900
|
[
"brute force",
"math",
"strings"
] | null | null |
Kyoya Ootori is selling photobooks of the Ouran High School Host Club. He has 26 photos, labeled "a" to "z", and he has compiled them into a photo booklet with some photos in some order (possibly with some photos being duplicated). A photo booklet can be described as a string of lowercase letters, consisting of the photos in the booklet in order. He now wants to sell some "special edition" photobooks, each with one extra photo inserted anywhere in the book. He wants to make as many distinct photobooks as possible, so he can make more money. He asks Haruhi, how many distinct photobooks can he make by inserting one extra photo into the photobook he already has?
Please help Haruhi solve this problem.
|
The first line of input will be a single string *s* (1<=≤<=|*s*|<=≤<=20). String *s* consists only of lowercase English letters.
|
Output a single integer equal to the number of distinct photobooks Kyoya Ootori can make.
|
[
"a\n",
"hi\n"
] |
[
"51\n",
"76\n"
] |
In the first case, we can make 'ab','ac',...,'az','ba','ca',...,'za', and 'aa', producing a total of 51 distinct photo booklets.
| 250
|
[
{
"input": "a",
"output": "51"
},
{
"input": "hi",
"output": "76"
},
{
"input": "y",
"output": "51"
},
{
"input": "kgan",
"output": "126"
},
{
"input": "zoabkyuvus",
"output": "276"
},
{
"input": "spyemhyznjieyhhbk",
"output": "451"
},
{
"input": "xulsyfkuizjauadjjopu",
"output": "526"
},
{
"input": "e",
"output": "51"
},
{
"input": "zv",
"output": "76"
},
{
"input": "jgv",
"output": "101"
},
{
"input": "zsfo",
"output": "126"
},
{
"input": "jselr",
"output": "151"
},
{
"input": "dwemig",
"output": "176"
},
{
"input": "mddoxsf",
"output": "201"
},
{
"input": "jgirkrmi",
"output": "226"
},
{
"input": "spkxurcum",
"output": "251"
},
{
"input": "fykkiubdkt",
"output": "276"
},
{
"input": "fznbcxsxygs",
"output": "301"
},
{
"input": "qcrvrdqcbtou",
"output": "326"
},
{
"input": "qktrbjzrqgmlr",
"output": "351"
},
{
"input": "foamodbvptlxxg",
"output": "376"
},
{
"input": "ydzpjhsidipricw",
"output": "401"
},
{
"input": "lpfpndmjfvqejdgf",
"output": "426"
},
{
"input": "ofkvparuvjtggnmab",
"output": "451"
},
{
"input": "xxncfutrtxcwdzwbgs",
"output": "476"
},
{
"input": "zovhffccflkgqncsdte",
"output": "501"
},
{
"input": "cskgsxywlvfeicoueglr",
"output": "526"
},
{
"input": "gggggggggggggggggggg",
"output": "526"
},
{
"input": "qdqdddqddqqddqddqdqd",
"output": "526"
},
{
"input": "takttttaakaaktakttkt",
"output": "526"
},
{
"input": "coccoooogogcgocccmcg",
"output": "526"
},
{
"input": "kskkskkkssksssk",
"output": "401"
},
{
"input": "lllllllllllllll",
"output": "401"
}
] | 1,673,756,284
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 33
| 62
| 0
|
l=list(input())
count=0
ans=26+25
for i in range(len(l)-1):
if l[i]==l[i+1]:
# coun
ans+=25
if l[i]!=l[i+1]:
count+=1
ans+=25
print(ans)
|
Title: Kyoya and Photobooks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Kyoya Ootori is selling photobooks of the Ouran High School Host Club. He has 26 photos, labeled "a" to "z", and he has compiled them into a photo booklet with some photos in some order (possibly with some photos being duplicated). A photo booklet can be described as a string of lowercase letters, consisting of the photos in the booklet in order. He now wants to sell some "special edition" photobooks, each with one extra photo inserted anywhere in the book. He wants to make as many distinct photobooks as possible, so he can make more money. He asks Haruhi, how many distinct photobooks can he make by inserting one extra photo into the photobook he already has?
Please help Haruhi solve this problem.
Input Specification:
The first line of input will be a single string *s* (1<=≤<=|*s*|<=≤<=20). String *s* consists only of lowercase English letters.
Output Specification:
Output a single integer equal to the number of distinct photobooks Kyoya Ootori can make.
Demo Input:
['a\n', 'hi\n']
Demo Output:
['51\n', '76\n']
Note:
In the first case, we can make 'ab','ac',...,'az','ba','ca',...,'za', and 'aa', producing a total of 51 distinct photo booklets.
|
```python
l=list(input())
count=0
ans=26+25
for i in range(len(l)-1):
if l[i]==l[i+1]:
# coun
ans+=25
if l[i]!=l[i+1]:
count+=1
ans+=25
print(ans)
```
| 3
|
|
115
|
A
|
Party
|
PROGRAMMING
| 900
|
[
"dfs and similar",
"graphs",
"trees"
] | null | null |
A company has *n* employees numbered from 1 to *n*. Each employee either has no immediate manager or exactly one immediate manager, who is another employee with a different number. An employee *A* is said to be the superior of another employee *B* if at least one of the following is true:
- Employee *A* is the immediate manager of employee *B* - Employee *B* has an immediate manager employee *C* such that employee *A* is the superior of employee *C*.
The company will not have a managerial cycle. That is, there will not exist an employee who is the superior of his/her own immediate manager.
Today the company is going to arrange a party. This involves dividing all *n* employees into several groups: every employee must belong to exactly one group. Furthermore, within any single group, there must not be two employees *A* and *B* such that *A* is the superior of *B*.
What is the minimum number of groups that must be formed?
|
The first line contains integer *n* (1<=≤<=*n*<=≤<=2000) — the number of employees.
The next *n* lines contain the integers *p**i* (1<=≤<=*p**i*<=≤<=*n* or *p**i*<==<=-1). Every *p**i* denotes the immediate manager for the *i*-th employee. If *p**i* is -1, that means that the *i*-th employee does not have an immediate manager.
It is guaranteed, that no employee will be the immediate manager of him/herself (*p**i*<=≠<=*i*). Also, there will be no managerial cycles.
|
Print a single integer denoting the minimum number of groups that will be formed in the party.
|
[
"5\n-1\n1\n2\n1\n-1\n"
] |
[
"3\n"
] |
For the first example, three groups are sufficient, for example:
- Employee 1 - Employees 2 and 4 - Employees 3 and 5
| 500
|
[
{
"input": "5\n-1\n1\n2\n1\n-1",
"output": "3"
},
{
"input": "4\n-1\n1\n2\n3",
"output": "4"
},
{
"input": "12\n-1\n1\n2\n3\n-1\n5\n6\n7\n-1\n9\n10\n11",
"output": "4"
},
{
"input": "6\n-1\n-1\n2\n3\n1\n1",
"output": "3"
},
{
"input": "3\n-1\n1\n1",
"output": "2"
},
{
"input": "1\n-1",
"output": "1"
},
{
"input": "2\n2\n-1",
"output": "2"
},
{
"input": "2\n-1\n-1",
"output": "1"
},
{
"input": "3\n2\n-1\n1",
"output": "3"
},
{
"input": "3\n-1\n-1\n-1",
"output": "1"
},
{
"input": "5\n4\n5\n1\n-1\n4",
"output": "3"
},
{
"input": "12\n-1\n1\n1\n1\n1\n1\n3\n4\n3\n3\n4\n7",
"output": "4"
},
{
"input": "12\n-1\n-1\n1\n-1\n1\n1\n5\n11\n8\n6\n6\n4",
"output": "5"
},
{
"input": "12\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n2\n-1\n-1\n-1",
"output": "2"
},
{
"input": "12\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1\n-1",
"output": "1"
},
{
"input": "12\n3\n4\n2\n8\n7\n1\n10\n12\n5\n-1\n9\n11",
"output": "12"
},
{
"input": "12\n5\n6\n7\n1\n-1\n9\n12\n4\n8\n-1\n3\n2",
"output": "11"
},
{
"input": "12\n-1\n9\n11\n6\n6\n-1\n6\n3\n8\n6\n1\n6",
"output": "6"
},
{
"input": "12\n7\n8\n4\n12\n7\n9\n-1\n-1\n-1\n8\n6\n-1",
"output": "3"
},
{
"input": "12\n-1\n10\n-1\n1\n-1\n5\n9\n12\n-1\n-1\n3\n-1",
"output": "2"
},
{
"input": "12\n-1\n7\n9\n12\n1\n7\n-1\n-1\n8\n5\n4\n-1",
"output": "3"
},
{
"input": "12\n11\n11\n8\n9\n1\n1\n2\n-1\n10\n3\n-1\n8",
"output": "5"
},
{
"input": "12\n-1\n8\n9\n-1\n4\n2\n11\n1\n-1\n6\n-1\n10",
"output": "6"
},
{
"input": "12\n7\n4\n4\n-1\n6\n7\n9\n7\n-1\n7\n4\n1",
"output": "4"
},
{
"input": "12\n-1\n6\n10\n6\n1\n11\n5\n9\n11\n5\n1\n9",
"output": "4"
},
{
"input": "12\n8\n6\n6\n8\n6\n-1\n6\n6\n8\n6\n8\n8",
"output": "3"
},
{
"input": "12\n3\n8\n9\n12\n2\n8\n11\n12\n2\n9\n-1\n11",
"output": "7"
},
{
"input": "7\n7\n6\n-1\n-1\n4\n4\n-1",
"output": "3"
},
{
"input": "77\n53\n-1\n48\n-1\n51\n-1\n54\n43\n70\n19\n64\n31\n45\n58\n6\n61\n41\n56\n34\n-1\n54\n-1\n66\n65\n74\n16\n38\n1\n2\n61\n-1\n34\n-1\n-1\n7\n19\n57\n13\n61\n42\n-1\n34\n65\n16\n31\n61\n6\n5\n34\n15\n-1\n13\n4\n22\n74\n7\n-1\n70\n38\n61\n45\n53\n46\n22\n-1\n65\n34\n19\n43\n48\n33\n58\n36\n-1\n47\n24\n34",
"output": "6"
},
{
"input": "5\n2\n3\n4\n5\n-1",
"output": "5"
}
] | 1,696,808,609
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 106
| 746
| 0
|
n = int(input())
parent = [int(input()) for _ in range(n)]
depth = [0] * n
for i in range(n):
d = 0
j = i
while parent[j] != -1 and depth[j] == 0:
j = parent[j] - 1
d += 1
depth[i] = depth[j] + d
print(max(depth)+1)
|
Title: Party
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A company has *n* employees numbered from 1 to *n*. Each employee either has no immediate manager or exactly one immediate manager, who is another employee with a different number. An employee *A* is said to be the superior of another employee *B* if at least one of the following is true:
- Employee *A* is the immediate manager of employee *B* - Employee *B* has an immediate manager employee *C* such that employee *A* is the superior of employee *C*.
The company will not have a managerial cycle. That is, there will not exist an employee who is the superior of his/her own immediate manager.
Today the company is going to arrange a party. This involves dividing all *n* employees into several groups: every employee must belong to exactly one group. Furthermore, within any single group, there must not be two employees *A* and *B* such that *A* is the superior of *B*.
What is the minimum number of groups that must be formed?
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=2000) — the number of employees.
The next *n* lines contain the integers *p**i* (1<=≤<=*p**i*<=≤<=*n* or *p**i*<==<=-1). Every *p**i* denotes the immediate manager for the *i*-th employee. If *p**i* is -1, that means that the *i*-th employee does not have an immediate manager.
It is guaranteed, that no employee will be the immediate manager of him/herself (*p**i*<=≠<=*i*). Also, there will be no managerial cycles.
Output Specification:
Print a single integer denoting the minimum number of groups that will be formed in the party.
Demo Input:
['5\n-1\n1\n2\n1\n-1\n']
Demo Output:
['3\n']
Note:
For the first example, three groups are sufficient, for example:
- Employee 1 - Employees 2 and 4 - Employees 3 and 5
|
```python
n = int(input())
parent = [int(input()) for _ in range(n)]
depth = [0] * n
for i in range(n):
d = 0
j = i
while parent[j] != -1 and depth[j] == 0:
j = parent[j] - 1
d += 1
depth[i] = depth[j] + d
print(max(depth)+1)
```
| 3
|
|
69
|
A
|
Young Physicist
|
PROGRAMMING
| 1,000
|
[
"implementation",
"math"
] |
A. Young Physicist
|
2
|
256
|
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
|
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
|
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
|
[
"3\n4 1 7\n-2 4 -1\n1 -5 -3\n",
"3\n3 -1 7\n-5 2 -4\n2 -1 -3\n"
] |
[
"NO",
"YES"
] |
none
| 500
|
[
{
"input": "3\n4 1 7\n-2 4 -1\n1 -5 -3",
"output": "NO"
},
{
"input": "3\n3 -1 7\n-5 2 -4\n2 -1 -3",
"output": "YES"
},
{
"input": "10\n21 32 -46\n43 -35 21\n42 2 -50\n22 40 20\n-27 -9 38\n-4 1 1\n-40 6 -31\n-13 -2 34\n-21 34 -12\n-32 -29 41",
"output": "NO"
},
{
"input": "10\n25 -33 43\n-27 -42 28\n-35 -20 19\n41 -42 -1\n49 -39 -4\n-49 -22 7\n-19 29 41\n8 -27 -43\n8 34 9\n-11 -3 33",
"output": "NO"
},
{
"input": "10\n-6 21 18\n20 -11 -8\n37 -11 41\n-5 8 33\n29 23 32\n30 -33 -11\n39 -49 -36\n28 34 -49\n22 29 -34\n-18 -6 7",
"output": "NO"
},
{
"input": "10\n47 -2 -27\n0 26 -14\n5 -12 33\n2 18 3\n45 -30 -49\n4 -18 8\n-46 -44 -41\n-22 -10 -40\n-35 -21 26\n33 20 38",
"output": "NO"
},
{
"input": "13\n-3 -36 -46\n-11 -50 37\n42 -11 -15\n9 42 44\n-29 -12 24\n3 9 -40\n-35 13 50\n14 43 18\n-13 8 24\n-48 -15 10\n50 9 -50\n21 0 -50\n0 0 -6",
"output": "YES"
},
{
"input": "14\n43 23 17\n4 17 44\n5 -5 -16\n-43 -7 -6\n47 -48 12\n50 47 -45\n2 14 43\n37 -30 15\n4 -17 -11\n17 9 -45\n-50 -3 -8\n-50 0 0\n-50 0 0\n-16 0 0",
"output": "YES"
},
{
"input": "13\n29 49 -11\n38 -11 -20\n25 1 -40\n-11 28 11\n23 -19 1\n45 -41 -17\n-3 0 -19\n-13 -33 49\n-30 0 28\n34 17 45\n-50 9 -27\n-50 0 0\n-37 0 0",
"output": "YES"
},
{
"input": "12\n3 28 -35\n-32 -44 -17\n9 -25 -6\n-42 -22 20\n-19 15 38\n-21 38 48\n-1 -37 -28\n-10 -13 -50\n-5 21 29\n34 28 50\n50 11 -49\n34 0 0",
"output": "YES"
},
{
"input": "37\n-64 -79 26\n-22 59 93\n-5 39 -12\n77 -9 76\n55 -86 57\n83 100 -97\n-70 94 84\n-14 46 -94\n26 72 35\n14 78 -62\n17 82 92\n-57 11 91\n23 15 92\n-80 -1 1\n12 39 18\n-23 -99 -75\n-34 50 19\n-39 84 -7\n45 -30 -39\n-60 49 37\n45 -16 -72\n33 -51 -56\n-48 28 5\n97 91 88\n45 -82 -11\n-21 -15 -90\n-53 73 -26\n-74 85 -90\n-40 23 38\n100 -13 49\n32 -100 -100\n0 -100 -70\n0 -100 0\n0 -100 0\n0 -100 0\n0 -100 0\n0 -37 0",
"output": "YES"
},
{
"input": "4\n68 3 100\n68 21 -100\n-100 -24 0\n-36 0 0",
"output": "YES"
},
{
"input": "33\n-1 -46 -12\n45 -16 -21\n-11 45 -21\n-60 -42 -93\n-22 -45 93\n37 96 85\n-76 26 83\n-4 9 55\n7 -52 -9\n66 8 -85\n-100 -54 11\n-29 59 74\n-24 12 2\n-56 81 85\n-92 69 -52\n-26 -97 91\n54 59 -51\n58 21 -57\n7 68 56\n-47 -20 -51\n-59 77 -13\n-85 27 91\n79 60 -56\n66 -80 5\n21 -99 42\n-31 -29 98\n66 93 76\n-49 45 61\n100 -100 -100\n100 -100 -100\n66 -75 -100\n0 0 -100\n0 0 -87",
"output": "YES"
},
{
"input": "3\n1 2 3\n3 2 1\n0 0 0",
"output": "NO"
},
{
"input": "2\n5 -23 12\n0 0 0",
"output": "NO"
},
{
"input": "1\n0 0 0",
"output": "YES"
},
{
"input": "1\n1 -2 0",
"output": "NO"
},
{
"input": "2\n-23 77 -86\n23 -77 86",
"output": "YES"
},
{
"input": "26\n86 7 20\n-57 -64 39\n-45 6 -93\n-44 -21 100\n-11 -49 21\n73 -71 -80\n-2 -89 56\n-65 -2 7\n5 14 84\n57 41 13\n-12 69 54\n40 -25 27\n-17 -59 0\n64 -91 -30\n-53 9 42\n-54 -8 14\n-35 82 27\n-48 -59 -80\n88 70 79\n94 57 97\n44 63 25\n84 -90 -40\n-100 100 -100\n-92 100 -100\n0 10 -100\n0 0 -82",
"output": "YES"
},
{
"input": "42\n11 27 92\n-18 -56 -57\n1 71 81\n33 -92 30\n82 83 49\n-87 -61 -1\n-49 45 49\n73 26 15\n-22 22 -77\n29 -93 87\n-68 44 -90\n-4 -84 20\n85 67 -6\n-39 26 77\n-28 -64 20\n65 -97 24\n-72 -39 51\n35 -75 -91\n39 -44 -8\n-25 -27 -57\n91 8 -46\n-98 -94 56\n94 -60 59\n-9 -95 18\n-53 -37 98\n-8 -94 -84\n-52 55 60\n15 -14 37\n65 -43 -25\n94 12 66\n-8 -19 -83\n29 81 -78\n-58 57 33\n24 86 -84\n-53 32 -88\n-14 7 3\n89 97 -53\n-5 -28 -91\n-100 100 -6\n-84 100 0\n0 100 0\n0 70 0",
"output": "YES"
},
{
"input": "3\n96 49 -12\n2 -66 28\n-98 17 -16",
"output": "YES"
},
{
"input": "5\n70 -46 86\n-100 94 24\n-27 63 -63\n57 -100 -47\n0 -11 0",
"output": "YES"
},
{
"input": "18\n-86 -28 70\n-31 -89 42\n31 -48 -55\n95 -17 -43\n24 -95 -85\n-21 -14 31\n68 -18 81\n13 31 60\n-15 28 99\n-42 15 9\n28 -61 -62\n-16 71 29\n-28 75 -48\n-77 -67 36\n-100 83 89\n100 100 -100\n57 34 -100\n0 0 -53",
"output": "YES"
},
{
"input": "44\n52 -54 -29\n-82 -5 -94\n-54 43 43\n91 16 71\n7 80 -91\n3 15 29\n-99 -6 -77\n-3 -77 -64\n73 67 34\n25 -10 -18\n-29 91 63\n-72 86 -16\n-68 85 -81\n-3 36 44\n-74 -14 -80\n34 -96 -97\n-76 -78 -33\n-24 44 -58\n98 12 77\n95 -63 -6\n-51 3 -90\n-92 -10 72\n7 3 -68\n57 -53 71\n29 57 -48\n35 -60 10\n79 -70 -61\n-20 77 55\n-86 -15 -35\n84 -88 -18\n100 -42 77\n-20 46 8\n-41 -43 -65\n38 -98 -23\n-100 65 45\n-7 -91 -63\n46 88 -85\n48 59 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 100\n0 0 1",
"output": "YES"
},
{
"input": "18\n-14 -64 -91\n-8 -66 -86\n-23 92 -40\n6 -3 -53\n57 41 78\n-79 42 -22\n-88 -17 45\n4 -45 44\n83 -18 -25\n34 86 -92\n75 -30 12\n44 99 11\n-67 -13 72\n22 83 -56\n-37 71 72\n-9 -100 100\n0 -100 31\n0 -58 0",
"output": "YES"
},
{
"input": "23\n-70 37 78\n42 84 6\n28 -94 -24\n-49 76 95\n-67 18 84\n-53 78 -5\n65 -63 -64\n-66 -64 -69\n81 -93 95\n10 52 -79\n-89 -61 -64\n-64 -47 43\n-81 -35 55\n80 82 73\n-60 -81 -18\n49 -10 -19\n-58 70 12\n-24 -15 -93\n98 -93 -54\n-28 -75 11\n100 100 -63\n100 100 0\n56 34 0",
"output": "YES"
},
{
"input": "3\n0 2 -2\n1 -1 3\n-3 0 0",
"output": "NO"
}
] | 1,586,357,367
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 80
| 218
| 0
|
k = int(input())
parentlist = []
for i in range(0, k):
parentlist.append([int(x) for x in input().split()])
summ = [sum(x) for x in zip(*parentlist)]
if sum(summ) == 0:
print('YES'.strip(''))
else:
print('NO'.strip(''))
# print(summ)
# flatten_list = list(chain.from_iterable(parentlist))
# summ = sum(map(int, flatten_list))
# yes = 'YES'
# no = 'NO'
# if (summ == 0):
# print(yes)
# else:
# print(no)
# 0 2 -2
# 1 -1 3
# -3 0 0
|
Title: Young Physicist
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
A guy named Vasya attends the final grade of a high school. One day Vasya decided to watch a match of his favorite hockey team. And, as the boy loves hockey very much, even more than physics, he forgot to do the homework. Specifically, he forgot to complete his physics tasks. Next day the teacher got very angry at Vasya and decided to teach him a lesson. He gave the lazy student a seemingly easy task: You are given an idle body in space and the forces that affect it. The body can be considered as a material point with coordinates (0; 0; 0). Vasya had only to answer whether it is in equilibrium. "Piece of cake" — thought Vasya, we need only to check if the sum of all vectors is equal to 0. So, Vasya began to solve the problem. But later it turned out that there can be lots and lots of these forces, and Vasya can not cope without your help. Help him. Write a program that determines whether a body is idle or is moving by the given vectors of forces.
Input Specification:
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100), then follow *n* lines containing three integers each: the *x**i* coordinate, the *y**i* coordinate and the *z**i* coordinate of the force vector, applied to the body (<=-<=100<=≤<=*x**i*,<=*y**i*,<=*z**i*<=≤<=100).
Output Specification:
Print the word "YES" if the body is in equilibrium, or the word "NO" if it is not.
Demo Input:
['3\n4 1 7\n-2 4 -1\n1 -5 -3\n', '3\n3 -1 7\n-5 2 -4\n2 -1 -3\n']
Demo Output:
['NO', 'YES']
Note:
none
|
```python
k = int(input())
parentlist = []
for i in range(0, k):
parentlist.append([int(x) for x in input().split()])
summ = [sum(x) for x in zip(*parentlist)]
if sum(summ) == 0:
print('YES'.strip(''))
else:
print('NO'.strip(''))
# print(summ)
# flatten_list = list(chain.from_iterable(parentlist))
# summ = sum(map(int, flatten_list))
# yes = 'YES'
# no = 'NO'
# if (summ == 0):
# print(yes)
# else:
# print(no)
# 0 2 -2
# 1 -1 3
# -3 0 0
```
| 0
|
18
|
C
|
Stripe
|
PROGRAMMING
| 1,200
|
[
"data structures",
"implementation"
] |
C. Stripe
|
2
|
64
|
Once Bob took a paper stripe of *n* squares (the height of the stripe is 1 square). In each square he wrote an integer number, possibly negative. He became interested in how many ways exist to cut this stripe into two pieces so that the sum of numbers from one piece is equal to the sum of numbers from the other piece, and each piece contains positive integer amount of squares. Would you help Bob solve this problem?
|
The first input line contains integer *n* (1<=≤<=*n*<=≤<=105) — amount of squares in the stripe. The second line contains *n* space-separated numbers — they are the numbers written in the squares of the stripe. These numbers are integer and do not exceed 10000 in absolute value.
|
Output the amount of ways to cut the stripe into two non-empty pieces so that the sum of numbers from one piece is equal to the sum of numbers from the other piece. Don't forget that it's allowed to cut the stripe along the squares' borders only.
|
[
"9\n1 5 -6 7 9 -16 0 -2 2\n",
"3\n1 1 1\n",
"2\n0 0\n"
] |
[
"3\n",
"0\n",
"1\n"
] |
none
| 0
|
[
{
"input": "9\n1 5 -6 7 9 -16 0 -2 2",
"output": "3"
},
{
"input": "3\n1 1 1",
"output": "0"
},
{
"input": "2\n0 0",
"output": "1"
},
{
"input": "4\n100 1 10 111",
"output": "1"
},
{
"input": "10\n0 4 -3 0 -2 2 -3 -3 2 5",
"output": "3"
},
{
"input": "10\n0 -1 2 2 -1 1 0 0 0 2",
"output": "0"
},
{
"input": "10\n-1 -1 1 -1 0 1 0 1 1 1",
"output": "1"
},
{
"input": "10\n0 0 0 0 0 0 0 0 0 0",
"output": "9"
},
{
"input": "50\n-4 -3 3 4 -1 0 2 -4 -3 -4 1 4 3 0 4 1 0 -3 4 -3 -2 2 2 1 0 -4 -4 -5 3 2 -1 4 5 -3 -3 4 4 -5 2 -3 4 -5 2 5 -4 4 1 -2 -4 3",
"output": "3"
},
{
"input": "15\n0 4 0 3 -1 4 -2 -2 -4 -4 3 2 4 -1 -3",
"output": "0"
},
{
"input": "10\n3 -1 -3 -1 3 -2 0 3 1 -2",
"output": "0"
},
{
"input": "100\n-4 2 4 4 1 3 -3 -3 2 1 -4 0 0 2 3 -1 -4 -3 4 -2 -3 -3 -3 -1 -2 -3 -1 -4 0 4 0 -1 4 0 -4 -4 4 -4 -2 1 -4 1 -3 -2 3 -4 4 0 -1 3 -1 4 -1 4 -1 3 -3 -3 -2 -2 4 -3 -3 4 -3 -2 -1 0 -2 4 0 -3 -1 -2 -3 1 -4 1 -3 -3 -3 -2 -3 0 1 -2 -2 -4 -3 -1 2 3 -1 1 1 0 3 -3 -1 -2",
"output": "1"
},
{
"input": "100\n-2 -1 1 0 -2 -1 2 2 0 0 2 1 0 2 0 2 1 0 -1 -1 -1 0 -2 -1 2 -1 -2 2 -2 2 -2 -2 2 1 1 1 -2 2 0 0 2 -1 2 2 2 0 -1 -1 -1 1 -2 2 2 2 -2 0 0 -2 0 -2 -2 0 -1 -1 -2 -1 1 2 -2 -1 1 -2 -1 0 -2 2 2 -1 -2 2 0 0 0 1 0 1 2 1 -2 -2 -1 -1 -2 -2 -2 -1 2 2 2 -2",
"output": "6"
},
{
"input": "100\n2 7 6 0 8 -2 0 1 8 -1 7 -4 -1 1 0 3 4 -4 3 7 8 -4 -6 6 4 -2 -5 7 4 6 1 6 3 8 -2 6 -6 -3 0 -1 -7 -8 -2 5 8 6 -2 -2 -5 -4 -7 -3 -5 -3 -3 -1 5 8 4 0 -7 -6 8 -4 -1 7 2 6 6 4 -5 -4 -5 -2 2 -2 -7 -1 5 -8 -6 -2 -5 4 2 8 -6 7 -8 -1 -5 8 6 -3 -1 7 -1 2 -8 -8",
"output": "0"
},
{
"input": "1\n0",
"output": "0"
},
{
"input": "1\n10000",
"output": "0"
},
{
"input": "1\n-10000",
"output": "0"
}
] | 1,638,740,301
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 45
| 280
| 11,776,000
|
n = int(input())
nums = [int(x) for x in input().split()]
leftsum = 0
left = [0 for _ in range(n)]
for x in range(n):
leftsum += nums[x]
left[x] = leftsum
rightsum = 0
right = [0 for _ in range(n)]
for x in range(n - 1, -1, -1):
rightsum += nums[x]
right[x] = rightsum
# print(left)
# print(right)
count = 0
for i in range(n - 1):
if left[i] == right[i + 1]:
count += 1
print(count)
|
Title: Stripe
Time Limit: 2 seconds
Memory Limit: 64 megabytes
Problem Description:
Once Bob took a paper stripe of *n* squares (the height of the stripe is 1 square). In each square he wrote an integer number, possibly negative. He became interested in how many ways exist to cut this stripe into two pieces so that the sum of numbers from one piece is equal to the sum of numbers from the other piece, and each piece contains positive integer amount of squares. Would you help Bob solve this problem?
Input Specification:
The first input line contains integer *n* (1<=≤<=*n*<=≤<=105) — amount of squares in the stripe. The second line contains *n* space-separated numbers — they are the numbers written in the squares of the stripe. These numbers are integer and do not exceed 10000 in absolute value.
Output Specification:
Output the amount of ways to cut the stripe into two non-empty pieces so that the sum of numbers from one piece is equal to the sum of numbers from the other piece. Don't forget that it's allowed to cut the stripe along the squares' borders only.
Demo Input:
['9\n1 5 -6 7 9 -16 0 -2 2\n', '3\n1 1 1\n', '2\n0 0\n']
Demo Output:
['3\n', '0\n', '1\n']
Note:
none
|
```python
n = int(input())
nums = [int(x) for x in input().split()]
leftsum = 0
left = [0 for _ in range(n)]
for x in range(n):
leftsum += nums[x]
left[x] = leftsum
rightsum = 0
right = [0 for _ in range(n)]
for x in range(n - 1, -1, -1):
rightsum += nums[x]
right[x] = rightsum
# print(left)
# print(right)
count = 0
for i in range(n - 1):
if left[i] == right[i + 1]:
count += 1
print(count)
```
| 3.842262
|
514
|
A
|
Chewbaсca and Number
|
PROGRAMMING
| 1,200
|
[
"greedy",
"implementation"
] | null | null |
Luke Skywalker gave Chewbacca an integer number *x*. Chewbacca isn't good at numbers but he loves inverting digits in them. Inverting digit *t* means replacing it with digit 9<=-<=*t*.
Help Chewbacca to transform the initial number *x* to the minimum possible positive number by inverting some (possibly, zero) digits. The decimal representation of the final number shouldn't start with a zero.
|
The first line contains a single integer *x* (1<=≤<=*x*<=≤<=1018) — the number that Luke Skywalker gave to Chewbacca.
|
Print the minimum possible positive number that Chewbacca can obtain after inverting some digits. The number shouldn't contain leading zeroes.
|
[
"27\n",
"4545\n"
] |
[
"22\n",
"4444\n"
] |
none
| 500
|
[
{
"input": "27",
"output": "22"
},
{
"input": "4545",
"output": "4444"
},
{
"input": "1",
"output": "1"
},
{
"input": "9",
"output": "9"
},
{
"input": "8772",
"output": "1222"
},
{
"input": "81",
"output": "11"
},
{
"input": "71723447",
"output": "21223442"
},
{
"input": "91730629",
"output": "91230320"
},
{
"input": "420062703497",
"output": "420032203402"
},
{
"input": "332711047202",
"output": "332211042202"
},
{
"input": "3395184971407775",
"output": "3304114021402224"
},
{
"input": "8464062628894325",
"output": "1434032321104324"
},
{
"input": "164324828731963982",
"output": "134324121231033012"
},
{
"input": "384979173822804784",
"output": "314020123122104214"
},
{
"input": "41312150450968417",
"output": "41312140440031412"
},
{
"input": "2156",
"output": "2143"
},
{
"input": "1932",
"output": "1032"
},
{
"input": "5902",
"output": "4002"
},
{
"input": "5728",
"output": "4221"
},
{
"input": "8537",
"output": "1432"
},
{
"input": "55403857",
"output": "44403142"
},
{
"input": "270739",
"output": "220230"
},
{
"input": "28746918",
"output": "21243011"
},
{
"input": "10279211",
"output": "10220211"
},
{
"input": "40289679",
"output": "40210320"
},
{
"input": "545203238506",
"output": "444203231403"
},
{
"input": "461117063340",
"output": "431112033340"
},
{
"input": "658492686568",
"output": "341402313431"
},
{
"input": "857373361868",
"output": "142323331131"
},
{
"input": "429325660016",
"output": "420324330013"
},
{
"input": "9894448650287940",
"output": "9104441340212040"
},
{
"input": "6354510839296263",
"output": "3344410130203233"
},
{
"input": "6873575462224593",
"output": "3123424432224403"
},
{
"input": "4237951492601449",
"output": "4232041402301440"
},
{
"input": "2680352384836991",
"output": "2310342314133001"
},
{
"input": "606187734191890310",
"output": "303112234101100310"
},
{
"input": "351499943576823355",
"output": "341400043423123344"
},
{
"input": "180593481782177068",
"output": "110403411212122031"
},
{
"input": "999999999999999999",
"output": "900000000000000000"
},
{
"input": "1000000000000000000",
"output": "1000000000000000000"
},
{
"input": "9999",
"output": "9000"
},
{
"input": "99",
"output": "90"
},
{
"input": "9991",
"output": "9001"
}
] | 1,668,140,715
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 3
| 46
| 0
|
def min_number(x):
return min(x,9-x)
number=input()
array = list(number)
array = map(int,array)
array = list(map(min_number,array))
array = map(str,array)
number=int("".join(array))
print(number)
|
Title: Chewbaсca and Number
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Luke Skywalker gave Chewbacca an integer number *x*. Chewbacca isn't good at numbers but he loves inverting digits in them. Inverting digit *t* means replacing it with digit 9<=-<=*t*.
Help Chewbacca to transform the initial number *x* to the minimum possible positive number by inverting some (possibly, zero) digits. The decimal representation of the final number shouldn't start with a zero.
Input Specification:
The first line contains a single integer *x* (1<=≤<=*x*<=≤<=1018) — the number that Luke Skywalker gave to Chewbacca.
Output Specification:
Print the minimum possible positive number that Chewbacca can obtain after inverting some digits. The number shouldn't contain leading zeroes.
Demo Input:
['27\n', '4545\n']
Demo Output:
['22\n', '4444\n']
Note:
none
|
```python
def min_number(x):
return min(x,9-x)
number=input()
array = list(number)
array = map(int,array)
array = list(map(min_number,array))
array = map(str,array)
number=int("".join(array))
print(number)
```
| 0
|
|
877
|
B
|
Nikita and string
|
PROGRAMMING
| 1,500
|
[
"brute force",
"dp"
] | null | null |
One day Nikita found the string containing letters "a" and "b" only.
Nikita thinks that string is beautiful if it can be cut into 3 strings (possibly empty) without changing the order of the letters, where the 1-st and the 3-rd one contain only letters "a" and the 2-nd contains only letters "b".
Nikita wants to make the string beautiful by removing some (possibly none) of its characters, but without changing their order. What is the maximum length of the string he can get?
|
The first line contains a non-empty string of length not greater than 5<=000 containing only lowercase English letters "a" and "b".
|
Print a single integer — the maximum possible size of beautiful string Nikita can get.
|
[
"abba\n",
"bab\n"
] |
[
"4",
"2"
] |
It the first sample the string is already beautiful.
In the second sample he needs to delete one of "b" to make it beautiful.
| 1,000
|
[
{
"input": "abba",
"output": "4"
},
{
"input": "bab",
"output": "2"
},
{
"input": "bbabbbaabbbb",
"output": "9"
},
{
"input": "bbabbbbbaaba",
"output": "10"
},
{
"input": "bbabbbababaa",
"output": "9"
},
{
"input": "aabbaababbab",
"output": "8"
},
{
"input": "a",
"output": "1"
},
{
"input": "b",
"output": "1"
},
{
"input": "ab",
"output": "2"
},
{
"input": "ba",
"output": "2"
},
{
"input": "bb",
"output": "2"
},
{
"input": "aa",
"output": "2"
},
{
"input": "babbbaab",
"output": "6"
},
{
"input": "abaaaa",
"output": "6"
},
{
"input": "aaa",
"output": "3"
}
] | 1,593,282,363
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 2
| 124
| 20,172,800
|
strs = input()
numa = 0
numb = 0
numaa = 0
flag = 0
flaga = 0
flagb = 0
flagaa = 0
maxslen = 0
for i in strs:
if flag == 0 and i == "b":
continue
flag = 1
if flaga == 0 and i == "a":
numa += 1
continue
if flagb == 0 and i == "b":
flaga = 1
numb += 1
continue
if flagaa == 0 and i == "a":
flagb = 1
numaa += 1
continue
maxslen = max(maxslen, numaa + numb + numa)
numa = numaa
numb = 1
flagb = 0
flagaa = 0
numaa = 0
print("maxslen " + str(maxslen) + " Numa " + str(numa) + " numb " + str(numb) + " numaa " + str(numaa) )
maxslen = max(maxslen, numaa + numb + numa)
print(maxslen)
|
Title: Nikita and string
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day Nikita found the string containing letters "a" and "b" only.
Nikita thinks that string is beautiful if it can be cut into 3 strings (possibly empty) without changing the order of the letters, where the 1-st and the 3-rd one contain only letters "a" and the 2-nd contains only letters "b".
Nikita wants to make the string beautiful by removing some (possibly none) of its characters, but without changing their order. What is the maximum length of the string he can get?
Input Specification:
The first line contains a non-empty string of length not greater than 5<=000 containing only lowercase English letters "a" and "b".
Output Specification:
Print a single integer — the maximum possible size of beautiful string Nikita can get.
Demo Input:
['abba\n', 'bab\n']
Demo Output:
['4', '2']
Note:
It the first sample the string is already beautiful.
In the second sample he needs to delete one of "b" to make it beautiful.
|
```python
strs = input()
numa = 0
numb = 0
numaa = 0
flag = 0
flaga = 0
flagb = 0
flagaa = 0
maxslen = 0
for i in strs:
if flag == 0 and i == "b":
continue
flag = 1
if flaga == 0 and i == "a":
numa += 1
continue
if flagb == 0 and i == "b":
flaga = 1
numb += 1
continue
if flagaa == 0 and i == "a":
flagb = 1
numaa += 1
continue
maxslen = max(maxslen, numaa + numb + numa)
numa = numaa
numb = 1
flagb = 0
flagaa = 0
numaa = 0
print("maxslen " + str(maxslen) + " Numa " + str(numa) + " numb " + str(numb) + " numaa " + str(numaa) )
maxslen = max(maxslen, numaa + numb + numa)
print(maxslen)
```
| 0
|
|
676
|
A
|
Nicholas and Permutation
|
PROGRAMMING
| 800
|
[
"constructive algorithms",
"implementation"
] | null | null |
Nicholas has an array *a* that contains *n* distinct integers from 1 to *n*. In other words, Nicholas has a permutation of size *n*.
Nicholas want the minimum element (integer 1) and the maximum element (integer *n*) to be as far as possible from each other. He wants to perform exactly one swap in order to maximize the distance between the minimum and the maximum elements. The distance between two elements is considered to be equal to the absolute difference between their positions.
|
The first line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100) — the size of the permutation.
The second line of the input contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=*n*), where *a**i* is equal to the element at the *i*-th position.
|
Print a single integer — the maximum possible distance between the minimum and the maximum elements Nicholas can achieve by performing exactly one swap.
|
[
"5\n4 5 1 3 2\n",
"7\n1 6 5 3 4 7 2\n",
"6\n6 5 4 3 2 1\n"
] |
[
"3\n",
"6\n",
"5\n"
] |
In the first sample, one may obtain the optimal answer by swapping elements 1 and 2.
In the second sample, the minimum and the maximum elements will be located in the opposite ends of the array if we swap 7 and 2.
In the third sample, the distance between the minimum and the maximum elements is already maximum possible, so we just perform some unnecessary swap, for example, one can swap 5 and 2.
| 500
|
[
{
"input": "5\n4 5 1 3 2",
"output": "3"
},
{
"input": "7\n1 6 5 3 4 7 2",
"output": "6"
},
{
"input": "6\n6 5 4 3 2 1",
"output": "5"
},
{
"input": "2\n1 2",
"output": "1"
},
{
"input": "2\n2 1",
"output": "1"
},
{
"input": "3\n2 3 1",
"output": "2"
},
{
"input": "4\n4 1 3 2",
"output": "3"
},
{
"input": "5\n1 4 5 2 3",
"output": "4"
},
{
"input": "6\n4 6 3 5 2 1",
"output": "5"
},
{
"input": "7\n1 5 3 6 2 4 7",
"output": "6"
},
{
"input": "100\n76 70 67 54 40 1 48 63 64 36 42 90 99 27 47 17 93 7 13 84 16 57 74 5 83 61 19 56 52 92 38 91 82 79 34 66 71 28 37 98 35 94 77 53 73 10 26 80 15 32 8 81 3 95 44 46 72 6 33 11 21 85 4 30 24 51 49 96 87 55 14 31 12 60 45 9 29 22 58 18 88 2 50 59 20 86 23 41 100 39 62 68 69 97 78 43 25 89 65 75",
"output": "94"
},
{
"input": "8\n4 5 3 8 6 7 1 2",
"output": "6"
},
{
"input": "9\n6 8 5 3 4 7 9 2 1",
"output": "8"
},
{
"input": "10\n8 7 10 1 2 3 4 6 5 9",
"output": "7"
},
{
"input": "11\n5 4 6 9 10 11 7 3 1 2 8",
"output": "8"
},
{
"input": "12\n3 6 7 8 9 10 12 5 4 2 11 1",
"output": "11"
},
{
"input": "13\n8 4 3 7 5 11 9 1 10 2 13 12 6",
"output": "10"
},
{
"input": "14\n6 10 13 9 7 1 12 14 3 2 5 4 11 8",
"output": "8"
},
{
"input": "15\n3 14 13 12 7 2 4 11 15 1 8 6 5 10 9",
"output": "9"
},
{
"input": "16\n11 6 9 8 7 14 12 13 10 15 2 5 3 1 4 16",
"output": "15"
},
{
"input": "17\n13 12 5 3 9 16 8 14 2 4 10 1 6 11 7 15 17",
"output": "16"
},
{
"input": "18\n8 6 14 17 9 11 15 13 5 3 18 1 2 7 12 16 4 10",
"output": "11"
},
{
"input": "19\n12 19 3 11 15 6 18 14 5 10 2 13 9 7 4 8 17 16 1",
"output": "18"
},
{
"input": "20\n15 17 10 20 7 2 16 9 13 6 18 5 19 8 11 14 4 12 3 1",
"output": "19"
},
{
"input": "21\n1 9 14 18 13 12 11 20 16 2 4 19 15 7 6 17 8 5 3 10 21",
"output": "20"
},
{
"input": "22\n8 3 17 4 16 21 14 11 10 15 6 18 13 12 22 20 5 2 9 7 19 1",
"output": "21"
},
{
"input": "23\n1 23 11 20 9 3 12 4 7 17 5 15 2 10 18 16 8 22 14 13 19 21 6",
"output": "22"
},
{
"input": "24\n2 10 23 22 20 19 18 16 11 12 15 17 21 8 24 13 1 5 6 7 14 3 9 4",
"output": "16"
},
{
"input": "25\n12 13 22 17 1 18 14 5 21 2 10 4 3 23 11 6 20 8 24 16 15 19 9 7 25",
"output": "24"
},
{
"input": "26\n6 21 20 16 26 17 11 2 24 4 1 12 14 8 25 7 15 10 22 5 13 18 9 23 19 3",
"output": "21"
},
{
"input": "27\n20 14 18 10 5 3 9 4 24 22 21 27 17 15 26 2 23 7 12 11 6 8 19 25 16 13 1",
"output": "26"
},
{
"input": "28\n28 13 16 6 1 12 4 27 22 7 18 3 21 26 25 11 5 10 20 24 19 15 14 8 23 17 9 2",
"output": "27"
},
{
"input": "29\n21 11 10 25 2 5 9 16 29 8 17 4 15 13 6 22 7 24 19 12 18 20 1 3 23 28 27 14 26",
"output": "22"
},
{
"input": "30\n6 19 14 22 26 17 27 8 25 3 24 30 4 18 23 16 9 13 29 20 15 2 5 11 28 12 1 10 21 7",
"output": "26"
},
{
"input": "31\n29 13 26 27 9 28 2 16 30 21 12 11 3 31 23 6 22 20 1 5 14 24 19 18 8 4 10 17 15 25 7",
"output": "18"
},
{
"input": "32\n15 32 11 3 18 23 19 14 5 8 6 21 13 24 25 4 16 9 27 20 17 31 2 22 7 12 30 1 26 10 29 28",
"output": "30"
},
{
"input": "33\n22 13 10 33 8 25 15 14 21 28 27 19 26 24 1 12 5 11 32 20 30 31 18 4 6 23 7 29 16 2 17 9 3",
"output": "29"
},
{
"input": "34\n34 30 7 16 6 1 10 23 29 13 15 25 32 26 18 11 28 3 14 21 19 5 31 33 4 17 8 9 24 20 27 22 2 12",
"output": "33"
},
{
"input": "35\n24 33 20 8 34 11 31 25 2 4 18 13 9 35 16 30 23 32 17 1 14 22 19 21 28 26 3 15 5 12 27 29 10 6 7",
"output": "21"
},
{
"input": "36\n1 32 27 35 22 7 34 15 18 36 31 28 13 2 10 21 20 17 16 4 3 24 19 29 11 12 25 5 33 26 14 6 9 23 30 8",
"output": "35"
},
{
"input": "37\n24 1 12 23 11 6 30 15 4 21 13 20 25 17 5 8 36 19 32 26 14 9 7 18 10 29 37 35 16 2 22 34 3 27 31 33 28",
"output": "35"
},
{
"input": "38\n9 35 37 28 36 21 10 25 19 4 26 5 22 7 27 18 6 14 15 24 1 17 11 34 20 8 2 16 3 23 32 31 13 12 38 33 30 29",
"output": "34"
},
{
"input": "39\n16 28 4 33 26 36 25 23 22 30 27 7 12 34 17 6 3 38 10 24 13 31 29 39 14 32 9 20 35 11 18 21 8 2 15 37 5 19 1",
"output": "38"
},
{
"input": "40\n35 39 28 11 9 31 36 8 5 32 26 19 38 33 2 22 23 25 6 37 12 7 3 10 17 24 20 16 27 4 34 15 40 14 18 13 29 21 30 1",
"output": "39"
},
{
"input": "41\n24 18 7 23 3 15 1 17 25 5 30 10 34 36 2 14 9 21 41 40 20 28 33 35 12 22 11 8 19 16 31 27 26 32 29 4 13 38 37 39 6",
"output": "34"
},
{
"input": "42\n42 15 24 26 4 34 19 29 38 32 31 33 14 41 21 3 11 39 25 6 5 20 23 10 16 36 18 28 27 1 7 40 22 30 9 2 37 17 8 12 13 35",
"output": "41"
},
{
"input": "43\n43 24 20 13 22 29 28 4 30 3 32 40 31 8 7 9 35 27 18 5 42 6 17 19 23 12 41 21 16 37 33 34 2 14 36 38 25 10 15 39 26 11 1",
"output": "42"
},
{
"input": "44\n4 38 6 40 29 3 44 2 30 35 25 36 34 10 11 31 21 7 14 23 37 19 27 18 5 22 1 16 17 9 39 13 15 32 43 8 41 26 42 12 24 33 20 28",
"output": "37"
},
{
"input": "45\n45 29 24 2 31 5 34 41 26 44 33 43 15 3 4 11 21 37 27 12 14 39 23 42 16 6 13 19 8 38 20 9 25 22 40 17 32 35 18 10 28 7 30 36 1",
"output": "44"
},
{
"input": "46\n29 3 12 33 45 40 19 17 25 27 28 1 16 23 24 46 31 8 44 15 5 32 22 11 4 36 34 10 35 26 21 7 14 2 18 9 20 41 6 43 42 37 38 13 39 30",
"output": "34"
},
{
"input": "47\n7 3 8 12 24 16 29 10 28 38 1 20 37 40 21 5 15 6 45 23 36 44 25 43 41 4 11 42 18 35 32 31 39 33 27 30 22 34 14 13 17 47 19 9 46 26 2",
"output": "41"
},
{
"input": "48\n29 26 14 18 34 33 13 39 32 1 37 20 35 19 28 48 30 23 46 27 5 22 24 38 12 15 8 36 43 45 16 47 6 9 31 40 44 17 2 41 11 42 25 4 21 3 10 7",
"output": "38"
},
{
"input": "49\n16 7 42 32 11 35 15 8 23 41 6 20 47 24 9 45 49 2 37 48 25 28 5 18 3 19 12 4 22 33 13 14 10 36 44 17 40 38 30 26 1 43 29 46 21 34 27 39 31",
"output": "40"
},
{
"input": "50\n31 45 3 34 13 43 32 4 42 9 7 8 24 14 35 6 19 46 44 17 18 1 25 20 27 41 2 16 12 10 11 47 38 21 28 49 30 15 50 36 29 26 22 39 48 5 23 37 33 40",
"output": "38"
},
{
"input": "51\n47 29 2 11 43 44 27 1 39 14 25 30 33 21 38 45 34 51 16 50 42 31 41 46 15 48 13 19 6 37 35 7 22 28 20 4 17 10 5 8 24 40 9 36 18 49 12 26 23 3 32",
"output": "43"
},
{
"input": "52\n16 45 23 7 15 19 43 20 4 32 35 36 9 50 5 26 38 46 13 33 12 2 48 37 41 31 10 28 8 42 3 21 11 1 17 27 34 30 44 40 6 51 49 47 25 22 18 24 52 29 14 39",
"output": "48"
},
{
"input": "53\n53 30 50 22 51 31 32 38 12 7 39 43 1 23 6 8 24 52 2 21 34 13 3 35 5 15 19 11 47 18 9 20 29 4 36 45 27 41 25 48 16 46 44 17 10 14 42 26 40 28 33 37 49",
"output": "52"
},
{
"input": "54\n6 39 17 3 45 52 16 21 23 48 42 36 13 37 46 10 43 27 49 7 38 32 31 30 15 25 2 29 8 51 54 19 41 44 24 34 22 5 20 14 12 1 33 40 4 26 9 35 18 28 47 50 11 53",
"output": "41"
},
{
"input": "55\n26 15 31 21 32 43 34 51 7 12 5 44 17 54 18 25 48 47 20 3 41 24 45 2 11 22 29 39 37 53 35 28 36 9 50 10 30 38 19 13 4 8 27 1 42 6 49 23 55 40 33 16 46 14 52",
"output": "48"
},
{
"input": "56\n6 20 38 46 10 11 40 19 5 1 47 33 4 18 32 36 37 45 56 49 48 52 12 26 31 14 2 9 24 3 16 51 41 43 23 17 34 7 29 50 55 25 39 44 22 27 54 8 28 35 30 42 13 53 21 15",
"output": "46"
},
{
"input": "57\n39 28 53 36 3 6 12 56 55 20 50 19 43 42 18 40 24 52 38 17 33 23 22 41 14 7 26 44 45 16 35 1 8 47 31 5 30 51 32 4 37 25 13 34 54 21 46 10 15 11 2 27 29 48 49 9 57",
"output": "56"
},
{
"input": "58\n1 26 28 14 22 33 57 40 9 42 44 37 24 19 58 12 48 3 34 31 49 4 16 47 55 52 27 23 46 18 20 32 56 6 39 36 41 38 13 43 45 21 53 54 29 17 5 10 25 30 2 35 11 7 15 51 8 50",
"output": "57"
},
{
"input": "59\n1 27 10 37 53 9 14 49 46 26 50 42 59 11 47 15 24 56 43 45 44 38 5 8 58 30 52 12 23 32 22 3 31 41 2 25 29 6 54 16 35 33 18 55 4 51 57 28 40 19 13 21 7 39 36 48 34 17 20",
"output": "58"
},
{
"input": "60\n60 27 34 32 54 55 33 12 40 3 47 44 50 39 38 59 11 25 17 15 16 30 21 31 10 52 5 23 4 48 6 26 36 57 14 22 8 56 58 9 24 7 37 53 42 43 20 49 51 19 2 46 28 18 35 13 29 45 41 1",
"output": "59"
},
{
"input": "61\n61 11 26 29 31 40 32 30 35 3 18 52 9 53 42 4 50 54 20 58 28 49 22 12 2 19 16 15 57 34 51 43 7 17 25 41 56 47 55 60 46 14 44 45 24 27 33 1 48 13 59 23 38 39 6 5 36 10 8 37 21",
"output": "60"
},
{
"input": "62\n21 23 34 38 11 61 55 30 37 48 54 51 46 47 6 56 36 49 1 35 12 28 29 20 43 42 5 8 22 57 44 4 53 10 58 33 27 25 16 45 50 40 18 15 3 41 39 2 7 60 59 13 32 24 52 31 14 9 19 26 17 62",
"output": "61"
},
{
"input": "63\n2 5 29 48 31 26 21 16 47 24 43 22 61 28 6 39 60 27 14 52 37 7 53 8 62 56 63 10 50 18 44 13 4 9 25 11 23 42 45 41 59 12 32 36 40 51 1 35 49 54 57 20 19 34 38 46 33 3 55 15 30 58 17",
"output": "46"
},
{
"input": "64\n23 5 51 40 12 46 44 8 64 31 58 55 45 24 54 39 21 19 52 61 30 42 16 18 15 32 53 22 28 26 11 25 48 56 27 9 29 41 35 49 59 38 62 7 34 1 20 33 60 17 2 3 43 37 57 14 6 36 13 10 50 4 63 47",
"output": "55"
},
{
"input": "65\n10 11 55 43 53 25 35 26 16 37 41 38 59 21 48 2 65 49 17 23 18 30 62 36 3 4 47 15 28 63 57 54 31 46 44 12 51 7 29 13 56 52 14 22 39 19 8 27 45 5 6 34 32 61 20 50 9 24 33 58 60 40 1 42 64",
"output": "62"
},
{
"input": "66\n66 39 3 2 55 53 60 54 12 49 10 30 59 26 32 46 50 56 7 13 43 36 24 28 11 8 6 21 35 25 42 57 23 45 64 5 34 61 27 51 52 9 15 1 38 17 63 48 37 20 58 14 47 19 22 41 31 44 33 65 4 62 40 18 16 29",
"output": "65"
},
{
"input": "67\n66 16 2 53 35 38 49 28 18 6 36 58 21 47 27 5 50 62 44 12 52 37 11 56 15 31 25 65 17 29 59 41 7 42 4 43 39 10 1 40 24 13 20 54 19 67 46 60 51 45 64 30 8 33 26 9 3 22 34 23 57 48 55 14 63 61 32",
"output": "45"
},
{
"input": "68\n13 6 27 21 65 23 59 14 62 43 33 31 38 41 67 20 16 25 42 4 28 40 29 9 64 17 2 26 32 58 60 53 46 48 47 54 44 50 39 19 30 57 61 1 11 18 37 24 55 15 63 34 8 52 56 7 10 12 35 66 5 36 45 49 68 22 51 3",
"output": "64"
},
{
"input": "69\n29 49 25 51 21 35 11 61 39 54 40 37 60 42 27 33 59 53 34 10 46 2 23 69 8 47 58 36 1 38 19 12 7 48 13 3 6 22 18 5 65 24 50 41 66 44 67 57 4 56 62 43 9 30 14 15 28 31 64 26 16 55 68 17 32 20 45 52 63",
"output": "45"
},
{
"input": "70\n19 12 15 18 36 16 61 69 24 7 11 13 3 48 55 21 37 17 43 31 41 22 28 32 27 63 38 49 59 56 30 25 67 51 52 45 50 44 66 57 26 60 5 46 33 6 23 34 8 40 2 68 14 39 65 64 62 42 47 54 10 53 9 1 70 58 20 4 29 35",
"output": "64"
},
{
"input": "71\n40 6 62 3 41 52 31 66 27 16 35 5 17 60 2 15 51 22 67 61 71 53 1 64 8 45 28 18 50 30 12 69 20 26 10 37 36 49 70 32 33 11 57 14 9 55 4 58 29 25 44 65 39 48 24 47 19 46 56 38 34 42 59 63 54 23 7 68 43 13 21",
"output": "50"
},
{
"input": "72\n52 64 71 40 32 10 62 21 11 37 38 13 22 70 1 66 41 50 27 20 42 47 25 68 49 12 15 72 44 60 53 5 23 14 43 29 65 36 51 54 35 67 7 19 55 48 58 46 39 24 33 30 61 45 57 2 31 3 18 59 6 9 4 63 8 16 26 34 28 69 17 56",
"output": "57"
},
{
"input": "73\n58 38 47 34 39 64 69 66 72 57 9 4 67 22 35 13 61 14 28 52 56 20 31 70 27 24 36 1 62 17 10 5 12 33 16 73 18 49 63 71 44 65 23 30 40 8 50 46 60 25 11 26 37 55 29 68 42 2 3 32 59 7 15 43 41 48 51 53 6 45 54 19 21",
"output": "45"
},
{
"input": "74\n19 51 59 34 8 40 42 55 65 16 74 26 49 63 64 70 35 72 7 12 43 18 61 27 47 31 13 32 71 22 25 67 9 1 48 50 33 10 21 46 11 45 17 37 28 60 69 66 38 2 30 3 39 15 53 68 57 41 6 36 24 73 4 23 5 62 44 14 20 29 52 54 56 58",
"output": "63"
},
{
"input": "75\n75 28 60 19 59 17 65 26 32 23 18 64 8 62 4 11 42 16 47 5 72 46 9 1 25 21 2 50 33 6 36 68 30 12 20 40 53 45 34 7 37 39 38 44 63 61 67 3 66 51 29 73 24 57 70 27 10 56 22 55 13 49 35 15 54 41 14 74 69 48 52 31 71 43 58",
"output": "74"
},
{
"input": "76\n1 47 54 17 38 37 12 32 14 48 43 71 60 56 4 13 64 41 52 57 62 24 23 49 20 10 63 3 25 66 59 40 58 33 53 46 70 7 35 61 72 74 73 19 30 5 29 6 15 28 21 27 51 55 50 9 65 8 67 39 76 42 31 34 16 2 36 11 26 44 22 45 75 18 69 68",
"output": "75"
},
{
"input": "77\n10 20 57 65 53 69 59 45 58 32 28 72 4 14 1 33 40 47 7 5 51 76 37 16 41 61 42 2 21 26 38 74 35 64 43 77 71 50 39 48 27 63 73 44 52 66 9 18 23 54 25 6 8 56 13 67 36 22 15 46 62 75 55 11 31 17 24 29 60 68 12 30 3 70 49 19 34",
"output": "62"
},
{
"input": "78\n7 61 69 47 68 42 65 78 70 3 32 59 49 51 23 71 11 63 22 18 43 34 24 13 27 16 19 40 21 46 48 77 28 66 54 67 60 15 75 62 9 26 52 58 4 25 8 37 41 76 1 6 30 50 44 36 5 14 29 53 17 12 2 57 73 35 64 39 56 10 33 20 45 74 31 55 38 72",
"output": "70"
},
{
"input": "79\n75 79 43 66 72 52 29 65 74 38 24 1 5 51 13 7 71 33 4 61 2 36 63 47 64 44 34 27 3 21 17 37 54 53 49 20 28 60 39 10 16 76 6 77 73 22 50 48 78 30 67 56 31 26 40 59 41 11 18 45 69 62 15 23 32 70 19 55 68 57 35 25 12 46 14 42 9 8 58",
"output": "77"
},
{
"input": "80\n51 20 37 12 68 11 28 52 76 21 7 5 3 16 64 34 25 2 6 40 60 62 75 13 45 17 56 29 32 47 79 73 49 72 15 46 30 54 80 27 43 24 74 18 42 71 14 4 44 63 65 33 1 77 55 57 41 59 58 70 69 35 19 67 10 36 26 23 48 50 39 61 9 66 38 8 31 22 53 78",
"output": "52"
},
{
"input": "81\n63 22 4 41 43 74 64 39 10 35 20 81 11 28 70 67 53 79 16 61 68 52 27 37 58 9 50 49 18 30 72 47 7 60 78 51 23 48 73 66 44 13 15 57 56 38 1 76 25 45 36 34 42 8 75 26 59 14 71 21 6 77 5 17 2 32 40 54 46 24 29 3 31 19 65 62 33 69 12 80 55",
"output": "69"
},
{
"input": "82\n50 24 17 41 49 18 80 11 79 72 57 31 21 35 2 51 36 66 20 65 38 3 45 32 59 81 28 30 70 55 29 76 73 6 33 39 8 7 19 48 63 1 77 43 4 13 78 54 69 9 40 46 74 82 60 71 16 64 12 14 47 26 44 5 10 75 53 25 27 15 56 42 58 34 23 61 67 62 68 22 37 52",
"output": "53"
},
{
"input": "83\n64 8 58 17 67 46 3 82 23 70 72 16 53 45 13 20 12 48 40 4 6 47 76 60 19 44 30 78 28 22 75 15 25 29 63 74 55 32 14 51 35 31 62 77 27 42 65 71 56 61 66 41 68 49 7 34 2 83 36 5 33 26 37 80 59 50 1 9 54 21 18 24 38 73 81 52 10 39 43 79 57 11 69",
"output": "66"
},
{
"input": "84\n75 8 66 21 61 63 72 51 52 13 59 25 28 58 64 53 79 41 34 7 67 11 39 56 44 24 50 9 49 55 1 80 26 6 73 74 27 69 65 37 18 43 36 17 30 3 47 29 76 78 32 22 12 68 46 5 42 81 57 31 33 83 54 48 14 62 10 16 4 20 71 70 35 15 45 19 60 77 2 23 84 40 82 38",
"output": "80"
},
{
"input": "85\n1 18 58 8 22 76 3 61 12 33 54 41 6 24 82 15 10 17 38 64 26 4 62 28 47 14 66 9 84 75 2 71 67 43 37 32 85 21 69 52 55 63 81 51 74 59 65 34 29 36 30 45 27 53 13 79 39 57 5 70 19 40 7 42 68 48 16 80 83 23 46 35 72 31 11 44 73 77 50 56 49 25 60 20 78",
"output": "84"
},
{
"input": "86\n64 56 41 10 31 69 47 39 37 36 27 19 9 42 15 6 78 59 52 17 71 45 72 14 2 54 38 79 4 18 16 8 46 75 50 82 44 24 20 55 58 86 61 43 35 32 33 40 63 30 28 60 13 53 12 57 77 81 76 66 73 84 85 62 68 22 51 5 49 7 1 70 80 65 34 48 23 21 83 11 74 26 29 67 25 3",
"output": "70"
},
{
"input": "87\n14 20 82 47 39 75 71 45 3 37 63 19 32 68 7 41 48 76 27 46 84 49 4 44 26 69 17 64 1 18 58 33 11 23 21 86 67 52 70 16 77 78 6 74 15 87 10 59 13 34 22 2 65 38 66 61 51 57 35 60 81 40 36 80 31 43 83 56 79 55 29 5 12 8 50 30 53 72 54 9 24 25 42 62 73 28 85",
"output": "58"
},
{
"input": "88\n1 83 73 46 61 31 39 86 57 43 16 29 26 80 82 7 36 42 13 20 6 64 19 40 24 12 47 87 8 34 75 9 69 3 11 52 14 25 84 59 27 10 54 51 81 74 65 77 70 17 60 35 23 44 49 2 4 88 5 21 41 32 68 66 15 55 48 58 78 53 22 38 45 33 30 50 85 76 37 79 63 18 28 62 72 56 71 67",
"output": "87"
},
{
"input": "89\n68 40 14 58 56 25 8 44 49 55 9 76 66 54 33 81 42 15 59 17 21 30 75 60 4 48 64 6 52 63 61 27 12 57 72 67 23 86 77 80 22 13 43 73 26 78 50 51 18 62 1 29 82 16 74 2 87 24 3 41 11 46 47 69 10 84 65 39 35 79 70 32 34 31 20 19 53 71 36 28 83 88 38 85 7 5 37 45 89",
"output": "88"
},
{
"input": "90\n2 67 26 58 9 49 76 22 60 30 77 20 13 7 37 81 47 16 19 12 14 45 41 68 85 54 28 24 46 1 27 43 32 89 53 35 59 75 18 51 17 64 66 80 31 88 87 90 38 72 55 71 42 11 73 69 62 78 23 74 65 79 84 4 86 52 10 6 3 82 56 5 48 33 21 57 40 29 61 63 34 36 83 8 15 44 50 70 39 25",
"output": "60"
},
{
"input": "91\n91 69 56 16 73 55 14 82 80 46 57 81 22 71 63 76 43 37 77 75 70 3 26 2 28 17 51 38 30 67 41 47 54 62 34 25 84 11 87 39 32 52 31 36 50 19 21 53 29 24 79 8 74 64 44 7 6 18 10 42 13 9 83 58 4 88 65 60 20 90 66 49 86 89 78 48 5 27 23 59 61 15 72 45 40 33 68 85 35 12 1",
"output": "90"
},
{
"input": "92\n67 57 76 78 25 89 6 82 11 16 26 17 59 48 73 10 21 31 27 80 4 5 22 13 92 55 45 85 63 28 75 60 54 88 91 47 29 35 7 87 1 39 43 51 71 84 83 81 46 9 38 56 90 24 37 41 19 86 50 61 79 20 18 14 69 23 62 65 49 52 58 53 36 2 68 64 15 42 30 34 66 32 44 40 8 33 3 77 74 12 70 72",
"output": "67"
},
{
"input": "93\n76 35 5 87 7 21 59 71 24 37 2 73 31 74 4 52 28 20 56 27 65 86 16 45 85 67 68 70 47 72 91 88 14 32 62 69 78 41 15 22 57 18 50 13 39 58 17 83 64 51 25 11 38 77 82 90 8 26 29 61 10 43 79 53 48 6 23 55 63 49 81 92 80 44 89 60 66 30 1 9 36 33 19 46 75 93 3 12 42 84 40 54 34",
"output": "85"
},
{
"input": "94\n29 85 82 78 61 83 80 63 11 38 50 43 9 24 4 87 79 45 3 17 90 7 34 27 1 76 26 39 84 47 22 41 81 19 44 23 56 92 35 31 72 62 70 53 40 88 13 14 73 2 59 86 46 94 15 12 77 57 89 42 75 48 18 51 32 55 71 30 49 91 20 60 5 93 33 64 21 36 10 28 8 65 66 69 74 58 6 52 25 67 16 37 54 68",
"output": "69"
},
{
"input": "95\n36 73 18 77 15 71 50 57 79 65 94 88 9 69 52 70 26 66 78 89 55 20 72 83 75 68 32 28 45 74 19 22 54 23 84 90 86 12 42 58 11 81 39 31 85 47 60 44 59 43 21 7 30 41 64 76 93 46 87 48 10 40 3 14 38 49 29 35 2 67 5 34 13 37 27 56 91 17 62 80 8 61 53 95 24 92 6 82 63 33 51 25 4 16 1",
"output": "94"
},
{
"input": "96\n64 3 47 83 19 10 72 61 73 95 16 40 54 84 8 86 28 4 37 42 92 48 63 76 67 1 59 66 20 35 93 2 43 7 45 70 34 33 26 91 85 89 13 29 58 68 44 25 87 75 49 71 41 17 55 36 32 31 74 22 52 79 30 88 50 78 38 39 65 27 69 77 81 94 82 53 21 80 57 60 24 46 51 9 18 15 96 62 6 23 11 12 90 5 14 56",
"output": "86"
},
{
"input": "97\n40 63 44 64 84 92 38 41 28 91 3 70 76 67 94 96 35 79 29 22 78 88 85 8 21 1 93 54 71 80 37 17 13 26 62 59 75 87 69 33 89 49 77 61 12 39 6 36 58 18 73 50 82 45 74 52 11 34 95 7 23 30 15 32 31 16 55 19 20 83 60 72 10 53 51 14 27 9 68 47 5 2 81 46 57 86 56 43 48 66 24 25 4 42 65 97 90",
"output": "95"
},
{
"input": "98\n85 94 69 86 22 52 27 79 53 91 35 55 33 88 8 75 76 95 64 54 67 30 70 49 6 16 2 48 80 32 25 90 98 46 9 96 36 81 10 92 28 11 37 97 15 41 38 40 83 44 29 47 23 3 31 61 87 39 78 20 68 12 17 73 59 18 77 72 43 51 84 24 89 65 26 7 74 93 21 19 5 14 50 42 82 71 60 56 34 62 58 57 45 66 13 63 4 1",
"output": "97"
},
{
"input": "99\n33 48 19 41 59 64 16 12 17 13 7 1 9 6 4 92 61 49 60 25 74 65 22 97 30 32 10 62 14 55 80 66 82 78 31 23 87 93 27 98 20 29 88 84 77 34 83 96 79 90 56 89 58 72 52 47 21 76 24 70 44 94 5 39 8 18 57 36 40 68 43 75 3 2 35 99 63 26 67 73 15 11 53 28 42 46 69 50 51 95 38 37 54 85 81 91 45 86 71",
"output": "87"
},
{
"input": "100\n28 30 77 4 81 67 31 25 66 56 88 73 83 51 57 34 21 90 38 76 22 99 53 70 91 3 64 54 6 94 8 5 97 80 50 45 61 40 16 95 36 98 9 2 17 44 72 55 18 58 47 12 87 24 7 32 14 23 65 41 63 48 62 39 92 27 43 19 46 13 42 52 96 84 26 69 100 79 93 49 35 60 71 59 68 15 10 29 20 1 78 33 75 86 11 85 74 82 89 37",
"output": "89"
},
{
"input": "100\n100 97 35 55 45 3 46 98 77 64 94 85 73 43 49 79 72 9 70 62 80 88 29 58 61 20 89 83 66 86 82 15 6 87 42 96 90 75 63 38 81 40 5 23 4 18 41 19 99 60 8 12 76 51 39 93 53 26 21 50 47 28 13 30 68 59 34 54 24 56 31 27 65 16 32 10 36 52 44 91 22 14 33 25 7 78 67 17 57 37 92 11 2 69 84 95 74 71 48 1",
"output": "99"
},
{
"input": "100\n83 96 73 70 30 25 7 77 58 89 76 85 49 82 45 51 14 62 50 9 31 32 16 15 97 64 4 37 20 93 24 10 80 71 100 39 75 72 78 74 8 29 53 86 79 48 3 68 90 99 56 87 63 94 36 1 40 65 6 44 43 84 17 52 34 95 38 47 60 57 98 59 33 41 46 81 23 27 19 2 54 91 55 35 26 12 92 18 28 66 69 21 5 67 13 11 22 88 61 42",
"output": "65"
},
{
"input": "100\n96 80 47 60 56 9 78 20 37 72 68 15 100 94 51 26 65 38 50 19 4 70 25 63 22 30 13 58 43 69 18 33 5 66 39 73 12 55 95 92 97 1 14 83 10 28 64 31 46 91 32 86 74 54 29 52 89 53 90 44 62 40 16 24 67 81 36 34 7 23 79 87 75 98 84 3 41 77 76 42 71 35 49 61 2 27 59 82 99 85 21 11 45 6 88 48 17 57 8 93",
"output": "87"
},
{
"input": "100\n5 6 88 37 97 51 25 81 54 17 57 98 99 44 67 24 30 93 100 36 8 38 84 42 21 4 75 31 85 48 70 77 43 50 65 94 29 32 68 86 56 39 69 47 20 60 52 53 10 34 79 2 95 40 89 64 71 26 22 46 1 62 91 76 83 41 9 78 16 63 13 3 28 92 27 49 7 12 96 72 80 23 14 19 18 66 59 87 90 45 73 82 33 74 35 61 55 15 58 11",
"output": "81"
},
{
"input": "100\n100 97 92 12 62 17 19 58 37 26 30 95 31 35 87 10 13 43 98 61 28 89 76 1 23 21 11 22 50 56 91 74 3 24 96 55 64 67 14 4 71 16 18 9 77 68 51 81 32 82 46 88 86 60 29 66 72 85 70 7 53 63 33 45 83 2 25 94 52 93 5 69 20 47 49 54 57 39 34 27 90 80 78 59 40 42 79 6 38 8 48 15 65 73 99 44 41 84 36 75",
"output": "99"
},
{
"input": "100\n22 47 34 65 69 5 68 78 53 54 41 23 80 51 11 8 2 85 81 75 25 58 29 73 30 49 10 71 17 96 76 89 79 20 12 15 55 7 46 32 19 3 82 35 74 44 38 40 92 14 6 50 97 63 45 93 37 18 62 77 87 36 83 9 90 61 57 28 39 43 52 42 24 56 21 84 26 99 88 59 33 70 4 60 98 95 94 100 13 48 66 72 16 31 64 91 1 86 27 67",
"output": "96"
},
{
"input": "100\n41 67 94 18 14 83 59 12 19 54 13 68 75 26 15 65 80 40 23 30 34 78 47 21 63 79 4 70 3 31 86 69 92 10 61 74 97 100 9 99 32 27 91 55 85 52 16 17 28 1 64 29 58 76 98 25 84 7 2 96 20 72 36 46 49 82 93 44 45 6 38 87 57 50 53 35 60 33 8 89 39 42 37 48 62 81 73 43 95 11 66 88 90 22 24 77 71 51 5 56",
"output": "62"
},
{
"input": "100\n1 88 38 56 62 99 39 80 12 33 57 24 28 84 37 42 10 95 83 58 8 40 20 2 30 78 60 79 36 71 51 31 27 65 22 47 6 19 61 94 75 4 74 35 15 23 92 9 70 13 11 59 90 18 66 81 64 72 16 32 34 67 46 91 21 87 77 97 82 41 7 86 26 43 45 3 93 17 52 96 50 63 48 5 53 44 29 25 98 54 49 14 73 69 89 55 76 85 68 100",
"output": "99"
},
{
"input": "100\n22 59 25 77 68 79 32 45 20 28 61 60 38 86 33 10 100 15 53 75 78 39 67 13 66 34 96 4 63 23 73 29 31 35 71 55 16 14 72 56 94 97 17 93 47 84 57 8 21 51 54 85 26 76 49 81 2 92 62 44 91 87 11 24 95 69 5 7 99 6 65 48 70 12 41 18 74 27 42 3 80 30 50 98 58 37 82 89 83 36 40 52 19 9 88 46 43 1 90 64",
"output": "97"
},
{
"input": "100\n12 1 76 78 97 82 59 80 48 8 91 51 54 74 16 10 89 99 83 63 93 90 55 25 30 33 29 6 9 65 92 79 44 39 15 58 37 46 32 19 27 3 75 49 62 71 98 42 69 50 26 81 96 5 7 61 60 21 20 36 18 34 40 4 47 85 64 38 22 84 2 68 11 56 31 66 17 14 95 43 53 35 23 52 70 13 72 45 41 77 73 87 88 94 28 86 24 67 100 57",
"output": "98"
},
{
"input": "100\n66 100 53 88 7 73 54 41 31 42 8 46 65 90 78 14 94 30 79 39 89 5 83 50 38 61 37 86 22 95 60 98 34 57 91 10 75 25 15 43 23 17 96 35 93 48 87 47 56 13 19 9 82 62 67 80 11 55 99 70 18 26 58 85 12 44 16 45 4 49 20 71 92 24 81 2 76 32 6 21 84 36 52 97 59 63 40 51 27 64 68 3 77 72 28 33 29 1 74 69",
"output": "98"
},
{
"input": "100\n56 64 1 95 72 39 9 49 87 29 94 7 32 6 30 48 50 25 31 78 90 45 60 44 80 68 17 20 73 15 75 98 83 13 71 22 36 26 96 88 35 3 85 54 16 41 92 99 69 86 93 33 43 62 77 46 47 37 12 10 18 40 27 4 63 55 28 59 23 34 61 53 76 42 51 91 21 70 8 58 38 19 5 66 84 11 52 24 81 82 79 67 97 65 57 74 2 89 100 14",
"output": "98"
},
{
"input": "3\n1 2 3",
"output": "2"
},
{
"input": "3\n1 3 2",
"output": "2"
},
{
"input": "3\n2 1 3",
"output": "2"
},
{
"input": "3\n2 3 1",
"output": "2"
},
{
"input": "3\n3 1 2",
"output": "2"
},
{
"input": "3\n3 2 1",
"output": "2"
},
{
"input": "4\n1 2 3 4",
"output": "3"
},
{
"input": "4\n1 2 4 3",
"output": "3"
},
{
"input": "4\n1 3 2 4",
"output": "3"
},
{
"input": "4\n1 3 4 2",
"output": "3"
},
{
"input": "4\n1 4 2 3",
"output": "3"
},
{
"input": "4\n1 4 3 2",
"output": "3"
},
{
"input": "4\n2 1 3 4",
"output": "3"
},
{
"input": "4\n2 1 4 3",
"output": "2"
},
{
"input": "4\n2 4 1 3",
"output": "2"
},
{
"input": "4\n2 4 3 1",
"output": "3"
},
{
"input": "4\n3 1 2 4",
"output": "3"
},
{
"input": "4\n3 1 4 2",
"output": "2"
},
{
"input": "4\n3 2 1 4",
"output": "3"
},
{
"input": "4\n3 2 4 1",
"output": "3"
},
{
"input": "4\n3 4 1 2",
"output": "2"
},
{
"input": "4\n3 4 2 1",
"output": "3"
},
{
"input": "4\n4 1 2 3",
"output": "3"
},
{
"input": "4\n4 1 3 2",
"output": "3"
},
{
"input": "4\n4 2 1 3",
"output": "3"
},
{
"input": "4\n4 2 3 1",
"output": "3"
},
{
"input": "4\n4 3 1 2",
"output": "3"
},
{
"input": "4\n4 3 2 1",
"output": "3"
},
{
"input": "8\n2 5 6 4 8 3 1 7",
"output": "6"
},
{
"input": "5\n2 3 1 5 4",
"output": "3"
},
{
"input": "6\n2 5 3 6 4 1",
"output": "5"
},
{
"input": "6\n5 4 2 6 1 3",
"output": "4"
},
{
"input": "6\n4 2 3 1 6 5",
"output": "4"
},
{
"input": "6\n5 4 2 1 6 3",
"output": "4"
},
{
"input": "9\n7 2 3 4 5 6 1 9 8",
"output": "7"
},
{
"input": "6\n3 2 1 4 6 5",
"output": "4"
},
{
"input": "6\n2 3 4 1 6 5",
"output": "4"
},
{
"input": "10\n5 2 3 4 1 6 7 8 10 9",
"output": "8"
},
{
"input": "6\n5 2 3 1 6 4",
"output": "4"
},
{
"input": "10\n2 9 3 4 1 10 5 6 7 8",
"output": "5"
},
{
"input": "10\n2 3 4 5 6 7 1 8 10 9",
"output": "8"
},
{
"input": "8\n2 3 4 5 1 6 8 7",
"output": "6"
},
{
"input": "6\n2 1 3 4 5 6",
"output": "5"
}
] | 1,583,963,878
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 159
| 124
| 307,200
|
n = int(input())
l = list(map(int,input().split()))
x = max(l)
y = min(l)
c = 0
t1=0
t2=0
for i in range(n):
if(x==l[i]):
t1 = i
for i in range(n):
if(y==l[i]):
t2 = i
p = [0]*7
p[1] = t1-t2
p[2]= t1- 0
p[3]= n-1-t1
p[4] = t2-t1
p[5] = n-1-t2
p[6] = t2-0
print(max(p))
|
Title: Nicholas and Permutation
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Nicholas has an array *a* that contains *n* distinct integers from 1 to *n*. In other words, Nicholas has a permutation of size *n*.
Nicholas want the minimum element (integer 1) and the maximum element (integer *n*) to be as far as possible from each other. He wants to perform exactly one swap in order to maximize the distance between the minimum and the maximum elements. The distance between two elements is considered to be equal to the absolute difference between their positions.
Input Specification:
The first line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100) — the size of the permutation.
The second line of the input contains *n* distinct integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=*n*), where *a**i* is equal to the element at the *i*-th position.
Output Specification:
Print a single integer — the maximum possible distance between the minimum and the maximum elements Nicholas can achieve by performing exactly one swap.
Demo Input:
['5\n4 5 1 3 2\n', '7\n1 6 5 3 4 7 2\n', '6\n6 5 4 3 2 1\n']
Demo Output:
['3\n', '6\n', '5\n']
Note:
In the first sample, one may obtain the optimal answer by swapping elements 1 and 2.
In the second sample, the minimum and the maximum elements will be located in the opposite ends of the array if we swap 7 and 2.
In the third sample, the distance between the minimum and the maximum elements is already maximum possible, so we just perform some unnecessary swap, for example, one can swap 5 and 2.
|
```python
n = int(input())
l = list(map(int,input().split()))
x = max(l)
y = min(l)
c = 0
t1=0
t2=0
for i in range(n):
if(x==l[i]):
t1 = i
for i in range(n):
if(y==l[i]):
t2 = i
p = [0]*7
p[1] = t1-t2
p[2]= t1- 0
p[3]= n-1-t1
p[4] = t2-t1
p[5] = n-1-t2
p[6] = t2-0
print(max(p))
```
| 3
|
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Today on a lecture about strings Gerald learned a new definition of string equivalency. Two strings *a* and *b* of equal length are called equivalent in one of the two cases:
1. They are equal. 1. If we split string *a* into two halves of the same size *a*1 and *a*2, and string *b* into two halves of the same size *b*1 and *b*2, then one of the following is correct: *a*1 is equivalent to *b*1, and *a*2 is equivalent to *b*2 1. *a*1 is equivalent to *b*2, and *a*2 is equivalent to *b*1
As a home task, the teacher gave two strings to his students and asked to determine if they are equivalent.
Gerald has already completed this home task. Now it's your turn!
|
The first two lines of the input contain two strings given by the teacher. Each of them has the length from 1 to 200<=000 and consists of lowercase English letters. The strings have the same length.
|
Print "YES" (without the quotes), if these two strings are equivalent, and "NO" (without the quotes) otherwise.
|
[
"aaba\nabaa\n",
"aabb\nabab\n"
] |
[
"YES\n",
"NO\n"
] |
In the first sample you should split the first string into strings "aa" and "ba", the second one — into strings "ab" and "aa". "aa" is equivalent to "aa"; "ab" is equivalent to "ba" as "ab" = "a" + "b", "ba" = "b" + "a".
In the second sample the first string can be splitted into strings "aa" and "bb", that are equivalent only to themselves. That's why string "aabb" is equivalent only to itself and to string "bbaa".
| 0
|
[
{
"input": "aaba\nabaa",
"output": "YES"
},
{
"input": "aabb\nabab",
"output": "NO"
},
{
"input": "a\na",
"output": "YES"
},
{
"input": "a\nb",
"output": "NO"
},
{
"input": "ab\nab",
"output": "YES"
},
{
"input": "ab\nba",
"output": "YES"
},
{
"input": "ab\nbb",
"output": "NO"
},
{
"input": "zzaa\naazz",
"output": "YES"
},
{
"input": "azza\nzaaz",
"output": "YES"
},
{
"input": "abc\nabc",
"output": "YES"
},
{
"input": "abc\nacb",
"output": "NO"
},
{
"input": "azzz\nzzaz",
"output": "YES"
},
{
"input": "abcd\ndcab",
"output": "YES"
},
{
"input": "abcd\ncdab",
"output": "YES"
},
{
"input": "abcd\ndcba",
"output": "YES"
},
{
"input": "abcd\nacbd",
"output": "NO"
},
{
"input": "oloaxgddgujq\noloaxgujqddg",
"output": "YES"
},
{
"input": "uwzwdxfmosmqatyv\ndxfmzwwusomqvyta",
"output": "YES"
},
{
"input": "hagnzomowtledfdotnll\nledfdotnllomowthagnz",
"output": "YES"
},
{
"input": "snyaydaeobufdg\nsnyaydaeobufdg",
"output": "YES"
},
{
"input": "baaaaa\nabaaaa",
"output": "NO"
},
{
"input": "hhiisug\nmzdjwju",
"output": "NO"
},
{
"input": "bbbabbabaaab\naaaabbabbbbb",
"output": "NO"
},
{
"input": "bbaaab\naababb",
"output": "NO"
},
{
"input": "aabbaaaa\naaaaabab",
"output": "NO"
},
{
"input": "aab\naba",
"output": "NO"
},
{
"input": "abcddd\nbacddd",
"output": "NO"
},
{
"input": "qgiufelsfhanx\naaaaaaaaaaaaa",
"output": "NO"
},
{
"input": "aabaababaaba\naababaaababa",
"output": "NO"
},
{
"input": "nocdqzdriyyil\naaaaaaaaaaaaa",
"output": "NO"
},
{
"input": "zdmctxl\nkojqhgw",
"output": "NO"
},
{
"input": "yhwepqwyhwepqwyhwepqweahnqtueahnqtueahnqtuyhwepqwyhwepqwyhwepqwyhwepqweahnqtueahnqtuyhwepqweahnqtueahnqtueahnqtueahnqtueahnqtueahnqtu\neahnqtueahnqtueahnqtuyhwepqweahnqtuyhwepqwyhwepqweahnqtuyhwepqweahnqtuyhwepqweahnqtueahnqtuyhwepqweahnqtueahnqtuyhwepqwyhwepqwyhwepqw",
"output": "NO"
},
{
"input": "abc\nbac",
"output": "NO"
},
{
"input": "ottceez\npcstdvz",
"output": "NO"
}
] | 1,619,395,743
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 104
| 295
| 10,649,600
|
def comparadorDePalavras(palavra1, palavra2):
if(palavra1 == palavra2):
return True
if(len(palavra1) != len(palavra2)):
return False
if(len(palavra1) % 2 == 1):
return False
metade = len(palavra1)//2
palavra1_1 = palavra1[:metade]
palavra2_1 = palavra2[:metade]
palavra1_2 = palavra1[metade:]
palavra2_2 = palavra2[metade:]
return (comparadorDePalavras(palavra1_1, palavra2_2) and comparadorDePalavras(palavra1_2, palavra2_1)) or (comparadorDePalavras(palavra1_1, palavra2_1) and comparadorDePalavras(palavra1_2, palavra2_2))
palavra1 = input()
palavra2 = input()
if (comparadorDePalavras(palavra1, palavra2)):
print('YES')
else:
print('NO')
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Today on a lecture about strings Gerald learned a new definition of string equivalency. Two strings *a* and *b* of equal length are called equivalent in one of the two cases:
1. They are equal. 1. If we split string *a* into two halves of the same size *a*1 and *a*2, and string *b* into two halves of the same size *b*1 and *b*2, then one of the following is correct: *a*1 is equivalent to *b*1, and *a*2 is equivalent to *b*2 1. *a*1 is equivalent to *b*2, and *a*2 is equivalent to *b*1
As a home task, the teacher gave two strings to his students and asked to determine if they are equivalent.
Gerald has already completed this home task. Now it's your turn!
Input Specification:
The first two lines of the input contain two strings given by the teacher. Each of them has the length from 1 to 200<=000 and consists of lowercase English letters. The strings have the same length.
Output Specification:
Print "YES" (without the quotes), if these two strings are equivalent, and "NO" (without the quotes) otherwise.
Demo Input:
['aaba\nabaa\n', 'aabb\nabab\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first sample you should split the first string into strings "aa" and "ba", the second one — into strings "ab" and "aa". "aa" is equivalent to "aa"; "ab" is equivalent to "ba" as "ab" = "a" + "b", "ba" = "b" + "a".
In the second sample the first string can be splitted into strings "aa" and "bb", that are equivalent only to themselves. That's why string "aabb" is equivalent only to itself and to string "bbaa".
|
```python
def comparadorDePalavras(palavra1, palavra2):
if(palavra1 == palavra2):
return True
if(len(palavra1) != len(palavra2)):
return False
if(len(palavra1) % 2 == 1):
return False
metade = len(palavra1)//2
palavra1_1 = palavra1[:metade]
palavra2_1 = palavra2[:metade]
palavra1_2 = palavra1[metade:]
palavra2_2 = palavra2[metade:]
return (comparadorDePalavras(palavra1_1, palavra2_2) and comparadorDePalavras(palavra1_2, palavra2_1)) or (comparadorDePalavras(palavra1_1, palavra2_1) and comparadorDePalavras(palavra1_2, palavra2_2))
palavra1 = input()
palavra2 = input()
if (comparadorDePalavras(palavra1, palavra2)):
print('YES')
else:
print('NO')
```
| 3
|
|
691
|
B
|
s-palindrome
|
PROGRAMMING
| 1,600
|
[
"implementation",
"strings"
] | null | null |
Let's call a string "s-palindrome" if it is symmetric about the middle of the string. For example, the string "oHo" is "s-palindrome", but the string "aa" is not. The string "aa" is not "s-palindrome", because the second half of it is not a mirror reflection of the first half.
You are given a string *s*. Check if the string is "s-palindrome".
|
The only line contains the string *s* (1<=≤<=|*s*|<=≤<=1000) which consists of only English letters.
|
Print "TAK" if the string *s* is "s-palindrome" and "NIE" otherwise.
|
[
"oXoxoXo\n",
"bod\n",
"ER\n"
] |
[
"TAK\n",
"TAK\n",
"NIE\n"
] |
none
| 0
|
[
{
"input": "oXoxoXo",
"output": "TAK"
},
{
"input": "bod",
"output": "TAK"
},
{
"input": "ER",
"output": "NIE"
},
{
"input": "o",
"output": "TAK"
},
{
"input": "a",
"output": "NIE"
},
{
"input": "opo",
"output": "NIE"
},
{
"input": "HCMoxkgbNb",
"output": "NIE"
},
{
"input": "vMhhXCMWDe",
"output": "NIE"
},
{
"input": "iIcamjTRFH",
"output": "NIE"
},
{
"input": "WvoWvvWovW",
"output": "TAK"
},
{
"input": "WXxAdbAxXW",
"output": "TAK"
},
{
"input": "vqMTUUTMpv",
"output": "TAK"
},
{
"input": "iii",
"output": "NIE"
},
{
"input": "AAWW",
"output": "NIE"
},
{
"input": "ss",
"output": "NIE"
},
{
"input": "i",
"output": "NIE"
},
{
"input": "ii",
"output": "NIE"
},
{
"input": "mm",
"output": "NIE"
},
{
"input": "LJ",
"output": "NIE"
},
{
"input": "m",
"output": "NIE"
},
{
"input": "ioi",
"output": "NIE"
},
{
"input": "OA",
"output": "NIE"
},
{
"input": "aaaiaaa",
"output": "NIE"
},
{
"input": "SS",
"output": "NIE"
},
{
"input": "iiii",
"output": "NIE"
},
{
"input": "ssops",
"output": "NIE"
},
{
"input": "ssss",
"output": "NIE"
},
{
"input": "ll",
"output": "NIE"
},
{
"input": "s",
"output": "NIE"
},
{
"input": "bb",
"output": "NIE"
},
{
"input": "uu",
"output": "NIE"
},
{
"input": "ZoZ",
"output": "NIE"
},
{
"input": "mom",
"output": "NIE"
},
{
"input": "uou",
"output": "NIE"
},
{
"input": "u",
"output": "NIE"
},
{
"input": "JL",
"output": "NIE"
},
{
"input": "mOm",
"output": "NIE"
},
{
"input": "llll",
"output": "NIE"
},
{
"input": "ouo",
"output": "NIE"
},
{
"input": "aa",
"output": "NIE"
},
{
"input": "olo",
"output": "NIE"
},
{
"input": "S",
"output": "NIE"
},
{
"input": "lAl",
"output": "NIE"
},
{
"input": "nnnn",
"output": "NIE"
},
{
"input": "ZzZ",
"output": "NIE"
},
{
"input": "bNd",
"output": "NIE"
},
{
"input": "ZZ",
"output": "NIE"
},
{
"input": "oNoNo",
"output": "NIE"
},
{
"input": "l",
"output": "NIE"
},
{
"input": "zz",
"output": "NIE"
},
{
"input": "NON",
"output": "NIE"
},
{
"input": "nn",
"output": "NIE"
},
{
"input": "NoN",
"output": "NIE"
},
{
"input": "sos",
"output": "NIE"
},
{
"input": "lol",
"output": "NIE"
},
{
"input": "mmm",
"output": "NIE"
},
{
"input": "YAiAY",
"output": "NIE"
},
{
"input": "ipIqi",
"output": "NIE"
},
{
"input": "AAA",
"output": "TAK"
},
{
"input": "uoOou",
"output": "NIE"
},
{
"input": "SOS",
"output": "NIE"
},
{
"input": "NN",
"output": "NIE"
},
{
"input": "n",
"output": "NIE"
},
{
"input": "h",
"output": "NIE"
},
{
"input": "blld",
"output": "NIE"
},
{
"input": "ipOqi",
"output": "NIE"
},
{
"input": "pop",
"output": "NIE"
},
{
"input": "BB",
"output": "NIE"
},
{
"input": "OuO",
"output": "NIE"
},
{
"input": "lxl",
"output": "NIE"
},
{
"input": "Z",
"output": "NIE"
},
{
"input": "vvivv",
"output": "NIE"
},
{
"input": "nnnnnnnnnnnnn",
"output": "NIE"
},
{
"input": "AA",
"output": "TAK"
},
{
"input": "t",
"output": "NIE"
},
{
"input": "z",
"output": "NIE"
},
{
"input": "mmmAmmm",
"output": "NIE"
},
{
"input": "qlililp",
"output": "NIE"
},
{
"input": "mpOqm",
"output": "NIE"
},
{
"input": "iiiiiiiiii",
"output": "NIE"
},
{
"input": "BAAAB",
"output": "NIE"
},
{
"input": "UA",
"output": "NIE"
},
{
"input": "mmmmmmm",
"output": "NIE"
},
{
"input": "NpOqN",
"output": "NIE"
},
{
"input": "uOu",
"output": "NIE"
},
{
"input": "uuu",
"output": "NIE"
},
{
"input": "NAMAN",
"output": "NIE"
},
{
"input": "lllll",
"output": "NIE"
},
{
"input": "T",
"output": "TAK"
},
{
"input": "mmmmmmmmmmmmmmmm",
"output": "NIE"
},
{
"input": "AiiA",
"output": "NIE"
},
{
"input": "iOi",
"output": "NIE"
},
{
"input": "lll",
"output": "NIE"
},
{
"input": "N",
"output": "NIE"
},
{
"input": "viv",
"output": "NIE"
},
{
"input": "oiio",
"output": "NIE"
},
{
"input": "AiiiA",
"output": "NIE"
},
{
"input": "NNNN",
"output": "NIE"
},
{
"input": "ixi",
"output": "NIE"
},
{
"input": "AuuA",
"output": "NIE"
},
{
"input": "AAAANANAAAA",
"output": "NIE"
},
{
"input": "mmmmm",
"output": "NIE"
},
{
"input": "oYo",
"output": "TAK"
},
{
"input": "dd",
"output": "NIE"
},
{
"input": "A",
"output": "TAK"
},
{
"input": "ioh",
"output": "NIE"
},
{
"input": "mmmm",
"output": "NIE"
},
{
"input": "uuuu",
"output": "NIE"
},
{
"input": "puq",
"output": "NIE"
},
{
"input": "rrrrrr",
"output": "NIE"
},
{
"input": "c",
"output": "NIE"
},
{
"input": "AbpA",
"output": "NIE"
},
{
"input": "qAq",
"output": "NIE"
},
{
"input": "tt",
"output": "NIE"
},
{
"input": "mnmnm",
"output": "NIE"
},
{
"input": "sss",
"output": "NIE"
},
{
"input": "yy",
"output": "NIE"
},
{
"input": "bob",
"output": "NIE"
},
{
"input": "NAN",
"output": "NIE"
},
{
"input": "mAm",
"output": "NIE"
},
{
"input": "tAt",
"output": "NIE"
},
{
"input": "yAy",
"output": "NIE"
},
{
"input": "zAz",
"output": "NIE"
},
{
"input": "aZ",
"output": "NIE"
},
{
"input": "hh",
"output": "NIE"
},
{
"input": "bbbb",
"output": "NIE"
},
{
"input": "ZAZ",
"output": "NIE"
},
{
"input": "Y",
"output": "TAK"
},
{
"input": "AAMM",
"output": "NIE"
},
{
"input": "lml",
"output": "NIE"
},
{
"input": "AZA",
"output": "NIE"
},
{
"input": "mXm",
"output": "NIE"
},
{
"input": "bd",
"output": "TAK"
},
{
"input": "H",
"output": "TAK"
},
{
"input": "uvu",
"output": "NIE"
},
{
"input": "dxxd",
"output": "NIE"
},
{
"input": "dp",
"output": "NIE"
},
{
"input": "vV",
"output": "NIE"
},
{
"input": "vMo",
"output": "NIE"
},
{
"input": "O",
"output": "TAK"
},
{
"input": "vYv",
"output": "TAK"
},
{
"input": "fv",
"output": "NIE"
},
{
"input": "U",
"output": "TAK"
},
{
"input": "iAi",
"output": "NIE"
},
{
"input": "I",
"output": "TAK"
},
{
"input": "VxrV",
"output": "NIE"
},
{
"input": "POP",
"output": "NIE"
},
{
"input": "bid",
"output": "NIE"
},
{
"input": "bmd",
"output": "NIE"
},
{
"input": "AiA",
"output": "NIE"
},
{
"input": "mmmmmm",
"output": "NIE"
},
{
"input": "XHX",
"output": "TAK"
},
{
"input": "llllll",
"output": "NIE"
},
{
"input": "aAa",
"output": "NIE"
},
{
"input": "Db",
"output": "NIE"
},
{
"input": "lOl",
"output": "NIE"
},
{
"input": "bzd",
"output": "NIE"
}
] | 1,653,991,709
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 168
| 46
| 0
|
t = input()
k = len(t) // 2 + 1
p = zip(t[:k], t[-k:][::-1])
u, v = 'AHIMOoTUVvWwXxY', 'bd db pq qp'
s = all(a in u and a == b or a + b in v for a, b in p)
print(['NIE', 'TAK'][s])
|
Title: s-palindrome
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Let's call a string "s-palindrome" if it is symmetric about the middle of the string. For example, the string "oHo" is "s-palindrome", but the string "aa" is not. The string "aa" is not "s-palindrome", because the second half of it is not a mirror reflection of the first half.
You are given a string *s*. Check if the string is "s-palindrome".
Input Specification:
The only line contains the string *s* (1<=≤<=|*s*|<=≤<=1000) which consists of only English letters.
Output Specification:
Print "TAK" if the string *s* is "s-palindrome" and "NIE" otherwise.
Demo Input:
['oXoxoXo\n', 'bod\n', 'ER\n']
Demo Output:
['TAK\n', 'TAK\n', 'NIE\n']
Note:
none
|
```python
t = input()
k = len(t) // 2 + 1
p = zip(t[:k], t[-k:][::-1])
u, v = 'AHIMOoTUVvWwXxY', 'bd db pq qp'
s = all(a in u and a == b or a + b in v for a, b in p)
print(['NIE', 'TAK'][s])
```
| 3
|
|
735
|
B
|
Urbanization
|
PROGRAMMING
| 1,100
|
[
"greedy",
"number theory",
"sortings"
] | null | null |
Local authorities have heard a lot about combinatorial abilities of Ostap Bender so they decided to ask his help in the question of urbanization. There are *n* people who plan to move to the cities. The wealth of the *i* of them is equal to *a**i*. Authorities plan to build two cities, first for *n*1 people and second for *n*2 people. Of course, each of *n* candidates can settle in only one of the cities. Thus, first some subset of candidates of size *n*1 settle in the first city and then some subset of size *n*2 is chosen among the remaining candidates and the move to the second city. All other candidates receive an official refuse and go back home.
To make the statistic of local region look better in the eyes of their bosses, local authorities decided to pick subsets of candidates in such a way that the sum of arithmetic mean of wealth of people in each of the cities is as large as possible. Arithmetic mean of wealth in one city is the sum of wealth *a**i* among all its residents divided by the number of them (*n*1 or *n*2 depending on the city). The division should be done in real numbers without any rounding.
Please, help authorities find the optimal way to pick residents for two cities.
|
The first line of the input contains three integers *n*, *n*1 and *n*2 (1<=≤<=*n*,<=*n*1,<=*n*2<=≤<=100<=000, *n*1<=+<=*n*2<=≤<=*n*) — the number of candidates who want to move to the cities, the planned number of residents of the first city and the planned number of residents of the second city.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100<=000), the *i*-th of them is equal to the wealth of the *i*-th candidate.
|
Print one real value — the maximum possible sum of arithmetic means of wealth of cities' residents. You answer will be considered correct if its absolute or relative error does not exceed 10<=-<=6.
Namely: let's assume that your answer is *a*, and the answer of the jury is *b*. The checker program will consider your answer correct, if .
|
[
"2 1 1\n1 5\n",
"4 2 1\n1 4 2 3\n"
] |
[
"6.00000000\n",
"6.50000000\n"
] |
In the first sample, one of the optimal solutions is to move candidate 1 to the first city and candidate 2 to the second.
In the second sample, the optimal solution is to pick candidates 3 and 4 for the first city, and candidate 2 for the second one. Thus we obtain (*a*<sub class="lower-index">3</sub> + *a*<sub class="lower-index">4</sub>) / 2 + *a*<sub class="lower-index">2</sub> = (3 + 2) / 2 + 4 = 6.5
| 1,000
|
[
{
"input": "2 1 1\n1 5",
"output": "6.00000000"
},
{
"input": "4 2 1\n1 4 2 3",
"output": "6.50000000"
},
{
"input": "3 1 2\n1 2 3",
"output": "4.50000000"
},
{
"input": "10 4 6\n3 5 7 9 12 25 67 69 83 96",
"output": "88.91666667"
},
{
"input": "19 7 12\n1 2 4 8 16 32 64 128 256 512 1024 2048 4096 8192 16384 32768 65536 100000 100000",
"output": "47052.10714286"
},
{
"input": "100 9 6\n109 711 40 95 935 48 228 253 308 726 816 534 252 8 966 363 162 508 84 83 807 506 748 178 45 30 106 108 764 698 825 198 336 353 158 790 64 262 403 334 577 571 742 541 946 602 279 621 910 776 421 886 29 133 114 394 762 965 339 263 750 530 49 80 124 31 322 292 27 590 960 278 111 932 849 491 561 744 469 511 106 271 156 160 836 363 149 473 457 543 976 809 490 29 85 626 265 88 995 946",
"output": "1849.66666667"
},
{
"input": "69 6 63\n53475 22876 79144 6335 33763 79104 65441 45527 65847 94406 74670 43529 75330 19403 67629 56187 57949 23071 64910 54409 55348 18056 855 24961 50565 6622 26467 33989 22660 79469 41246 13965 79706 14422 16075 93378 81313 48173 13470 97348 2346 27452 59427 29925 29847 73823 32021 10988 24609 98855 90919 45939 17203 8439 43007 40138 55693 30314 71734 33458 66850 4011 20089 20546 92090 50842 78859 62756 40177",
"output": "135712.88888889"
},
{
"input": "69 6 9\n2612 17461 69001 33130 10662 85485 88195 45974 16712 81365 67119 87797 15559 20197 74716 92979 97268 49466 68603 48351 99905 35606 54242 98603 68232 54398 82637 49647 38979 46171 54680 23334 15892 92186 69670 29711 67999 2220 32317 717 70667 68262 86760 55720 97158 61122 7251 138 21022 27197 12691 59331 13576 66999 38332 13574 83484 66646 17704 33065 98583 80259 64631 16745 69431 40747 82089 82788 32739",
"output": "183129.44444444"
}
] | 1,581,525,219
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 37
| 171
| 7,782,400
|
I = lambda: map(int, input().split())
_, n1, n2 = I()
A = sorted(I(), reverse=True)
if n1 > n2:
n1, n2 = n2, n1
print(sum(A[:n1])/n1 + sum(A[n1:n1+n2])/n2)
|
Title: Urbanization
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Local authorities have heard a lot about combinatorial abilities of Ostap Bender so they decided to ask his help in the question of urbanization. There are *n* people who plan to move to the cities. The wealth of the *i* of them is equal to *a**i*. Authorities plan to build two cities, first for *n*1 people and second for *n*2 people. Of course, each of *n* candidates can settle in only one of the cities. Thus, first some subset of candidates of size *n*1 settle in the first city and then some subset of size *n*2 is chosen among the remaining candidates and the move to the second city. All other candidates receive an official refuse and go back home.
To make the statistic of local region look better in the eyes of their bosses, local authorities decided to pick subsets of candidates in such a way that the sum of arithmetic mean of wealth of people in each of the cities is as large as possible. Arithmetic mean of wealth in one city is the sum of wealth *a**i* among all its residents divided by the number of them (*n*1 or *n*2 depending on the city). The division should be done in real numbers without any rounding.
Please, help authorities find the optimal way to pick residents for two cities.
Input Specification:
The first line of the input contains three integers *n*, *n*1 and *n*2 (1<=≤<=*n*,<=*n*1,<=*n*2<=≤<=100<=000, *n*1<=+<=*n*2<=≤<=*n*) — the number of candidates who want to move to the cities, the planned number of residents of the first city and the planned number of residents of the second city.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100<=000), the *i*-th of them is equal to the wealth of the *i*-th candidate.
Output Specification:
Print one real value — the maximum possible sum of arithmetic means of wealth of cities' residents. You answer will be considered correct if its absolute or relative error does not exceed 10<=-<=6.
Namely: let's assume that your answer is *a*, and the answer of the jury is *b*. The checker program will consider your answer correct, if .
Demo Input:
['2 1 1\n1 5\n', '4 2 1\n1 4 2 3\n']
Demo Output:
['6.00000000\n', '6.50000000\n']
Note:
In the first sample, one of the optimal solutions is to move candidate 1 to the first city and candidate 2 to the second.
In the second sample, the optimal solution is to pick candidates 3 and 4 for the first city, and candidate 2 for the second one. Thus we obtain (*a*<sub class="lower-index">3</sub> + *a*<sub class="lower-index">4</sub>) / 2 + *a*<sub class="lower-index">2</sub> = (3 + 2) / 2 + 4 = 6.5
|
```python
I = lambda: map(int, input().split())
_, n1, n2 = I()
A = sorted(I(), reverse=True)
if n1 > n2:
n1, n2 = n2, n1
print(sum(A[:n1])/n1 + sum(A[n1:n1+n2])/n2)
```
| 3
|
|
630
|
B
|
Moore's Law
|
PROGRAMMING
| 1,200
|
[
"math"
] | null | null |
The city administration of IT City decided to fix up a symbol of scientific and technical progress in the city's main square, namely an indicator board that shows the effect of Moore's law in real time.
Moore's law is the observation that the number of transistors in a dense integrated circuit doubles approximately every 24 months. The implication of Moore's law is that computer performance as function of time increases exponentially as well.
You are to prepare information that will change every second to display on the indicator board. Let's assume that every second the number of transistors increases exactly 1.000000011 times.
|
The only line of the input contains a pair of integers *n* (1000<=≤<=*n*<=≤<=10 000) and *t* (0<=≤<=*t*<=≤<=2 000 000 000) — the number of transistors in the initial time and the number of seconds passed since the initial time.
|
Output one number — the estimate of the number of transistors in a dence integrated circuit in *t* seconds since the initial time. The relative error of your answer should not be greater than 10<=-<=6.
|
[
"1000 1000000\n"
] |
[
"1011.060722383550382782399454922040\n"
] |
none
| 0
|
[
{
"input": "1000 1000000",
"output": "1011.060722383550382782399454922040"
},
{
"input": "1000 0",
"output": "1000"
},
{
"input": "1000 1",
"output": "1000.000011000"
},
{
"input": "1000 2",
"output": "1000.000022000000121000"
},
{
"input": "10000 3",
"output": "10000.000330000003630000013310000"
},
{
"input": "10000 2000000000",
"output": "35849124123571.66604124267909180280"
},
{
"input": "4907 244618708",
"output": "72346.60521729832602747499118899866"
},
{
"input": "9030 982505993",
"output": "446019624.4250800721903194914485562"
},
{
"input": "4054 287739817",
"output": "96047.41901816849953518710733057692"
},
{
"input": "1587 1941728048",
"output": "2996928752532.893524588882808611548"
}
] | 1,692,988,126
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 10
| 31
| 0
|
i = input().split()
n = int(i[0])
t = int(i[1])
print(n * 1.0 *(1.000000011 ** t))
|
Title: Moore's Law
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The city administration of IT City decided to fix up a symbol of scientific and technical progress in the city's main square, namely an indicator board that shows the effect of Moore's law in real time.
Moore's law is the observation that the number of transistors in a dense integrated circuit doubles approximately every 24 months. The implication of Moore's law is that computer performance as function of time increases exponentially as well.
You are to prepare information that will change every second to display on the indicator board. Let's assume that every second the number of transistors increases exactly 1.000000011 times.
Input Specification:
The only line of the input contains a pair of integers *n* (1000<=≤<=*n*<=≤<=10 000) and *t* (0<=≤<=*t*<=≤<=2 000 000 000) — the number of transistors in the initial time and the number of seconds passed since the initial time.
Output Specification:
Output one number — the estimate of the number of transistors in a dence integrated circuit in *t* seconds since the initial time. The relative error of your answer should not be greater than 10<=-<=6.
Demo Input:
['1000 1000000\n']
Demo Output:
['1011.060722383550382782399454922040\n']
Note:
none
|
```python
i = input().split()
n = int(i[0])
t = int(i[1])
print(n * 1.0 *(1.000000011 ** t))
```
| 3
|
|
902
|
A
|
Visiting a Friend
|
PROGRAMMING
| 1,100
|
[
"greedy",
"implementation"
] | null | null |
Pig is visiting a friend.
Pig's house is located at point 0, and his friend's house is located at point *m* on an axis.
Pig can use teleports to move along the axis.
To use a teleport, Pig should come to a certain point (where the teleport is located) and choose where to move: for each teleport there is the rightmost point it can move Pig to, this point is known as the limit of the teleport.
Formally, a teleport located at point *x* with limit *y* can move Pig from point *x* to any point within the segment [*x*;<=*y*], including the bounds.
Determine if Pig can visit the friend using teleports only, or he should use his car.
|
The first line contains two integers *n* and *m* (1<=≤<=*n*<=≤<=100,<=1<=≤<=*m*<=≤<=100) — the number of teleports and the location of the friend's house.
The next *n* lines contain information about teleports.
The *i*-th of these lines contains two integers *a**i* and *b**i* (0<=≤<=*a**i*<=≤<=*b**i*<=≤<=*m*), where *a**i* is the location of the *i*-th teleport, and *b**i* is its limit.
It is guaranteed that *a**i*<=≥<=*a**i*<=-<=1 for every *i* (2<=≤<=*i*<=≤<=*n*).
|
Print "YES" if there is a path from Pig's house to his friend's house that uses only teleports, and "NO" otherwise.
You can print each letter in arbitrary case (upper or lower).
|
[
"3 5\n0 2\n2 4\n3 5\n",
"3 7\n0 4\n2 5\n6 7\n"
] |
[
"YES\n",
"NO\n"
] |
The first example is shown on the picture below:
Pig can use the first teleport from his house (point 0) to reach point 2, then using the second teleport go from point 2 to point 3, then using the third teleport go from point 3 to point 5, where his friend lives.
The second example is shown on the picture below:
You can see that there is no path from Pig's house to his friend's house that uses only teleports.
| 500
|
[
{
"input": "3 5\n0 2\n2 4\n3 5",
"output": "YES"
},
{
"input": "3 7\n0 4\n2 5\n6 7",
"output": "NO"
},
{
"input": "1 1\n0 0",
"output": "NO"
},
{
"input": "30 10\n0 7\n1 2\n1 2\n1 4\n1 4\n1 3\n2 2\n2 4\n2 6\n2 9\n2 2\n3 5\n3 8\n4 8\n4 5\n4 6\n5 6\n5 7\n6 6\n6 9\n6 7\n6 9\n7 7\n7 7\n8 8\n8 8\n9 9\n9 9\n10 10\n10 10",
"output": "NO"
},
{
"input": "30 100\n0 27\n4 82\n11 81\n14 32\n33 97\n33 34\n37 97\n38 52\n45 91\n49 56\n50 97\n57 70\n59 94\n59 65\n62 76\n64 65\n65 95\n67 77\n68 100\n71 73\n80 94\n81 92\n84 85\n85 100\n88 91\n91 95\n92 98\n92 98\n99 100\n100 100",
"output": "YES"
},
{
"input": "70 10\n0 4\n0 4\n0 8\n0 9\n0 1\n0 5\n0 7\n1 3\n1 8\n1 8\n1 6\n1 6\n1 2\n1 3\n1 2\n1 3\n2 5\n2 4\n2 3\n2 4\n2 6\n2 2\n2 5\n2 7\n3 7\n3 4\n3 7\n3 4\n3 8\n3 4\n3 9\n3 3\n3 7\n3 9\n3 3\n3 9\n4 6\n4 7\n4 5\n4 7\n5 8\n5 5\n5 9\n5 7\n5 5\n6 6\n6 9\n6 7\n6 8\n6 9\n6 8\n7 7\n7 8\n7 7\n7 8\n8 9\n8 8\n8 9\n8 8\n9 9\n9 9\n9 9\n9 9\n9 9\n9 9\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "NO"
},
{
"input": "30 10\n0 7\n1 2\n1 2\n1 4\n1 4\n1 3\n2 2\n2 4\n2 6\n2 9\n2 2\n3 5\n3 8\n4 8\n4 5\n4 6\n5 6\n5 7\n6 6\n6 9\n6 7\n6 9\n7 7\n7 7\n8 10\n8 10\n9 9\n9 9\n10 10\n10 10",
"output": "YES"
},
{
"input": "50 100\n0 95\n1 100\n1 38\n2 82\n5 35\n7 71\n8 53\n11 49\n15 27\n17 84\n17 75\n18 99\n18 43\n18 69\n21 89\n27 60\n27 29\n38 62\n38 77\n39 83\n40 66\n48 80\n48 100\n50 51\n50 61\n53 77\n53 63\n55 58\n56 68\n60 82\n62 95\n66 74\n67 83\n69 88\n69 81\n69 88\n69 98\n70 91\n70 76\n71 90\n72 99\n81 99\n85 87\n88 97\n88 93\n90 97\n90 97\n92 98\n98 99\n100 100",
"output": "YES"
},
{
"input": "70 10\n0 4\n0 4\n0 8\n0 9\n0 1\n0 5\n0 7\n1 3\n1 8\n1 8\n1 10\n1 9\n1 6\n1 2\n1 3\n1 2\n2 6\n2 5\n2 4\n2 3\n2 10\n2 2\n2 6\n2 2\n3 10\n3 7\n3 7\n3 4\n3 7\n3 4\n3 8\n3 4\n3 10\n3 5\n3 3\n3 7\n4 8\n4 8\n4 9\n4 6\n5 7\n5 10\n5 7\n5 8\n5 5\n6 8\n6 9\n6 10\n6 6\n6 9\n6 7\n7 8\n7 9\n7 10\n7 10\n8 8\n8 8\n8 9\n8 10\n9 10\n9 9\n9 10\n9 10\n9 9\n9 9\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "YES"
},
{
"input": "85 10\n0 9\n0 4\n0 2\n0 5\n0 1\n0 8\n0 7\n1 2\n1 4\n1 5\n1 9\n1 1\n1 6\n1 6\n2 5\n2 7\n2 7\n2 7\n2 7\n3 4\n3 7\n3 9\n3 5\n3 3\n4 4\n4 6\n4 5\n5 6\n5 6\n5 6\n5 6\n5 7\n5 8\n5 5\n5 7\n5 8\n5 9\n5 8\n6 8\n6 7\n6 8\n6 9\n6 9\n6 6\n6 9\n6 7\n7 7\n7 7\n7 7\n7 8\n7 7\n7 8\n7 8\n7 9\n8 8\n8 8\n8 8\n8 8\n8 8\n8 9\n8 9\n9 9\n9 9\n9 9\n9 9\n9 9\n9 9\n9 9\n9 9\n9 9\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "NO"
},
{
"input": "30 40\n0 0\n4 8\n5 17\n7 32\n7 16\n8 16\n10 19\n12 22\n12 27\n13 21\n13 28\n13 36\n14 28\n14 18\n18 21\n21 26\n21 36\n22 38\n23 32\n24 30\n26 35\n29 32\n29 32\n31 34\n31 31\n33 33\n33 35\n35 40\n38 38\n40 40",
"output": "NO"
},
{
"input": "70 100\n0 99\n1 87\n1 94\n1 4\n2 72\n3 39\n3 69\n4 78\n5 85\n7 14\n8 59\n12 69\n14 15\n14 76\n17 17\n19 53\n19 57\n19 21\n21 35\n21 83\n24 52\n24 33\n27 66\n27 97\n30 62\n30 74\n30 64\n32 63\n35 49\n37 60\n40 99\n40 71\n41 83\n42 66\n42 46\n45 83\n51 76\n53 69\n54 82\n54 96\n54 88\n55 91\n56 88\n58 62\n62 87\n64 80\n67 90\n67 69\n68 92\n72 93\n74 93\n77 79\n77 91\n78 97\n78 98\n81 85\n81 83\n81 83\n84 85\n86 88\n89 94\n89 92\n92 97\n96 99\n97 98\n97 99\n99 99\n100 100\n100 100\n100 100",
"output": "NO"
},
{
"input": "1 10\n0 10",
"output": "YES"
},
{
"input": "70 40\n0 34\n1 16\n3 33\n4 36\n4 22\n5 9\n5 9\n7 16\n8 26\n9 29\n9 25\n10 15\n10 22\n10 29\n10 20\n11 27\n11 26\n11 12\n12 19\n13 21\n14 31\n14 36\n15 34\n15 37\n16 21\n17 31\n18 22\n20 27\n20 32\n20 20\n20 29\n21 29\n21 34\n21 30\n22 40\n23 23\n23 28\n24 29\n25 38\n26 35\n27 37\n28 39\n28 33\n28 40\n28 33\n29 31\n29 33\n30 38\n30 36\n30 30\n30 38\n31 37\n31 35\n31 32\n31 36\n33 39\n33 40\n35 38\n36 38\n37 38\n37 40\n38 39\n38 40\n38 39\n39 39\n39 40\n40 40\n40 40\n40 40\n40 40",
"output": "YES"
},
{
"input": "50 40\n0 9\n1 26\n1 27\n2 33\n2 5\n3 30\n4 28\n5 31\n5 27\n5 29\n7 36\n8 32\n8 13\n9 24\n10 10\n10 30\n11 26\n11 22\n11 40\n11 31\n12 26\n13 25\n14 32\n17 19\n21 29\n22 36\n24 27\n25 39\n25 27\n27 32\n27 29\n27 39\n27 29\n28 38\n30 38\n32 40\n32 38\n33 33\n33 40\n34 35\n34 34\n34 38\n34 38\n35 37\n36 39\n36 39\n37 37\n38 40\n39 39\n40 40",
"output": "YES"
},
{
"input": "70 40\n0 34\n1 16\n3 33\n4 36\n4 22\n5 9\n5 9\n7 16\n8 26\n9 29\n9 25\n10 15\n10 22\n10 29\n10 20\n11 27\n11 26\n11 12\n12 19\n13 21\n14 31\n14 36\n15 34\n15 37\n16 21\n17 31\n18 22\n20 27\n20 32\n20 20\n20 29\n21 29\n21 34\n21 30\n22 22\n23 28\n23 39\n24 24\n25 27\n26 38\n27 39\n28 33\n28 39\n28 34\n28 33\n29 30\n29 35\n30 30\n30 38\n30 34\n30 31\n31 36\n31 31\n31 32\n31 38\n33 34\n33 34\n35 36\n36 38\n37 38\n37 39\n38 38\n38 38\n38 38\n39 39\n39 39\n40 40\n40 40\n40 40\n40 40",
"output": "NO"
},
{
"input": "10 100\n0 34\n8 56\n17 79\n24 88\n28 79\n45 79\n48 93\n55 87\n68 93\n88 99",
"output": "NO"
},
{
"input": "10 10\n0 2\n3 8\n3 5\n3 3\n3 9\n3 8\n5 7\n6 10\n7 10\n9 10",
"output": "NO"
},
{
"input": "50 10\n0 2\n0 2\n0 6\n1 9\n1 3\n1 2\n1 6\n1 1\n1 1\n2 7\n2 6\n2 4\n3 9\n3 8\n3 8\n3 8\n3 6\n3 4\n3 7\n3 4\n3 6\n3 5\n4 8\n5 5\n5 7\n6 7\n6 6\n7 7\n7 7\n7 7\n7 8\n7 8\n8 8\n8 8\n8 9\n8 8\n8 9\n9 9\n9 9\n9 9\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "NO"
},
{
"input": "10 40\n0 21\n1 19\n4 33\n6 26\n8 39\n15 15\n20 24\n27 27\n29 39\n32 37",
"output": "NO"
},
{
"input": "50 10\n0 2\n0 2\n0 6\n1 9\n1 3\n1 2\n1 6\n1 1\n1 1\n2 7\n2 6\n2 4\n3 9\n3 8\n3 8\n3 8\n3 6\n3 4\n3 7\n3 4\n3 6\n3 10\n4 6\n5 9\n5 5\n6 7\n6 10\n7 8\n7 7\n7 7\n7 7\n7 10\n8 8\n8 8\n8 10\n8 8\n8 8\n9 10\n9 10\n9 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "YES"
},
{
"input": "1 1\n0 1",
"output": "YES"
},
{
"input": "30 40\n0 0\n4 8\n5 17\n7 32\n7 16\n8 16\n10 19\n12 22\n12 27\n13 21\n13 28\n13 36\n14 28\n14 18\n18 21\n21 26\n21 36\n22 38\n23 32\n24 30\n26 35\n29 32\n29 32\n31 34\n31 31\n33 33\n33 35\n35 36\n38 38\n40 40",
"output": "NO"
},
{
"input": "30 100\n0 27\n4 82\n11 81\n14 32\n33 97\n33 34\n37 97\n38 52\n45 91\n49 56\n50 97\n57 70\n59 94\n59 65\n62 76\n64 65\n65 95\n67 77\n68 82\n71 94\n80 90\n81 88\n84 93\n85 89\n88 92\n91 97\n92 99\n92 97\n99 99\n100 100",
"output": "NO"
},
{
"input": "10 100\n0 34\n8 56\n17 79\n24 88\n28 79\n45 79\n48 93\n55 87\n68 93\n79 100",
"output": "YES"
},
{
"input": "10 40\n0 21\n1 19\n4 33\n6 26\n8 39\n15 15\n20 24\n27 27\n29 39\n37 40",
"output": "YES"
},
{
"input": "85 10\n0 9\n0 4\n0 2\n0 5\n0 1\n0 8\n0 7\n1 2\n1 10\n1 2\n1 5\n1 10\n1 8\n1 1\n2 8\n2 7\n2 5\n2 5\n2 7\n3 5\n3 7\n3 5\n3 4\n3 7\n4 7\n4 8\n4 6\n5 7\n5 10\n5 5\n5 6\n5 6\n5 6\n5 6\n5 7\n5 8\n5 5\n5 7\n6 10\n6 9\n6 7\n6 10\n6 8\n6 7\n6 10\n6 10\n7 8\n7 9\n7 8\n7 8\n7 8\n7 8\n7 7\n7 7\n8 8\n8 8\n8 10\n8 9\n8 9\n8 9\n8 9\n9 9\n9 10\n9 9\n9 9\n9 9\n9 9\n9 10\n9 10\n9 9\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10\n10 10",
"output": "YES"
},
{
"input": "50 100\n0 95\n1 7\n1 69\n2 83\n5 67\n7 82\n8 31\n11 25\n15 44\n17 75\n17 27\n18 43\n18 69\n18 40\n21 66\n27 29\n27 64\n38 77\n38 90\n39 52\n40 60\n48 91\n48 98\n50 89\n50 63\n53 54\n53 95\n55 76\n56 59\n60 96\n62 86\n66 70\n67 77\n69 88\n69 98\n69 80\n69 95\n70 74\n70 77\n71 99\n72 73\n81 87\n85 99\n88 96\n88 91\n90 97\n90 99\n92 92\n98 99\n100 100",
"output": "NO"
},
{
"input": "50 40\n0 9\n1 26\n1 27\n2 33\n2 5\n3 30\n4 28\n5 31\n5 27\n5 29\n7 36\n8 32\n8 13\n9 24\n10 10\n10 30\n11 26\n11 22\n11 35\n11 23\n12 36\n13 31\n14 31\n17 17\n21 25\n22 33\n24 26\n25 32\n25 25\n27 39\n27 29\n27 34\n27 32\n28 34\n30 36\n32 37\n32 33\n33 35\n33 33\n34 38\n34 38\n34 36\n34 36\n35 36\n36 36\n36 39\n37 37\n38 39\n39 39\n40 40",
"output": "NO"
},
{
"input": "10 10\n0 2\n3 8\n3 5\n3 3\n3 9\n3 8\n5 7\n6 9\n7 7\n9 9",
"output": "NO"
},
{
"input": "70 100\n0 99\n1 87\n1 94\n1 4\n2 72\n3 39\n3 69\n4 78\n5 85\n7 14\n8 59\n12 69\n14 15\n14 76\n17 17\n19 53\n19 57\n19 21\n21 35\n21 83\n24 52\n24 33\n27 66\n27 97\n30 62\n30 74\n30 64\n32 63\n35 49\n37 60\n40 99\n40 71\n41 83\n42 66\n42 46\n45 83\n51 76\n53 69\n54 82\n54 96\n54 88\n55 91\n56 88\n58 62\n62 87\n64 80\n67 90\n67 69\n68 92\n72 93\n74 93\n77 79\n77 91\n78 97\n78 98\n81 85\n81 83\n81 83\n84 85\n86 88\n89 94\n89 100\n92 97\n96 96\n97 98\n97 100\n99 100\n100 100\n100 100\n100 100",
"output": "YES"
},
{
"input": "2 2\n0 2\n0 1",
"output": "YES"
},
{
"input": "2 100\n0 49\n50 100",
"output": "NO"
},
{
"input": "2 100\n0 50\n50 100",
"output": "YES"
},
{
"input": "10 100\n0 10\n10 20\n20 30\n30 40\n40 50\n50 60\n60 70\n70 80\n80 90\n90 100",
"output": "YES"
},
{
"input": "100 10\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 10",
"output": "YES"
},
{
"input": "1 4\n1 4",
"output": "NO"
},
{
"input": "3 5\n0 2\n2 5\n3 4",
"output": "YES"
},
{
"input": "2 5\n0 5\n1 2",
"output": "YES"
},
{
"input": "5 5\n0 2\n0 2\n3 5\n3 5\n3 5",
"output": "NO"
},
{
"input": "4 10\n0 3\n2 10\n4 10\n5 7",
"output": "YES"
},
{
"input": "3 8\n0 0\n1 8\n2 8",
"output": "NO"
},
{
"input": "6 8\n0 3\n1 5\n2 3\n5 6\n6 7\n7 8",
"output": "YES"
}
] | 1,514,205,715
| 415
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 46
| 5,529,600
|
n, m = map(int, input().split())
def sai():
ao, bo = map(int, input().split())
if ao != 0:
print("NO")
return
for i in range(n-1):
a,b = map(int, input().split())
if a > bo:
print("NO")
return
ao, bo = a, b
if b != m:
print("NO")
return
print("YES")
sai()
|
Title: Visiting a Friend
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Pig is visiting a friend.
Pig's house is located at point 0, and his friend's house is located at point *m* on an axis.
Pig can use teleports to move along the axis.
To use a teleport, Pig should come to a certain point (where the teleport is located) and choose where to move: for each teleport there is the rightmost point it can move Pig to, this point is known as the limit of the teleport.
Formally, a teleport located at point *x* with limit *y* can move Pig from point *x* to any point within the segment [*x*;<=*y*], including the bounds.
Determine if Pig can visit the friend using teleports only, or he should use his car.
Input Specification:
The first line contains two integers *n* and *m* (1<=≤<=*n*<=≤<=100,<=1<=≤<=*m*<=≤<=100) — the number of teleports and the location of the friend's house.
The next *n* lines contain information about teleports.
The *i*-th of these lines contains two integers *a**i* and *b**i* (0<=≤<=*a**i*<=≤<=*b**i*<=≤<=*m*), where *a**i* is the location of the *i*-th teleport, and *b**i* is its limit.
It is guaranteed that *a**i*<=≥<=*a**i*<=-<=1 for every *i* (2<=≤<=*i*<=≤<=*n*).
Output Specification:
Print "YES" if there is a path from Pig's house to his friend's house that uses only teleports, and "NO" otherwise.
You can print each letter in arbitrary case (upper or lower).
Demo Input:
['3 5\n0 2\n2 4\n3 5\n', '3 7\n0 4\n2 5\n6 7\n']
Demo Output:
['YES\n', 'NO\n']
Note:
The first example is shown on the picture below:
Pig can use the first teleport from his house (point 0) to reach point 2, then using the second teleport go from point 2 to point 3, then using the third teleport go from point 3 to point 5, where his friend lives.
The second example is shown on the picture below:
You can see that there is no path from Pig's house to his friend's house that uses only teleports.
|
```python
n, m = map(int, input().split())
def sai():
ao, bo = map(int, input().split())
if ao != 0:
print("NO")
return
for i in range(n-1):
a,b = map(int, input().split())
if a > bo:
print("NO")
return
ao, bo = a, b
if b != m:
print("NO")
return
print("YES")
sai()
```
| 0
|
|
415
|
A
|
Mashmokh and Lights
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
Mashmokh works in a factory. At the end of each day he must turn off all of the lights.
The lights on the factory are indexed from 1 to *n*. There are *n* buttons in Mashmokh's room indexed from 1 to *n* as well. If Mashmokh pushes button with index *i*, then each light with index not less than *i* that is still turned on turns off.
Mashmokh is not very clever. So instead of pushing the first button he pushes some of the buttons randomly each night. He pushed *m* distinct buttons *b*1,<=*b*2,<=...,<=*b**m* (the buttons were pushed consecutively in the given order) this night. Now he wants to know for each light the index of the button that turned this light off. Please note that the index of button *b**i* is actually *b**i*, not *i*.
Please, help Mashmokh, print these indices.
|
The first line of the input contains two space-separated integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), the number of the factory lights and the pushed buttons respectively. The next line contains *m* distinct space-separated integers *b*1,<=*b*2,<=...,<=*b**m* (1<=≤<=*b**i*<=≤<=*n*).
It is guaranteed that all lights will be turned off after pushing all buttons.
|
Output *n* space-separated integers where the *i*-th number is index of the button that turns the *i*-th light off.
|
[
"5 4\n4 3 1 2\n",
"5 5\n5 4 3 2 1\n"
] |
[
"1 1 3 4 4 \n",
"1 2 3 4 5 \n"
] |
In the first sample, after pressing button number 4, lights 4 and 5 are turned off and lights 1, 2 and 3 are still on. Then after pressing button number 3, light number 3 is turned off as well. Pressing button number 1 turns off lights number 1 and 2 as well so pressing button number 2 in the end has no effect. Thus button number 4 turned lights 4 and 5 off, button number 3 turned light 3 off and button number 1 turned light 1 and 2 off.
| 500
|
[
{
"input": "5 4\n4 3 1 2",
"output": "1 1 3 4 4 "
},
{
"input": "5 5\n5 4 3 2 1",
"output": "1 2 3 4 5 "
},
{
"input": "16 11\n8 5 12 10 14 2 6 3 15 9 1",
"output": "1 2 2 2 5 5 5 8 8 8 8 8 8 8 8 8 "
},
{
"input": "79 22\n76 32 48 28 33 44 58 59 1 51 77 13 15 64 49 72 74 21 61 12 60 57",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 28 28 28 28 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 76 76 76 76 "
},
{
"input": "25 19\n3 12 21 11 19 6 5 15 4 16 20 8 9 1 22 23 25 18 13",
"output": "1 1 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 "
},
{
"input": "48 8\n42 27 40 1 18 3 19 2",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 27 27 27 27 27 27 27 27 27 27 27 27 27 27 27 42 42 42 42 42 42 42 "
},
{
"input": "44 19\n13 20 7 10 9 14 43 17 18 39 21 42 37 1 33 8 35 4 6",
"output": "1 1 1 1 1 1 7 7 7 7 7 7 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 "
},
{
"input": "80 29\n79 51 28 73 65 39 10 1 59 29 7 70 64 3 35 17 24 71 74 2 6 49 66 80 13 18 60 15 12",
"output": "1 1 1 1 1 1 1 1 1 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 51 79 79 "
},
{
"input": "31 4\n8 18 30 1",
"output": "1 1 1 1 1 1 1 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 "
},
{
"input": "62 29\n61 55 35 13 51 56 23 6 8 26 27 40 48 11 18 12 19 50 54 14 24 21 32 17 43 33 1 2 3",
"output": "1 1 1 1 1 6 6 6 6 6 6 6 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 13 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 35 55 55 55 55 55 55 61 61 "
},
{
"input": "5 4\n2 3 4 1",
"output": "1 2 2 2 2 "
},
{
"input": "39 37\n2 5 17 24 19 33 35 16 20 3 1 34 10 36 15 37 14 8 28 21 13 31 30 29 7 25 32 12 6 27 22 4 11 39 18 9 26",
"output": "1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 "
},
{
"input": "100 100\n100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1",
"output": "1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 "
},
{
"input": "1 1\n1",
"output": "1 "
},
{
"input": "18 3\n18 1 11",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 18 "
},
{
"input": "67 20\n66 23 40 49 3 39 60 43 52 47 16 36 22 5 41 10 55 34 64 1",
"output": "1 1 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 23 66 66 "
},
{
"input": "92 52\n9 85 44 13 27 61 8 1 28 41 6 14 70 67 39 71 56 80 34 21 5 10 40 73 63 38 90 57 37 36 82 86 65 46 7 54 81 12 45 49 83 59 64 26 62 25 60 24 91 47 53 55",
"output": "1 1 1 1 1 1 1 8 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 "
},
{
"input": "66 36\n44 62 32 29 3 15 47 30 50 42 35 2 33 65 10 13 56 12 1 16 7 36 39 11 25 28 20 52 46 38 37 8 61 49 48 14",
"output": "1 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 29 29 29 32 32 32 32 32 32 32 32 32 32 32 32 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 "
},
{
"input": "32 8\n27 23 1 13 18 24 17 26",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 23 23 23 23 27 27 27 27 27 27 "
},
{
"input": "26 13\n1 14 13 2 4 24 21 22 16 3 10 12 6",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 "
},
{
"input": "31 20\n10 11 20 2 4 26 31 7 13 12 28 1 30 18 21 8 3 16 15 19",
"output": "1 2 2 2 2 2 2 2 2 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 "
},
{
"input": "86 25\n22 62 8 23 53 77 9 31 43 1 58 16 72 11 15 35 60 39 79 4 82 64 76 63 59",
"output": "1 1 1 1 1 1 1 8 8 8 8 8 8 8 8 8 8 8 8 8 8 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 22 "
},
{
"input": "62 54\n2 5 4 47 40 61 37 31 41 16 44 42 48 32 10 6 62 38 52 49 11 20 55 22 3 36 25 21 50 8 28 14 18 39 34 54 53 19 46 27 15 23 12 24 60 17 33 57 58 1 35 29 51 7",
"output": "1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 "
},
{
"input": "57 19\n43 45 37 40 42 55 16 33 47 32 34 35 9 41 1 6 8 15 5",
"output": "1 1 1 1 1 1 1 1 9 9 9 9 9 9 9 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 37 37 37 37 37 37 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 "
},
{
"input": "32 14\n4 7 13 1 25 22 9 27 6 28 30 2 14 21",
"output": "1 1 1 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 "
},
{
"input": "57 12\n8 53 51 38 1 6 16 33 13 46 28 35",
"output": "1 1 1 1 1 1 1 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 "
},
{
"input": "87 9\n57 34 78 1 52 67 56 6 54",
"output": "1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 34 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 57 "
},
{
"input": "88 42\n85 45 52 14 63 53 70 71 16 86 66 47 12 22 10 72 4 31 3 69 11 77 17 25 46 75 23 1 21 84 44 20 18 33 48 88 41 83 67 61 73 34",
"output": "1 1 3 4 4 4 4 4 4 10 10 12 12 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 85 85 85 85 "
},
{
"input": "27 25\n9 21 17 5 16 3 23 7 12 4 14 11 13 1 15 19 27 8 20 10 22 25 6 18 26",
"output": "1 1 3 3 5 5 5 5 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 "
},
{
"input": "89 28\n5 22 79 42 16 35 66 48 57 55 1 37 29 31 40 38 45 62 41 87 64 89 81 13 60 44 71 82",
"output": "1 1 1 1 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 "
},
{
"input": "17 4\n4 3 1 2",
"output": "1 1 3 4 4 4 4 4 4 4 4 4 4 4 4 4 4 "
}
] | 1,396,800,313
| 1,513
|
Python 3
|
WRONG_ANSWER
|
PRETESTS
| 0
| 46
| 0
|
n,m=map(int,input().split())
a=list(map(int,input().split()))
b=[0]*n
for i in range(m):
num=a[i]
while num<=len(b) and b[num-1]==0:
b[num-1]=a[i]
num+=1
print(b)
|
Title: Mashmokh and Lights
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Mashmokh works in a factory. At the end of each day he must turn off all of the lights.
The lights on the factory are indexed from 1 to *n*. There are *n* buttons in Mashmokh's room indexed from 1 to *n* as well. If Mashmokh pushes button with index *i*, then each light with index not less than *i* that is still turned on turns off.
Mashmokh is not very clever. So instead of pushing the first button he pushes some of the buttons randomly each night. He pushed *m* distinct buttons *b*1,<=*b*2,<=...,<=*b**m* (the buttons were pushed consecutively in the given order) this night. Now he wants to know for each light the index of the button that turned this light off. Please note that the index of button *b**i* is actually *b**i*, not *i*.
Please, help Mashmokh, print these indices.
Input Specification:
The first line of the input contains two space-separated integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), the number of the factory lights and the pushed buttons respectively. The next line contains *m* distinct space-separated integers *b*1,<=*b*2,<=...,<=*b**m* (1<=≤<=*b**i*<=≤<=*n*).
It is guaranteed that all lights will be turned off after pushing all buttons.
Output Specification:
Output *n* space-separated integers where the *i*-th number is index of the button that turns the *i*-th light off.
Demo Input:
['5 4\n4 3 1 2\n', '5 5\n5 4 3 2 1\n']
Demo Output:
['1 1 3 4 4 \n', '1 2 3 4 5 \n']
Note:
In the first sample, after pressing button number 4, lights 4 and 5 are turned off and lights 1, 2 and 3 are still on. Then after pressing button number 3, light number 3 is turned off as well. Pressing button number 1 turns off lights number 1 and 2 as well so pressing button number 2 in the end has no effect. Thus button number 4 turned lights 4 and 5 off, button number 3 turned light 3 off and button number 1 turned light 1 and 2 off.
|
```python
n,m=map(int,input().split())
a=list(map(int,input().split()))
b=[0]*n
for i in range(m):
num=a[i]
while num<=len(b) and b[num-1]==0:
b[num-1]=a[i]
num+=1
print(b)
```
| 0
|
|
133
|
A
|
HQ9+
|
PROGRAMMING
| 900
|
[
"implementation"
] | null | null |
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
|
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
|
Output "YES", if executing the program will produce any output, and "NO" otherwise.
|
[
"Hi!\n",
"Codeforces\n"
] |
[
"YES\n",
"NO\n"
] |
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
| 500
|
[
{
"input": "Hi!",
"output": "YES"
},
{
"input": "Codeforces",
"output": "NO"
},
{
"input": "a+b=c",
"output": "NO"
},
{
"input": "hq-lowercase",
"output": "NO"
},
{
"input": "Q",
"output": "YES"
},
{
"input": "9",
"output": "YES"
},
{
"input": "H",
"output": "YES"
},
{
"input": "+",
"output": "NO"
},
{
"input": "~",
"output": "NO"
},
{
"input": "dEHsbM'gS[\\brZ_dpjXw8f?L[4E\"s4Zc9*(,j:>p$}m7HD[_9nOWQ\\uvq2mHWR",
"output": "YES"
},
{
"input": "tt6l=RHOfStm.;Qd$-}zDes*E,.F7qn5-b%HC",
"output": "YES"
},
{
"input": "@F%K2=%RyL/",
"output": "NO"
},
{
"input": "juq)k(FT.^G=G\\zcqnO\"uJIE1_]KFH9S=1c\"mJ;F9F)%>&.WOdp09+k`Yc6}\"6xw,Aos:M\\_^^:xBb[CcsHm?J",
"output": "YES"
},
{
"input": "6G_\"Fq#<AWyHG=Rci1t%#Jc#x<Fpg'N@t%F=``YO7\\Zd;6PkMe<#91YgzTC)",
"output": "YES"
},
{
"input": "Fvg_~wC>SO4lF}*c`Q;mII9E{4.QodbqN]C",
"output": "YES"
},
{
"input": "p-UXsbd&f",
"output": "NO"
},
{
"input": "<]D7NMA)yZe=`?RbP5lsa.l_Mg^V:\"-0x+$3c,q&L%18Ku<HcA\\s!^OQblk^x{35S'>yz8cKgVHWZ]kV0>_",
"output": "YES"
},
{
"input": "f.20)8b+.R}Gy!DbHU3v(.(=Q^`z[_BaQ}eO=C1IK;b2GkD\\{\\Bf\"!#qh]",
"output": "YES"
},
{
"input": "}do5RU<(w<q[\"-NR)IAH_HyiD{",
"output": "YES"
},
{
"input": "Iy^.,Aw*,5+f;l@Q;jLK'G5H-r1Pfmx?ei~`CjMmUe{K:lS9cu4ay8rqRh-W?Gqv!e-j*U)!Mzn{E8B6%~aSZ~iQ_QwlC9_cX(o8",
"output": "YES"
},
{
"input": "sKLje,:q>-D,;NvQ3,qN3-N&tPx0nL/,>Ca|z\"k2S{NF7btLa3_TyXG4XZ:`(t&\"'^M|@qObZxv",
"output": "YES"
},
{
"input": "%z:c@1ZsQ@\\6U/NQ+M9R>,$bwG`U1+C\\18^:S},;kw!&4r|z`",
"output": "YES"
},
{
"input": "OKBB5z7ud81[Tn@P\"nDUd,>@",
"output": "NO"
},
{
"input": "y{0;neX]w0IenPvPx0iXp+X|IzLZZaRzBJ>q~LhMhD$x-^GDwl;,a'<bAqH8QrFwbK@oi?I'W.bZ]MlIQ/x(0YzbTH^l.)]0Bv",
"output": "YES"
},
{
"input": "EL|xIP5_+Caon1hPpQ0[8+r@LX4;b?gMy>;/WH)pf@Ur*TiXu*e}b-*%acUA~A?>MDz#!\\Uh",
"output": "YES"
},
{
"input": "UbkW=UVb>;z6)p@Phr;^Dn.|5O{_i||:Rv|KJ_ay~V(S&Jp",
"output": "NO"
},
{
"input": "!3YPv@2JQ44@)R2O_4`GO",
"output": "YES"
},
{
"input": "Kba/Q,SL~FMd)3hOWU'Jum{9\"$Ld4:GW}D]%tr@G{hpG:PV5-c'VIZ~m/6|3I?_4*1luKnOp`%p|0H{[|Y1A~4-ZdX,Rw2[\\",
"output": "YES"
},
{
"input": "NRN*=v>;oU7[acMIJn*n^bWm!cm3#E7Efr>{g-8bl\"DN4~_=f?[T;~Fq#&)aXq%</GcTJD^e$@Extm[e\"C)q_L",
"output": "NO"
},
{
"input": "y#<fv{_=$MP!{D%I\\1OqjaqKh[pqE$KvYL<9@*V'j8uH0/gQdA'G;&y4Cv6&",
"output": "YES"
},
{
"input": "+SE_Pg<?7Fh,z&uITQut2a-mk8X8La`c2A}",
"output": "YES"
},
{
"input": "Uh3>ER](J",
"output": "NO"
},
{
"input": "!:!{~=9*\\P;Z6F?HC5GadFz)>k*=u|+\"Cm]ICTmB!`L{&oS/z6b~#Snbp/^\\Q>XWU-vY+/dP.7S=-#&whS@,",
"output": "YES"
},
{
"input": "KimtYBZp+ISeO(uH;UldoE6eAcp|9u?SzGZd6j-e}[}u#e[Cx8.qgY]$2!",
"output": "YES"
},
{
"input": "[:[SN-{r>[l+OggH3v3g{EPC*@YBATT@",
"output": "YES"
},
{
"input": "'jdL(vX",
"output": "NO"
},
{
"input": "Q;R+aay]cL?Zh*uG\"YcmO*@Dts*Gjp}D~M7Z96+<4?9I3aH~0qNdO(RmyRy=ci,s8qD_kwj;QHFzD|5,5",
"output": "YES"
},
{
"input": "{Q@#<LU_v^qdh%gGxz*pu)Y\"]k-l-N30WAxvp2IE3:jD0Wi4H/xWPH&s",
"output": "YES"
},
{
"input": "~@Gb(S&N$mBuBUMAky-z^{5VwLNTzYg|ZUZncL@ahS?K*As<$iNUARM3r43J'jJB)$ujfPAq\"G<S9flGyakZg!2Z.-NJ|2{F>]",
"output": "YES"
},
{
"input": "Jp5Aa>aP6fZ!\\6%A}<S}j{O4`C6y$8|i3IW,WHy&\"ioE&7zP\"'xHAY;:x%@SnS]Mr{R|})gU",
"output": "YES"
},
{
"input": "ZA#:U)$RI^sE\\vuAt]x\"2zipI!}YEu2<j$:H0_9/~eB?#->",
"output": "YES"
},
{
"input": "&ppw0._:\\p-PuWM@l}%%=",
"output": "NO"
},
{
"input": "P(^pix\"=oiEZu8?@d@J(I`Xp5TN^T3\\Z7P5\"ZrvZ{2Fwz3g-8`U!)(1$a<g+9Q|COhDoH;HwFY02Pa|ZGp$/WZBR=>6Jg!yr",
"output": "YES"
},
{
"input": "`WfODc\\?#ax~1xu@[ao+o_rN|L7%v,p,nDv>3+6cy.]q3)+A6b!q*Hc+#.t4f~vhUa~$^q",
"output": "YES"
},
{
"input": ",)TH9N}'6t2+0Yg?S#6/{_.,!)9d}h'wG|sY&'Ul4D0l0",
"output": "YES"
},
{
"input": "VXB&r9Z)IlKOJ:??KDA",
"output": "YES"
},
{
"input": "\")1cL>{o\\dcYJzu?CefyN^bGRviOH&P7rJS3PT4:0V3F)%\\}L=AJouYsj_>j2|7^1NWu*%NbOP>ngv-ls<;b-4Sd3Na0R",
"output": "YES"
},
{
"input": "2Y}\\A)>row{~c[g>:'.|ZC8%UTQ/jcdhK%6O)QRC.kd@%y}LJYk=V{G5pQK/yKJ%{G3C",
"output": "YES"
},
{
"input": "O.&=qt(`z(",
"output": "NO"
},
{
"input": "_^r6fyIc/~~;>l%9?aVEi7-{=,[<aMiB'-scSg$$|\"jAzY0N>QkHHGBZj2c\"=fhRlWd5;5K|GgU?7h]!;wl@",
"output": "YES"
},
{
"input": "+/`sAd&eB29E=Nu87${.u6GY@$^a$,}s^!p!F}B-z8<<wORb<S7;HM1a,gp",
"output": "YES"
},
{
"input": "U_ilyOGMT+QiW/M8/D(1=6a7)_FA,h4`8",
"output": "YES"
},
{
"input": "!0WKT:$O",
"output": "NO"
},
{
"input": "1EE*I%EQz6$~pPu7|(r7nyPQt4uGU@]~H'4uII?b1_Wn)K?ZRHrr0z&Kr;}aO3<mN=3:{}QgPxI|Ncm4#)",
"output": "YES"
},
{
"input": "[u3\"$+!:/.<Dp1M7tH}:zxjt],^kv}qP;y12\"`^'/u*h%AFmPJ>e1#Yly",
"output": "YES"
},
{
"input": "'F!_]tB<A&UO+p?7liE>(x&RFgG2~\\(",
"output": "NO"
},
{
"input": "Qv)X8",
"output": "YES"
},
{
"input": "aGv7,J@&g1(}E3g6[LuDZwZl2<v7IwQA%\"R(?ouBD>_=y\"3Kf%^>vON<a^T\\G^ootgE@whWmZo=[ex|F",
"output": "YES"
},
{
"input": "e{}2vQ+/r@p0}cLKNe4MCk",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnkH",
"output": "YES"
},
{
"input": "Qzbmweyydiadtlcouegmdbyfwurpwbpuvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "mzbmweyydiadtlcouegmdbyfwurpwb9uvhifnuapwyndmhtqvkgkbhtytszotwflegsjzzszfwtzfpnscguemwrczqxycivdqnky",
"output": "YES"
},
{
"input": "1H1",
"output": "YES"
},
{
"input": "+Q",
"output": "YES"
},
{
"input": "1ab",
"output": "NO"
},
{
"input": "!",
"output": "NO"
},
{
"input": "0+",
"output": "NO"
},
{
"input": "+H",
"output": "YES"
},
{
"input": "cH",
"output": "YES"
},
{
"input": "+8",
"output": "NO"
},
{
"input": "8+",
"output": "NO"
},
{
"input": "++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "(+)",
"output": "NO"
},
{
"input": "H+",
"output": "YES"
},
{
"input": "a!",
"output": "NO"
},
{
"input": "++++++++++++++",
"output": "NO"
},
{
"input": "+++++++++++++++++++++++++++++++++++++++++++++++++++++++++",
"output": "NO"
},
{
"input": "8",
"output": "NO"
},
{
"input": "3",
"output": "NO"
},
{
"input": "HQ9",
"output": "YES"
},
{
"input": "+++H",
"output": "YES"
},
{
"input": "++++++++++",
"output": "NO"
},
{
"input": "HHHHHHH",
"output": "YES"
},
{
"input": "abacabaH",
"output": "YES"
},
{
"input": "+G",
"output": "NO"
}
] | 1,690,892,374
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 85
| 498
| 14,540,800
|
import sys
import math
import statistics
import operator
input = lambda :sys.stdin.readline().rstrip()
output =lambda:sys.stdout()
def isPrime(n):
for i in range(2,int(n**0.5)+1):
if n%i==0:
return False
return True
fArray=[0,1]
def fibonacci(n):
if n<=len(fArray):
return fArray[n-1]
else:
temp = fibonacci(n-1)+fibonacci(n-2)
fArray.append(temp)
return temp
def isInt(n):
if (n*10)%10==0:
return True
else:
return False
def find_gcd(x, y):
while(y):
x, y = y, x % y
return x
def gcd(l):
num1=l[0]
num2=l[1]
gcd=find_gcd(num1,num2)
for i in range(2,len(l)):
gcd=find_gcd(gcd,l[i])
return gcd
# for _ in range(int(input())):
n=input()
if "H" in n:
print("YES")
elif 'Q' in n:
print("YES")
elif '9' in n:
print("YES")
else:
print("NO")
|
Title: HQ9+
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
HQ9+ is a joke programming language which has only four one-character instructions:
- "H" prints "Hello, World!",- "Q" prints the source code of the program itself,- "9" prints the lyrics of "99 Bottles of Beer" song, - "+" increments the value stored in the internal accumulator.
Instructions "H" and "Q" are case-sensitive and must be uppercase. The characters of the program which are not instructions are ignored.
You are given a program written in HQ9+. You have to figure out whether executing this program will produce any output.
Input Specification:
The input will consist of a single line *p* which will give a program in HQ9+. String *p* will contain between 1 and 100 characters, inclusive. ASCII-code of each character of *p* will be between 33 (exclamation mark) and 126 (tilde), inclusive.
Output Specification:
Output "YES", if executing the program will produce any output, and "NO" otherwise.
Demo Input:
['Hi!\n', 'Codeforces\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first case the program contains only one instruction — "H", which prints "Hello, World!".
In the second case none of the program characters are language instructions.
|
```python
import sys
import math
import statistics
import operator
input = lambda :sys.stdin.readline().rstrip()
output =lambda:sys.stdout()
def isPrime(n):
for i in range(2,int(n**0.5)+1):
if n%i==0:
return False
return True
fArray=[0,1]
def fibonacci(n):
if n<=len(fArray):
return fArray[n-1]
else:
temp = fibonacci(n-1)+fibonacci(n-2)
fArray.append(temp)
return temp
def isInt(n):
if (n*10)%10==0:
return True
else:
return False
def find_gcd(x, y):
while(y):
x, y = y, x % y
return x
def gcd(l):
num1=l[0]
num2=l[1]
gcd=find_gcd(num1,num2)
for i in range(2,len(l)):
gcd=find_gcd(gcd,l[i])
return gcd
# for _ in range(int(input())):
n=input()
if "H" in n:
print("YES")
elif 'Q' in n:
print("YES")
elif '9' in n:
print("YES")
else:
print("NO")
```
| 3
|
|
734
|
B
|
Anton and Digits
|
PROGRAMMING
| 800
|
[
"brute force",
"greedy",
"implementation",
"math"
] | null | null |
Recently Anton found a box with digits in his room. There are *k*2 digits 2, *k*3 digits 3, *k*5 digits 5 and *k*6 digits 6.
Anton's favorite integers are 32 and 256. He decided to compose this integers from digits he has. He wants to make the sum of these integers as large as possible. Help him solve this task!
Each digit can be used no more than once, i.e. the composed integers should contain no more than *k*2 digits 2, *k*3 digits 3 and so on. Of course, unused digits are not counted in the sum.
|
The only line of the input contains four integers *k*2, *k*3, *k*5 and *k*6 — the number of digits 2, 3, 5 and 6 respectively (0<=≤<=*k*2,<=*k*3,<=*k*5,<=*k*6<=≤<=5·106).
|
Print one integer — maximum possible sum of Anton's favorite integers that can be composed using digits from the box.
|
[
"5 1 3 4\n",
"1 1 1 1\n"
] |
[
"800\n",
"256\n"
] |
In the first sample, there are five digits 2, one digit 3, three digits 5 and four digits 6. Anton can compose three integers 256 and one integer 32 to achieve the value 256 + 256 + 256 + 32 = 800. Note, that there is one unused integer 2 and one unused integer 6. They are not counted in the answer.
In the second sample, the optimal answer is to create on integer 256, thus the answer is 256.
| 750
|
[
{
"input": "5 1 3 4",
"output": "800"
},
{
"input": "1 1 1 1",
"output": "256"
},
{
"input": "10 2 1 5",
"output": "320"
},
{
"input": "4 2 7 2",
"output": "576"
},
{
"input": "489 292 127 263",
"output": "41856"
},
{
"input": "9557 5242 1190 7734",
"output": "472384"
},
{
"input": "1480320 1969946 1158387 3940412",
"output": "306848928"
},
{
"input": "0 0 0 0",
"output": "0"
},
{
"input": "5000000 5000000 5000000 5000000",
"output": "1280000000"
},
{
"input": "1048576 256 1048576 1048576",
"output": "268435456"
},
{
"input": "2073144 2073145 0 0",
"output": "66340608"
},
{
"input": "1000000 0 0 1",
"output": "0"
},
{
"input": "2 1 1 1",
"output": "288"
},
{
"input": "0 5000000 5000000 5000000",
"output": "0"
},
{
"input": "4494839 1140434 3336818 4921605",
"output": "890719296"
},
{
"input": "2363223 3835613 926184 3190201",
"output": "283088352"
},
{
"input": "198044 2268164 2811743 1458798",
"output": "50699264"
},
{
"input": "5 5 1 0",
"output": "160"
},
{
"input": "1 1 1 4",
"output": "256"
},
{
"input": "3 3 4 4",
"output": "768"
},
{
"input": "1 2 0 5",
"output": "32"
},
{
"input": "1207814 1649617 2347252 3136345",
"output": "309200384"
},
{
"input": "78025 2308643 78025 4943733",
"output": "19974400"
},
{
"input": "3046068 2548438 2676145 4789979",
"output": "696930656"
},
{
"input": "4755258 2724358 2030900 4801065",
"output": "607089856"
},
{
"input": "1359689 3792971 4451626 4497236",
"output": "348080384"
},
{
"input": "3484483 3995744 87159 4941393",
"output": "131027072"
},
{
"input": "1273630 1273630 980163 1711706",
"output": "260312672"
},
{
"input": "2010798 1111442 4014004 4430228",
"output": "514764288"
},
{
"input": "1714940 133067 3346537 3346537",
"output": "439024640"
},
{
"input": "3731658 4548347 3731658 3731658",
"output": "955304448"
},
{
"input": "601597 2632066 450558 450558",
"output": "120176096"
},
{
"input": "726573 158002 568571 568571",
"output": "150610240"
},
{
"input": "407729 4510137 3425929 3425929",
"output": "104378624"
},
{
"input": "1781608 3826276 4384744 4384744",
"output": "456091648"
},
{
"input": "4486284 4486284 3249460 3249460",
"output": "871440128"
},
{
"input": "4759823 3520376 4743363 4743363",
"output": "1214827648"
},
{
"input": "386719 4643763 2749163 1701105",
"output": "99000064"
},
{
"input": "3173901 1042250 4102237 3173901",
"output": "812518656"
},
{
"input": "2681845 4558270 4388852 13014",
"output": "88734176"
},
{
"input": "1152975 910150 2776412 242825",
"output": "91288000"
},
{
"input": "2005366 3807065 4174270 2471686",
"output": "513373696"
},
{
"input": "2092196 2406694 3664886 85601",
"output": "86124896"
},
{
"input": "4542228 4542228 3992410 1039690",
"output": "378241856"
},
{
"input": "3093105 2256347 675644 570209",
"output": "218176608"
},
{
"input": "0 1 1 1",
"output": "0"
},
{
"input": "10 20 10 20",
"output": "2560"
},
{
"input": "0 0 5 1",
"output": "0"
},
{
"input": "10 0 10 11",
"output": "2560"
},
{
"input": "2 1 32768 65536",
"output": "512"
},
{
"input": "2 3 5 6",
"output": "512"
},
{
"input": "5 3 2 2",
"output": "608"
},
{
"input": "1 0 2 3",
"output": "256"
},
{
"input": "1 0 1 1",
"output": "256"
},
{
"input": "2 0 3 3",
"output": "512"
},
{
"input": "2 2 2 0",
"output": "64"
},
{
"input": "0 0 1 1",
"output": "0"
},
{
"input": "1 0 2 2",
"output": "256"
},
{
"input": "4 3 4 4",
"output": "1024"
},
{
"input": "5 1 5 6100",
"output": "1280"
}
] | 1,693,708,446
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 60
| 46
| 0
|
a, b, d, e = map(int, input().split())
c = 0
r = [a, d, e]
c += min(r) * 256
a -= min(r)
q = [a, b]
c += min(q) * 32
print(c)
|
Title: Anton and Digits
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Recently Anton found a box with digits in his room. There are *k*2 digits 2, *k*3 digits 3, *k*5 digits 5 and *k*6 digits 6.
Anton's favorite integers are 32 and 256. He decided to compose this integers from digits he has. He wants to make the sum of these integers as large as possible. Help him solve this task!
Each digit can be used no more than once, i.e. the composed integers should contain no more than *k*2 digits 2, *k*3 digits 3 and so on. Of course, unused digits are not counted in the sum.
Input Specification:
The only line of the input contains four integers *k*2, *k*3, *k*5 and *k*6 — the number of digits 2, 3, 5 and 6 respectively (0<=≤<=*k*2,<=*k*3,<=*k*5,<=*k*6<=≤<=5·106).
Output Specification:
Print one integer — maximum possible sum of Anton's favorite integers that can be composed using digits from the box.
Demo Input:
['5 1 3 4\n', '1 1 1 1\n']
Demo Output:
['800\n', '256\n']
Note:
In the first sample, there are five digits 2, one digit 3, three digits 5 and four digits 6. Anton can compose three integers 256 and one integer 32 to achieve the value 256 + 256 + 256 + 32 = 800. Note, that there is one unused integer 2 and one unused integer 6. They are not counted in the answer.
In the second sample, the optimal answer is to create on integer 256, thus the answer is 256.
|
```python
a, b, d, e = map(int, input().split())
c = 0
r = [a, d, e]
c += min(r) * 256
a -= min(r)
q = [a, b]
c += min(q) * 32
print(c)
```
| 3
|
|
284
|
B
|
Cows and Poker Game
|
PROGRAMMING
| 1,000
|
[
"brute force",
"implementation"
] | null | null |
There are *n* cows playing poker at a table. For the current betting phase, each player's status is either "ALLIN", "IN", or "FOLDED", and does not change throughout the phase. To increase the suspense, a player whose current status is not "FOLDED" may show his/her hand to the table. However, so as not to affect any betting decisions, he/she may only do so if all other players have a status of either "ALLIN" or "FOLDED". The player's own status may be either "ALLIN" or "IN".
Find the number of cows that can currently show their hands without affecting any betting decisions.
|
The first line contains a single integer, *n* (2<=≤<=*n*<=≤<=2·105). The second line contains *n* characters, each either "A", "I", or "F". The *i*-th character is "A" if the *i*-th player's status is "ALLIN", "I" if the *i*-th player's status is "IN", or "F" if the *i*-th player's status is "FOLDED".
|
The first line should contain a single integer denoting the number of players that can currently show their hands.
|
[
"6\nAFFAAA\n",
"3\nAFI\n"
] |
[
"4\n",
"1\n"
] |
In the first sample, cows 1, 4, 5, and 6 can show their hands. In the second sample, only cow 3 can show her hand.
| 1,000
|
[
{
"input": "6\nAFFAAA",
"output": "4"
},
{
"input": "3\nAFI",
"output": "1"
},
{
"input": "3\nFFF",
"output": "0"
},
{
"input": "3\nFIF",
"output": "1"
},
{
"input": "3\nAAA",
"output": "3"
},
{
"input": "3\nIII",
"output": "0"
},
{
"input": "3\nIIA",
"output": "0"
},
{
"input": "3\nAFF",
"output": "1"
},
{
"input": "5\nFAFFF",
"output": "1"
},
{
"input": "3\nIAA",
"output": "1"
},
{
"input": "3\nIIF",
"output": "0"
},
{
"input": "2\nFA",
"output": "1"
},
{
"input": "2\nFF",
"output": "0"
},
{
"input": "2\nIF",
"output": "1"
},
{
"input": "5\nAAAAI",
"output": "1"
},
{
"input": "5\nIIIIF",
"output": "0"
},
{
"input": "10\nAAAAAAAAAA",
"output": "10"
},
{
"input": "100\nAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA",
"output": "100"
},
{
"input": "5\nFAIAF",
"output": "1"
},
{
"input": "5\nAIAIF",
"output": "0"
},
{
"input": "5\nFAAII",
"output": "0"
},
{
"input": "5\nAIFFF",
"output": "1"
},
{
"input": "5\nAFAFA",
"output": "3"
},
{
"input": "2\nFA",
"output": "1"
},
{
"input": "8\nAFFFFIAF",
"output": "1"
},
{
"input": "8\nIAAIFFFI",
"output": "0"
},
{
"input": "5\nIIIII",
"output": "0"
}
] | 1,591,434,195
| 2,147,483,647
|
PyPy 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 7
| 2,000
| 9,728,000
|
a = int(input())
t = list(input())
p=0
for k in range(a):
if t[k]!='F':
if k==0:
if 'I' not in t[k+1:]:
p+=1
elif k==a-1:
if 'I' not in t[0:k]:
p+=1
else:
if 'I' not in t[0:k]:
if 'I' not in t[k+1:]:
p+=1
print(p)
|
Title: Cows and Poker Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are *n* cows playing poker at a table. For the current betting phase, each player's status is either "ALLIN", "IN", or "FOLDED", and does not change throughout the phase. To increase the suspense, a player whose current status is not "FOLDED" may show his/her hand to the table. However, so as not to affect any betting decisions, he/she may only do so if all other players have a status of either "ALLIN" or "FOLDED". The player's own status may be either "ALLIN" or "IN".
Find the number of cows that can currently show their hands without affecting any betting decisions.
Input Specification:
The first line contains a single integer, *n* (2<=≤<=*n*<=≤<=2·105). The second line contains *n* characters, each either "A", "I", or "F". The *i*-th character is "A" if the *i*-th player's status is "ALLIN", "I" if the *i*-th player's status is "IN", or "F" if the *i*-th player's status is "FOLDED".
Output Specification:
The first line should contain a single integer denoting the number of players that can currently show their hands.
Demo Input:
['6\nAFFAAA\n', '3\nAFI\n']
Demo Output:
['4\n', '1\n']
Note:
In the first sample, cows 1, 4, 5, and 6 can show their hands. In the second sample, only cow 3 can show her hand.
|
```python
a = int(input())
t = list(input())
p=0
for k in range(a):
if t[k]!='F':
if k==0:
if 'I' not in t[k+1:]:
p+=1
elif k==a-1:
if 'I' not in t[0:k]:
p+=1
else:
if 'I' not in t[0:k]:
if 'I' not in t[k+1:]:
p+=1
print(p)
```
| 0
|
|
486
|
A
|
Calculating Function
|
PROGRAMMING
| 800
|
[
"implementation",
"math"
] | null | null |
For a positive integer *n* let's define a function *f*:
*f*(*n*)<==<=<=-<=1<=+<=2<=-<=3<=+<=..<=+<=(<=-<=1)*n**n*
Your task is to calculate *f*(*n*) for a given integer *n*.
|
The single line contains the positive integer *n* (1<=≤<=*n*<=≤<=1015).
|
Print *f*(*n*) in a single line.
|
[
"4\n",
"5\n"
] |
[
"2\n",
"-3\n"
] |
*f*(4) = - 1 + 2 - 3 + 4 = 2
*f*(5) = - 1 + 2 - 3 + 4 - 5 = - 3
| 500
|
[
{
"input": "4",
"output": "2"
},
{
"input": "5",
"output": "-3"
},
{
"input": "1000000000",
"output": "500000000"
},
{
"input": "1000000001",
"output": "-500000001"
},
{
"input": "1000000000000000",
"output": "500000000000000"
},
{
"input": "100",
"output": "50"
},
{
"input": "101",
"output": "-51"
},
{
"input": "102",
"output": "51"
},
{
"input": "103",
"output": "-52"
},
{
"input": "104",
"output": "52"
},
{
"input": "105",
"output": "-53"
},
{
"input": "106",
"output": "53"
},
{
"input": "107",
"output": "-54"
},
{
"input": "108",
"output": "54"
},
{
"input": "109",
"output": "-55"
},
{
"input": "208170109961052",
"output": "104085054980526"
},
{
"input": "46017661651072",
"output": "23008830825536"
},
{
"input": "4018154546667",
"output": "-2009077273334"
},
{
"input": "288565475053",
"output": "-144282737527"
},
{
"input": "3052460231",
"output": "-1526230116"
},
{
"input": "29906716",
"output": "14953358"
},
{
"input": "87897701693326",
"output": "43948850846663"
},
{
"input": "8240",
"output": "4120"
},
{
"input": "577935",
"output": "-288968"
},
{
"input": "62",
"output": "31"
},
{
"input": "1",
"output": "-1"
},
{
"input": "2",
"output": "1"
},
{
"input": "9999999999999",
"output": "-5000000000000"
},
{
"input": "1000000000000",
"output": "500000000000"
},
{
"input": "99999999999999",
"output": "-50000000000000"
},
{
"input": "999999999999999",
"output": "-500000000000000"
},
{
"input": "42191359342",
"output": "21095679671"
},
{
"input": "100000000000000",
"output": "50000000000000"
},
{
"input": "145645214654154",
"output": "72822607327077"
},
{
"input": "4294967296",
"output": "2147483648"
},
{
"input": "3037000499",
"output": "-1518500250"
},
{
"input": "10000000000001",
"output": "-5000000000001"
},
{
"input": "100000017040846",
"output": "50000008520423"
},
{
"input": "98979894985999",
"output": "-49489947493000"
}
] | 1,693,496,134
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 0
| 30
| 0
|
print("Hello 31")
|
Title: Calculating Function
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
For a positive integer *n* let's define a function *f*:
*f*(*n*)<==<=<=-<=1<=+<=2<=-<=3<=+<=..<=+<=(<=-<=1)*n**n*
Your task is to calculate *f*(*n*) for a given integer *n*.
Input Specification:
The single line contains the positive integer *n* (1<=≤<=*n*<=≤<=1015).
Output Specification:
Print *f*(*n*) in a single line.
Demo Input:
['4\n', '5\n']
Demo Output:
['2\n', '-3\n']
Note:
*f*(4) = - 1 + 2 - 3 + 4 = 2
*f*(5) = - 1 + 2 - 3 + 4 - 5 = - 3
|
```python
print("Hello 31")
```
| 0
|
|
75
|
A
|
Life Without Zeros
|
PROGRAMMING
| 1,000
|
[
"implementation"
] |
A. Life Without Zeros
|
2
|
256
|
Can you imagine our life if we removed all zeros from it? For sure we will have many problems.
In this problem we will have a simple example if we removed all zeros from our life, it's the addition operation. Let's assume you are given this equation *a*<=+<=*b*<==<=*c*, where *a* and *b* are positive integers, and *c* is the sum of *a* and *b*. Now let's remove all zeros from this equation. Will the equation remain correct after removing all zeros?
For example if the equation is 101<=+<=102<==<=203, if we removed all zeros it will be 11<=+<=12<==<=23 which is still a correct equation.
But if the equation is 105<=+<=106<==<=211, if we removed all zeros it will be 15<=+<=16<==<=211 which is not a correct equation.
|
The input will consist of two lines, the first line will contain the integer *a*, and the second line will contain the integer *b* which are in the equation as described above (1<=≤<=*a*,<=*b*<=≤<=109). There won't be any leading zeros in both. The value of *c* should be calculated as *c*<==<=*a*<=+<=*b*.
|
The output will be just one line, you should print "YES" if the equation will remain correct after removing all zeros, and print "NO" otherwise.
|
[
"101\n102\n",
"105\n106\n"
] |
[
"YES\n",
"NO\n"
] |
none
| 500
|
[
{
"input": "101\n102",
"output": "YES"
},
{
"input": "105\n106",
"output": "NO"
},
{
"input": "544\n397",
"output": "YES"
},
{
"input": "822\n280",
"output": "NO"
},
{
"input": "101\n413",
"output": "NO"
},
{
"input": "309\n139",
"output": "NO"
},
{
"input": "693\n970",
"output": "NO"
},
{
"input": "981\n1",
"output": "YES"
},
{
"input": "352\n276",
"output": "YES"
},
{
"input": "164\n691",
"output": "YES"
},
{
"input": "110036\n43",
"output": "YES"
},
{
"input": "100\n1000",
"output": "NO"
},
{
"input": "1000000000\n1000000000",
"output": "YES"
},
{
"input": "999999999\n999999999",
"output": "YES"
},
{
"input": "6\n4",
"output": "NO"
},
{
"input": "123456\n876543",
"output": "YES"
},
{
"input": "1234567\n9876543",
"output": "NO"
},
{
"input": "1111111\n1119111",
"output": "NO"
},
{
"input": "10502405\n40403403",
"output": "YES"
},
{
"input": "1\n1",
"output": "YES"
},
{
"input": "5\n4",
"output": "YES"
},
{
"input": "1\n6",
"output": "YES"
},
{
"input": "40\n17",
"output": "NO"
},
{
"input": "35\n81",
"output": "YES"
},
{
"input": "347\n908",
"output": "NO"
},
{
"input": "2081\n7450",
"output": "NO"
},
{
"input": "84355694\n373629503",
"output": "NO"
},
{
"input": "885992048\n510468672",
"output": "NO"
},
{
"input": "540144752\n647307841",
"output": "NO"
},
{
"input": "341781108\n784147010",
"output": "NO"
},
{
"input": "960440938\n572334653",
"output": "NO"
},
{
"input": "657414510\n768771903",
"output": "NO"
},
{
"input": "501871728\n725074574",
"output": "NO"
},
{
"input": "968\n851",
"output": "YES"
},
{
"input": "943\n939",
"output": "YES"
},
{
"input": "347\n908",
"output": "NO"
},
{
"input": "611\n41",
"output": "YES"
},
{
"input": "737\n289",
"output": "NO"
},
{
"input": "168\n571",
"output": "YES"
},
{
"input": "868\n463",
"output": "YES"
},
{
"input": "815732007\n913882008",
"output": "NO"
},
{
"input": "459039901\n453033850",
"output": "NO"
},
{
"input": "975305404\n484601256",
"output": "NO"
}
] | 1,626,010,779
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 124
| 0
|
a = int(input())
b = int(input())
c = a + b
A = a // 10
B = b // 10
C = c // 10
if A + B == C:
print("YES")
else:
print("NO")
|
Title: Life Without Zeros
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Can you imagine our life if we removed all zeros from it? For sure we will have many problems.
In this problem we will have a simple example if we removed all zeros from our life, it's the addition operation. Let's assume you are given this equation *a*<=+<=*b*<==<=*c*, where *a* and *b* are positive integers, and *c* is the sum of *a* and *b*. Now let's remove all zeros from this equation. Will the equation remain correct after removing all zeros?
For example if the equation is 101<=+<=102<==<=203, if we removed all zeros it will be 11<=+<=12<==<=23 which is still a correct equation.
But if the equation is 105<=+<=106<==<=211, if we removed all zeros it will be 15<=+<=16<==<=211 which is not a correct equation.
Input Specification:
The input will consist of two lines, the first line will contain the integer *a*, and the second line will contain the integer *b* which are in the equation as described above (1<=≤<=*a*,<=*b*<=≤<=109). There won't be any leading zeros in both. The value of *c* should be calculated as *c*<==<=*a*<=+<=*b*.
Output Specification:
The output will be just one line, you should print "YES" if the equation will remain correct after removing all zeros, and print "NO" otherwise.
Demo Input:
['101\n102\n', '105\n106\n']
Demo Output:
['YES\n', 'NO\n']
Note:
none
|
```python
a = int(input())
b = int(input())
c = a + b
A = a // 10
B = b // 10
C = c // 10
if A + B == C:
print("YES")
else:
print("NO")
```
| 0
|
472
|
A
|
Design Tutorial: Learn from Math
|
PROGRAMMING
| 800
|
[
"math",
"number theory"
] | null | null |
One way to create a task is to learn from math. You can generate some random math statement or modify some theorems to get something new and build a new task from that.
For example, there is a statement called the "Goldbach's conjecture". It says: "each even number no less than four can be expressed as the sum of two primes". Let's modify it. How about a statement like that: "each integer no less than 12 can be expressed as the sum of two composite numbers." Not like the Goldbach's conjecture, I can prove this theorem.
You are given an integer *n* no less than 12, express it as a sum of two composite numbers.
|
The only line contains an integer *n* (12<=≤<=*n*<=≤<=106).
|
Output two composite integers *x* and *y* (1<=<<=*x*,<=*y*<=<<=*n*) such that *x*<=+<=*y*<==<=*n*. If there are multiple solutions, you can output any of them.
|
[
"12\n",
"15\n",
"23\n",
"1000000\n"
] |
[
"4 8\n",
"6 9\n",
"8 15\n",
"500000 500000\n"
] |
In the first example, 12 = 4 + 8 and both 4, 8 are composite numbers. You can output "6 6" or "8 4" as well.
In the second example, 15 = 6 + 9. Note that you can't output "1 14" because 1 is not a composite number.
| 500
|
[
{
"input": "12",
"output": "4 8"
},
{
"input": "15",
"output": "6 9"
},
{
"input": "23",
"output": "8 15"
},
{
"input": "1000000",
"output": "500000 500000"
},
{
"input": "63874",
"output": "4 63870"
},
{
"input": "14568",
"output": "4 14564"
},
{
"input": "192",
"output": "4 188"
},
{
"input": "86",
"output": "4 82"
},
{
"input": "46220",
"output": "4 46216"
},
{
"input": "57114",
"output": "4 57110"
},
{
"input": "869",
"output": "4 865"
},
{
"input": "738457",
"output": "4 738453"
},
{
"input": "58113",
"output": "6 58107"
},
{
"input": "4864",
"output": "4 4860"
},
{
"input": "15",
"output": "6 9"
},
{
"input": "74752",
"output": "4 74748"
},
{
"input": "6073",
"output": "4 6069"
},
{
"input": "1289",
"output": "4 1285"
},
{
"input": "20",
"output": "4 16"
},
{
"input": "58134",
"output": "4 58130"
},
{
"input": "57756",
"output": "4 57752"
},
{
"input": "765",
"output": "6 759"
},
{
"input": "59",
"output": "4 55"
},
{
"input": "991666",
"output": "4 991662"
},
{
"input": "70761",
"output": "4 70757"
},
{
"input": "13",
"output": "4 9"
},
{
"input": "999999",
"output": "4 999995"
},
{
"input": "17",
"output": "8 9"
},
{
"input": "21",
"output": "6 15"
},
{
"input": "19",
"output": "4 15"
},
{
"input": "100007",
"output": "6 100001"
},
{
"input": "999987",
"output": "6 999981"
},
{
"input": "22",
"output": "4 18"
}
] | 1,695,484,108
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 33
| 61
| 1,331,200
|
def isPrime(n):
if n == 0 or n == 1:
return True
for i in range(2,n//2+1):
if n % i == 0:
return False
return True
n = int(input())
for i in range(2,n):
if (not isPrime(i)) and (not isPrime(n - i)):
print(i,n-i)
break
|
Title: Design Tutorial: Learn from Math
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One way to create a task is to learn from math. You can generate some random math statement or modify some theorems to get something new and build a new task from that.
For example, there is a statement called the "Goldbach's conjecture". It says: "each even number no less than four can be expressed as the sum of two primes". Let's modify it. How about a statement like that: "each integer no less than 12 can be expressed as the sum of two composite numbers." Not like the Goldbach's conjecture, I can prove this theorem.
You are given an integer *n* no less than 12, express it as a sum of two composite numbers.
Input Specification:
The only line contains an integer *n* (12<=≤<=*n*<=≤<=106).
Output Specification:
Output two composite integers *x* and *y* (1<=<<=*x*,<=*y*<=<<=*n*) such that *x*<=+<=*y*<==<=*n*. If there are multiple solutions, you can output any of them.
Demo Input:
['12\n', '15\n', '23\n', '1000000\n']
Demo Output:
['4 8\n', '6 9\n', '8 15\n', '500000 500000\n']
Note:
In the first example, 12 = 4 + 8 and both 4, 8 are composite numbers. You can output "6 6" or "8 4" as well.
In the second example, 15 = 6 + 9. Note that you can't output "1 14" because 1 is not a composite number.
|
```python
def isPrime(n):
if n == 0 or n == 1:
return True
for i in range(2,n//2+1):
if n % i == 0:
return False
return True
n = int(input())
for i in range(2,n):
if (not isPrime(i)) and (not isPrime(n - i)):
print(i,n-i)
break
```
| 3
|
|
699
|
A
|
Launch of Collider
|
PROGRAMMING
| 1,000
|
[
"implementation"
] | null | null |
There will be a launch of a new, powerful and unusual collider very soon, which located along a straight line. *n* particles will be launched inside it. All of them are located in a straight line and there can not be two or more particles located in the same point. The coordinates of the particles coincide with the distance in meters from the center of the collider, *x**i* is the coordinate of the *i*-th particle and its position in the collider at the same time. All coordinates of particle positions are even integers.
You know the direction of each particle movement — it will move to the right or to the left after the collider's launch start. All particles begin to move simultaneously at the time of the collider's launch start. Each particle will move straight to the left or straight to the right with the constant speed of 1 meter per microsecond. The collider is big enough so particles can not leave it in the foreseeable time.
Write the program which finds the moment of the first collision of any two particles of the collider. In other words, find the number of microseconds before the first moment when any two particles are at the same point.
|
The first line contains the positive integer *n* (1<=≤<=*n*<=≤<=200<=000) — the number of particles.
The second line contains *n* symbols "L" and "R". If the *i*-th symbol equals "L", then the *i*-th particle will move to the left, otherwise the *i*-th symbol equals "R" and the *i*-th particle will move to the right.
The third line contains the sequence of pairwise distinct even integers *x*1,<=*x*2,<=...,<=*x**n* (0<=≤<=*x**i*<=≤<=109) — the coordinates of particles in the order from the left to the right. It is guaranteed that the coordinates of particles are given in the increasing order.
|
In the first line print the only integer — the first moment (in microseconds) when two particles are at the same point and there will be an explosion.
Print the only integer -1, if the collision of particles doesn't happen.
|
[
"4\nRLRL\n2 4 6 10\n",
"3\nLLR\n40 50 60\n"
] |
[
"1\n",
"-1\n"
] |
In the first sample case the first explosion will happen in 1 microsecond because the particles number 1 and 2 will simultaneously be at the same point with the coordinate 3.
In the second sample case there will be no explosion because there are no particles which will simultaneously be at the same point.
| 500
|
[
{
"input": "4\nRLRL\n2 4 6 10",
"output": "1"
},
{
"input": "3\nLLR\n40 50 60",
"output": "-1"
},
{
"input": "4\nRLLR\n46 230 264 470",
"output": "92"
},
{
"input": "6\nLLRLLL\n446 492 650 844 930 970",
"output": "97"
},
{
"input": "8\nRRLLLLLL\n338 478 512 574 594 622 834 922",
"output": "17"
},
{
"input": "10\nLRLRLLRRLR\n82 268 430 598 604 658 670 788 838 1000",
"output": "3"
},
{
"input": "2\nRL\n0 1000000000",
"output": "500000000"
},
{
"input": "12\nLRLLRRRRLRLL\n254 1260 1476 1768 2924 4126 4150 4602 5578 7142 8134 9082",
"output": "108"
},
{
"input": "14\nRLLRRLRLLRLLLR\n698 2900 3476 3724 3772 3948 4320 4798 5680 6578 7754 8034 8300 8418",
"output": "88"
},
{
"input": "16\nRRLLLRLRLLLLRLLR\n222 306 968 1060 1636 1782 2314 2710 3728 4608 5088 6790 6910 7156 7418 7668",
"output": "123"
},
{
"input": "18\nRLRLLRRRLLLRLRRLRL\n1692 2028 2966 3008 3632 4890 5124 5838 6596 6598 6890 8294 8314 8752 8868 9396 9616 9808",
"output": "10"
},
{
"input": "20\nRLLLLLLLRRRRLRRLRRLR\n380 902 1400 1834 2180 2366 2562 2596 2702 2816 3222 3238 3742 5434 6480 7220 7410 8752 9708 9970",
"output": "252"
},
{
"input": "22\nLRRRRRRRRRRRLLRRRRRLRL\n1790 2150 2178 2456 2736 3282 3622 4114 4490 4772 5204 5240 5720 5840 5910 5912 6586 7920 8584 9404 9734 9830",
"output": "48"
},
{
"input": "24\nLLRLRRLLRLRRRRLLRRLRLRRL\n100 360 864 1078 1360 1384 1438 2320 2618 3074 3874 3916 3964 5178 5578 6278 6630 6992 8648 8738 8922 8930 9276 9720",
"output": "27"
},
{
"input": "26\nRLLLLLLLRLRRLRLRLRLRLLLRRR\n908 1826 2472 2474 2728 3654 3716 3718 3810 3928 4058 4418 4700 5024 5768 6006 6128 6386 6968 7040 7452 7774 7822 8726 9338 9402",
"output": "59"
},
{
"input": "28\nRRLRLRRRRRRLLLRRLRRLLLRRLLLR\n156 172 1120 1362 2512 3326 3718 4804 4990 5810 6242 6756 6812 6890 6974 7014 7088 7724 8136 8596 8770 8840 9244 9250 9270 9372 9400 9626",
"output": "10"
},
{
"input": "30\nRLLRLRLLRRRLRRRLLLLLLRRRLRRLRL\n128 610 1680 2436 2896 2994 3008 3358 3392 4020 4298 4582 4712 4728 5136 5900 6088 6232 6282 6858 6934 7186 7224 7256 7614 8802 8872 9170 9384 9794",
"output": "7"
},
{
"input": "10\nLLLLRRRRRR\n0 2 4 6 8 10 12 14 16 18",
"output": "-1"
},
{
"input": "5\nLLLLL\n0 10 20 30 40",
"output": "-1"
},
{
"input": "6\nRRRRRR\n40 50 60 70 80 100",
"output": "-1"
},
{
"input": "1\nR\n0",
"output": "-1"
},
{
"input": "2\nRL\n2 1000000000",
"output": "499999999"
},
{
"input": "2\nRL\n0 400000",
"output": "200000"
},
{
"input": "2\nRL\n0 200002",
"output": "100001"
},
{
"input": "2\nRL\n2 20000000",
"output": "9999999"
},
{
"input": "4\nLLRL\n2 4 10 100",
"output": "45"
},
{
"input": "4\nRLRL\n2 10 12 14",
"output": "1"
},
{
"input": "2\nRL\n0 100000000",
"output": "50000000"
},
{
"input": "2\nRL\n2 600002",
"output": "300000"
},
{
"input": "1\nL\n0",
"output": "-1"
},
{
"input": "2\nRL\n0 600000",
"output": "300000"
},
{
"input": "5\nRRRRR\n0 2 4 6 8",
"output": "-1"
},
{
"input": "2\nRL\n2 200000000",
"output": "99999999"
},
{
"input": "2\nRL\n0 267382766",
"output": "133691383"
},
{
"input": "3\nRRL\n4 8 999999998",
"output": "499999995"
},
{
"input": "2\nRL\n0 2",
"output": "1"
},
{
"input": "2\nRL\n2 400002",
"output": "200000"
},
{
"input": "2\nLL\n2 4",
"output": "-1"
},
{
"input": "2\nLL\n0 2",
"output": "-1"
},
{
"input": "2\nRL\n0 100000",
"output": "50000"
},
{
"input": "2\nRL\n2 200000020",
"output": "100000009"
},
{
"input": "2\nRL\n2000000 4000000",
"output": "1000000"
},
{
"input": "2\nRL\n0 199998",
"output": "99999"
},
{
"input": "3\nLRR\n40 50 60",
"output": "-1"
},
{
"input": "2\nRL\n200 400400",
"output": "200100"
},
{
"input": "2\nRL\n2 400004",
"output": "200001"
},
{
"input": "2\nRL\n0 200000000",
"output": "100000000"
}
] | 1,588,239,657
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 85
| 233
| 13,516,800
|
# https://codeforces.com/contest/699/problem/A
n = int(input())
particles = input()
positions = map(int, input().split())
temp = None
ans = float('inf')
for p, x in zip(particles, positions):
if temp is None:
if p == "R":
temp = x
else:
if p == "R":
temp = x
if p == "L":
if abs(temp - x) < ans:
ans = abs(temp - x)
if ans == float('inf'):
print(-1)
else:
print(ans//2)
|
Title: Launch of Collider
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There will be a launch of a new, powerful and unusual collider very soon, which located along a straight line. *n* particles will be launched inside it. All of them are located in a straight line and there can not be two or more particles located in the same point. The coordinates of the particles coincide with the distance in meters from the center of the collider, *x**i* is the coordinate of the *i*-th particle and its position in the collider at the same time. All coordinates of particle positions are even integers.
You know the direction of each particle movement — it will move to the right or to the left after the collider's launch start. All particles begin to move simultaneously at the time of the collider's launch start. Each particle will move straight to the left or straight to the right with the constant speed of 1 meter per microsecond. The collider is big enough so particles can not leave it in the foreseeable time.
Write the program which finds the moment of the first collision of any two particles of the collider. In other words, find the number of microseconds before the first moment when any two particles are at the same point.
Input Specification:
The first line contains the positive integer *n* (1<=≤<=*n*<=≤<=200<=000) — the number of particles.
The second line contains *n* symbols "L" and "R". If the *i*-th symbol equals "L", then the *i*-th particle will move to the left, otherwise the *i*-th symbol equals "R" and the *i*-th particle will move to the right.
The third line contains the sequence of pairwise distinct even integers *x*1,<=*x*2,<=...,<=*x**n* (0<=≤<=*x**i*<=≤<=109) — the coordinates of particles in the order from the left to the right. It is guaranteed that the coordinates of particles are given in the increasing order.
Output Specification:
In the first line print the only integer — the first moment (in microseconds) when two particles are at the same point and there will be an explosion.
Print the only integer -1, if the collision of particles doesn't happen.
Demo Input:
['4\nRLRL\n2 4 6 10\n', '3\nLLR\n40 50 60\n']
Demo Output:
['1\n', '-1\n']
Note:
In the first sample case the first explosion will happen in 1 microsecond because the particles number 1 and 2 will simultaneously be at the same point with the coordinate 3.
In the second sample case there will be no explosion because there are no particles which will simultaneously be at the same point.
|
```python
# https://codeforces.com/contest/699/problem/A
n = int(input())
particles = input()
positions = map(int, input().split())
temp = None
ans = float('inf')
for p, x in zip(particles, positions):
if temp is None:
if p == "R":
temp = x
else:
if p == "R":
temp = x
if p == "L":
if abs(temp - x) < ans:
ans = abs(temp - x)
if ans == float('inf'):
print(-1)
else:
print(ans//2)
```
| 3
|
|
815
|
A
|
Karen and Game
|
PROGRAMMING
| 1,700
|
[
"brute force",
"greedy",
"implementation"
] | null | null |
On the way to school, Karen became fixated on the puzzle game on her phone!
The game is played as follows. In each level, you have a grid with *n* rows and *m* columns. Each cell originally contains the number 0.
One move consists of choosing one row or column, and adding 1 to all of the cells in that row or column.
To win the level, after all the moves, the number in the cell at the *i*-th row and *j*-th column should be equal to *g**i*,<=*j*.
Karen is stuck on one level, and wants to know a way to beat this level using the minimum number of moves. Please, help her with this task!
|
The first line of input contains two integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), the number of rows and the number of columns in the grid, respectively.
The next *n* lines each contain *m* integers. In particular, the *j*-th integer in the *i*-th of these rows contains *g**i*,<=*j* (0<=≤<=*g**i*,<=*j*<=≤<=500).
|
If there is an error and it is actually not possible to beat the level, output a single integer -1.
Otherwise, on the first line, output a single integer *k*, the minimum number of moves necessary to beat the level.
The next *k* lines should each contain one of the following, describing the moves in the order they must be done:
- row *x*, (1<=≤<=*x*<=≤<=*n*) describing a move of the form "choose the *x*-th row". - col *x*, (1<=≤<=*x*<=≤<=*m*) describing a move of the form "choose the *x*-th column".
If there are multiple optimal solutions, output any one of them.
|
[
"3 5\n2 2 2 3 2\n0 0 0 1 0\n1 1 1 2 1\n",
"3 3\n0 0 0\n0 1 0\n0 0 0\n",
"3 3\n1 1 1\n1 1 1\n1 1 1\n"
] |
[
"4\nrow 1\nrow 1\ncol 4\nrow 3\n",
"-1\n",
"3\nrow 1\nrow 2\nrow 3\n"
] |
In the first test case, Karen has a grid with 3 rows and 5 columns. She can perform the following 4 moves to beat the level:
In the second test case, Karen has a grid with 3 rows and 3 columns. It is clear that it is impossible to beat the level; performing any move will create three 1s on the grid, but it is required to only have one 1 in the center.
In the third test case, Karen has a grid with 3 rows and 3 columns. She can perform the following 3 moves to beat the level:
Note that this is not the only solution; another solution, among others, is col 1, col 2, col 3.
| 500
|
[
{
"input": "3 5\n2 2 2 3 2\n0 0 0 1 0\n1 1 1 2 1",
"output": "4\nrow 1\nrow 1\ncol 4\nrow 3"
},
{
"input": "3 3\n0 0 0\n0 1 0\n0 0 0",
"output": "-1"
},
{
"input": "3 3\n1 1 1\n1 1 1\n1 1 1",
"output": "3\nrow 1\nrow 2\nrow 3"
},
{
"input": "3 5\n2 4 2 2 3\n0 2 0 0 1\n1 3 1 1 2",
"output": "6\nrow 1\nrow 1\ncol 2\ncol 2\ncol 5\nrow 3"
},
{
"input": "3 5\n0 0 0 0 0\n0 0 0 0 0\n0 0 0 0 1",
"output": "-1"
},
{
"input": "9 10\n14 5 6 4 8 9 4 14 14 13\n13 4 5 3 7 8 3 13 13 12\n16 7 8 6 10 11 6 16 16 15\n10 1 2 0 4 5 0 10 10 9\n11 2 3 1 5 6 1 11 11 10\n10 1 2 0 4 5 0 10 10 9\n12 3 4 2 6 7 2 12 12 11\n13 4 5 3 7 8 3 13 13 12\n13 4 5 3 7 8 3 13 13 12",
"output": "73\nrow 1\nrow 1\nrow 1\nrow 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 2\ncol 3\ncol 3\ncol 5\ncol 5\ncol 5\ncol 5\ncol 6\ncol 6\ncol 6\ncol 6\ncol 6\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 8\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 10\ncol 10\ncol 10\ncol 10\ncol 10\ncol 10\ncol 10\ncol 10\ncol 10\nrow 2\nrow 2\nrow 2\nrow 3\nrow 3\nrow 3\nrow 3\nrow 3\nrow 3\nrow 5\nrow 7\nrow 7\nrow 8\nrow 8\nrow 8\nrow 9\nr..."
},
{
"input": "10 10\n30 30 30 33 30 33 30 33 30 33\n431 431 431 434 431 434 431 434 431 434\n19 19 19 22 19 22 19 22 19 22\n24 24 24 27 24 27 24 27 24 27\n5 5 5 8 5 8 5 8 5 8\n0 0 0 3 0 3 0 3 0 3\n0 0 0 3 0 3 0 3 0 3\n0 0 0 3 0 3 0 3 0 3\n0 0 0 3 0 3 0 3 0 3\n0 0 0 3 0 3 0 3 0 3",
"output": "521\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\ncol 4\ncol 4\ncol 4\ncol 6\ncol 6\ncol 6\ncol 8\ncol 8\ncol 8\ncol 10\ncol 10\ncol 10\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\n..."
},
{
"input": "1 1\n0",
"output": "0"
},
{
"input": "1 1\n500",
"output": "500\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nro..."
},
{
"input": "10 10\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n0 0 0 0 0 0 0 0 0 0\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1\n1 1 1 1 1 1 1 1 1 1",
"output": "9\nrow 1\nrow 2\nrow 3\nrow 4\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10"
},
{
"input": "10 10\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1\n1 1 1 1 1 1 0 1 1 1",
"output": "9\ncol 1\ncol 2\ncol 3\ncol 4\ncol 5\ncol 6\ncol 8\ncol 9\ncol 10"
},
{
"input": "10 11\n8 7 10 15 5 13 12 9 14 11 6\n6 5 8 13 3 11 10 7 12 9 4\n10 9 12 17 7 15 14 11 16 13 8\n9 8 11 16 6 14 13 10 15 12 7\n12 11 14 19 9 17 16 13 18 15 10\n14 13 16 21 11 19 18 15 20 17 12\n7 6 9 14 4 12 11 8 13 10 5\n5 4 7 12 2 10 9 6 11 8 3\n11 10 13 18 8 16 15 12 17 14 9\n13 12 15 20 10 18 17 14 19 16 11",
"output": "120\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 1\nrow 1\ncol 1\ncol 1\ncol 1\ncol 2\ncol 2\ncol 3\ncol 3\ncol 3\ncol 3\ncol 3\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 4\ncol 6\ncol 6\ncol 6\ncol 6\ncol 6\ncol 6\ncol 6\ncol 6\ncol 7\ncol 7\ncol 7\ncol 7\ncol 7\ncol 7\ncol 7\ncol 8\ncol 8\ncol 8\ncol 8\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 9\ncol 10\n..."
},
{
"input": "5 3\n2 2 2\n2 2 2\n2 2 2\n1 1 1\n2 2 2",
"output": "7\ncol 1\ncol 2\ncol 3\nrow 1\nrow 2\nrow 3\nrow 5"
},
{
"input": "3 5\n2 2 2 1 2\n2 2 2 1 2\n2 2 2 1 2",
"output": "7\nrow 1\nrow 2\nrow 3\ncol 1\ncol 2\ncol 3\ncol 5"
},
{
"input": "1 100\n396 314 350 362 287 349 266 289 297 305 235 226 256 385 302 304 253 192 298 238 360 366 163 340 247 395 318 260 252 281 178 188 252 379 212 187 354 232 225 159 290 335 387 234 383 215 356 182 323 280 195 209 263 215 322 262 334 157 189 214 195 386 220 209 177 193 368 174 270 329 388 237 260 343 230 173 254 371 327 266 193 178 161 209 335 310 323 323 353 172 368 307 329 234 363 264 334 266 305 209",
"output": "11960\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\n..."
},
{
"input": "100 1\n173\n164\n99\n114\n255\n223\n280\n235\n207\n190\n136\n204\n206\n282\n253\n335\n267\n184\n288\n299\n263\n243\n341\n111\n278\n111\n214\n133\n125\n245\n99\n144\n232\n203\n131\n204\n117\n315\n269\n206\n262\n125\n212\n95\n220\n243\n141\n163\n311\n171\n222\n266\n141\n314\n329\n138\n187\n342\n272\n181\n300\n261\n339\n110\n194\n187\n183\n129\n151\n187\n129\n185\n322\n167\n99\n340\n285\n99\n176\n175\n272\n126\n220\n164\n237\n214\n96\n162\n129\n141\n144\n135\n172\n191\n155\n333\n186\n324\n237\n318",
"output": "11282\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\n..."
},
{
"input": "1 100\n0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "0"
},
{
"input": "100 1\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0",
"output": "0"
},
{
"input": "1 100\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "1\nrow 1"
},
{
"input": "100 1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "1 100\n500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500 500",
"output": "500\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nro..."
},
{
"input": "100 1\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500\n500",
"output": "500\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\nco..."
},
{
"input": "2 1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "4 3\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "3\ncol 1\ncol 2\ncol 3"
},
{
"input": "2 1\n2\n2",
"output": "2\ncol 1\ncol 1"
},
{
"input": "3 2\n1 1\n1 1\n1 1",
"output": "2\ncol 1\ncol 2"
},
{
"input": "2 1\n1\n2",
"output": "2\ncol 1\nrow 2"
},
{
"input": "2 3\n1 1 1\n1 1 1",
"output": "2\nrow 1\nrow 2"
},
{
"input": "1 2\n1 1",
"output": "1\nrow 1"
},
{
"input": "5 1\n1\n1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "10 3\n101 201 301\n102 202 302\n103 203 303\n104 204 304\n105 205 305\n106 206 306\n107 207 307\n108 208 308\n109 209 309\n111 211 311",
"output": "649\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\nco..."
},
{
"input": "2 1\n10\n10",
"output": "10\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1"
},
{
"input": "4 3\n2 2 2\n2 2 2\n2 2 2\n2 2 2",
"output": "6\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3"
},
{
"input": "3 1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "8 2\n2 2\n2 2\n2 2\n2 2\n2 2\n2 2\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "1 2\n2 2",
"output": "2\nrow 1\nrow 1"
},
{
"input": "3 2\n2 3\n2 3\n2 3",
"output": "5\ncol 1\ncol 2\ncol 1\ncol 2\ncol 2"
},
{
"input": "2 1\n3\n3",
"output": "3\ncol 1\ncol 1\ncol 1"
},
{
"input": "6 2\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1",
"output": "2\ncol 1\ncol 2"
},
{
"input": "4 1\n1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "2 5\n1 1 1 1 1\n1 1 1 1 1",
"output": "2\nrow 1\nrow 2"
},
{
"input": "3 1\n500\n500\n500",
"output": "500\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\nco..."
},
{
"input": "5 2\n1 1\n2 2\n2 2\n2 2\n2 2",
"output": "6\ncol 1\ncol 2\nrow 2\nrow 3\nrow 4\nrow 5"
},
{
"input": "4 3\n3 3 3\n3 3 3\n3 3 3\n3 3 3",
"output": "9\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3"
},
{
"input": "5 2\n1 1\n1 1\n1 1\n1 1\n1 1",
"output": "2\ncol 1\ncol 2"
},
{
"input": "1 4\n1 1 1 1",
"output": "1\nrow 1"
},
{
"input": "3 1\n2\n3\n2",
"output": "3\ncol 1\ncol 1\nrow 2"
},
{
"input": "1 5\n1 1 1 1 1",
"output": "1\nrow 1"
},
{
"input": "2 4\n3 1 1 1\n3 1 1 1",
"output": "4\nrow 1\nrow 2\ncol 1\ncol 1"
},
{
"input": "3 3\n1 1 1\n0 1 0\n0 0 0",
"output": "-1"
},
{
"input": "3 2\n2 2\n1 1\n2 2",
"output": "4\ncol 1\ncol 2\nrow 1\nrow 3"
},
{
"input": "2 1\n9\n9",
"output": "9\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1"
},
{
"input": "1 7\n3 3 3 3 3 3 3",
"output": "3\nrow 1\nrow 1\nrow 1"
},
{
"input": "5 2\n3 3\n3 3\n3 3\n3 3\n3 3",
"output": "6\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "10 11\n250 198 192 182 85 239 295 91 318 216 249\n290 238 232 222 125 279 335 131 358 256 289\n409 357 351 341 244 398 454 250 477 375 408\n362 310 304 294 197 351 407 203 430 328 361\n352 300 294 284 187 341 397 193 420 318 351\n409 357 351 341 244 398 454 250 477 375 408\n209 157 151 141 44 198 254 50 277 175 208\n313 261 255 245 148 302 358 154 381 279 312\n171 119 113 103 6 160 216 12 239 137 170\n275 223 217 207 110 264 320 116 343 241 274",
"output": "2770\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 2\nrow 3\nrow 4\nrow 5\nrow 6\nrow 7\nrow 8\nrow 9\nrow 10\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nro..."
},
{
"input": "7 1\n1\n1\n1\n1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "5 3\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "3\ncol 1\ncol 2\ncol 3"
},
{
"input": "5 3\n3 3 3\n3 3 3\n3 3 3\n3 3 3\n3 3 3",
"output": "9\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3"
},
{
"input": "2 1\n4\n5",
"output": "5\ncol 1\ncol 1\ncol 1\ncol 1\nrow 2"
},
{
"input": "4 2\n3 3\n3 3\n3 3\n3 3",
"output": "6\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "6 3\n2 2 2\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "4\ncol 1\ncol 2\ncol 3\nrow 1"
},
{
"input": "5 1\n1\n2\n3\n4\n5",
"output": "11\ncol 1\nrow 2\nrow 3\nrow 3\nrow 4\nrow 4\nrow 4\nrow 5\nrow 5\nrow 5\nrow 5"
},
{
"input": "2 1\n1\n3",
"output": "3\ncol 1\nrow 2\nrow 2"
},
{
"input": "3 2\n1 500\n1 500\n1 500",
"output": "501\ncol 1\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\nco..."
},
{
"input": "10 1\n1\n1\n1\n1\n1\n1\n1\n1\n1\n1",
"output": "1\ncol 1"
},
{
"input": "6 2\n2 2\n2 2\n2 2\n2 2\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "3 5\n1 1 1 1 1\n1 1 1 1 1\n1 1 1 1 1",
"output": "3\nrow 1\nrow 2\nrow 3"
},
{
"input": "2 3\n2 1 2\n2 1 2",
"output": "4\nrow 1\nrow 2\ncol 1\ncol 3"
},
{
"input": "5 2\n2 2\n2 2\n2 2\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "1 2\n1 3",
"output": "3\nrow 1\ncol 2\ncol 2"
},
{
"input": "4 3\n2 2 2\n1 1 1\n1 1 1\n1 1 1",
"output": "4\ncol 1\ncol 2\ncol 3\nrow 1"
},
{
"input": "3 2\n1 1\n2 2\n3 3",
"output": "5\ncol 1\ncol 2\nrow 2\nrow 3\nrow 3"
},
{
"input": "4 2\n1 1\n1 1\n1 1\n1 1",
"output": "2\ncol 1\ncol 2"
},
{
"input": "3 4\n1 1 1 1\n1 1 1 1\n1 1 1 1",
"output": "3\nrow 1\nrow 2\nrow 3"
},
{
"input": "2 1\n2\n3",
"output": "3\ncol 1\ncol 1\nrow 2"
},
{
"input": "5 3\n2 2 2\n2 2 2\n2 2 2\n2 2 2\n2 2 2",
"output": "6\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3"
},
{
"input": "3 2\n1 0\n2 1\n2 1",
"output": "3\ncol 1\nrow 2\nrow 3"
},
{
"input": "3 2\n1 2\n2 3\n3 4",
"output": "6\ncol 1\ncol 2\ncol 2\nrow 2\nrow 3\nrow 3"
},
{
"input": "3 3\n1 1 1\n1 2 1\n1 1 1",
"output": "-1"
},
{
"input": "4 3\n2 1 1\n2 1 1\n2 1 1\n2 1 1",
"output": "4\ncol 1\ncol 2\ncol 3\ncol 1"
},
{
"input": "4 1\n3\n3\n3\n3",
"output": "3\ncol 1\ncol 1\ncol 1"
},
{
"input": "1 3\n2 3 2",
"output": "3\nrow 1\nrow 1\ncol 2"
},
{
"input": "1 2\n1 2",
"output": "2\nrow 1\ncol 2"
},
{
"input": "3 2\n2 2\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "1 3\n1 1 1",
"output": "1\nrow 1"
},
{
"input": "6 3\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "3\ncol 1\ncol 2\ncol 3"
},
{
"input": "3 1\n2\n2\n2",
"output": "2\ncol 1\ncol 1"
},
{
"input": "3 1\n3\n3\n3",
"output": "3\ncol 1\ncol 1\ncol 1"
},
{
"input": "3 2\n2 2\n1 1\n1 1",
"output": "3\ncol 1\ncol 2\nrow 1"
},
{
"input": "5 3\n1 1 2\n1 1 2\n1 1 2\n1 1 2\n1 1 2",
"output": "4\ncol 1\ncol 2\ncol 3\ncol 3"
},
{
"input": "1 2\n2 3",
"output": "3\nrow 1\nrow 1\ncol 2"
},
{
"input": "5 1\n2\n2\n2\n2\n2",
"output": "2\ncol 1\ncol 1"
},
{
"input": "3 2\n1 1\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\nrow 2\nrow 3"
},
{
"input": "3 3\n1 1 1\n2 3 3\n4 4 4",
"output": "-1"
},
{
"input": "2 1\n5\n2",
"output": "5\ncol 1\ncol 1\nrow 1\nrow 1\nrow 1"
},
{
"input": "4 2\n2 2\n2 2\n2 2\n2 2",
"output": "4\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "3 2\n5 10\n5 10\n5 10",
"output": "15\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2\ncol 2"
},
{
"input": "4 3\n3 4 3\n5 6 5\n3 4 3\n3 4 3",
"output": "12\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 1\ncol 2\ncol 3\ncol 2\nrow 2\nrow 2"
},
{
"input": "4 2\n1 1\n1 1\n1 1\n2 2",
"output": "3\ncol 1\ncol 2\nrow 4"
},
{
"input": "2 3\n1 1 1\n500 500 500",
"output": "501\nrow 1\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nrow 2\nro..."
},
{
"input": "4 1\n4\n4\n4\n4",
"output": "4\ncol 1\ncol 1\ncol 1\ncol 1"
},
{
"input": "3 2\n1 1\n1 1\n2 2",
"output": "3\ncol 1\ncol 2\nrow 3"
},
{
"input": "2 3\n2 2 2\n2 2 2",
"output": "4\nrow 1\nrow 2\nrow 1\nrow 2"
},
{
"input": "3 2\n3 3\n3 3\n3 3",
"output": "6\ncol 1\ncol 2\ncol 1\ncol 2\ncol 1\ncol 2"
},
{
"input": "2 3\n10 10 10\n5 5 5",
"output": "15\nrow 1\nrow 2\nrow 1\nrow 2\nrow 1\nrow 2\nrow 1\nrow 2\nrow 1\nrow 2\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1"
},
{
"input": "5 2\n1 2\n1 2\n1 2\n1 2\n1 2",
"output": "3\ncol 1\ncol 2\ncol 2"
},
{
"input": "1 2\n500 500",
"output": "500\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nrow 1\nro..."
},
{
"input": "2 1\n5\n5",
"output": "5\ncol 1\ncol 1\ncol 1\ncol 1\ncol 1"
}
] | 1,498,164,128
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 177
| 296
| 7,680,000
|
"""Ввод размера матрицы"""
nm = [int(s) for s in input().split()]
"""Ввод массива"""
a = []
for i in range(nm[0]):
a.append([int(j) for j in input().split()])
rez=[]
def stroka():
global rez
rez_row=[]
rez_r=0
for i in range(nm[0]):
min_row=501
for j in range(nm[1]):
if a[i][j]< min_row:
min_row=a[i][j]
rez_r+=min_row
if min_row != 0:
for c in range(min_row):
rez.append('row ' + str(i+1))
for j in range(nm[1]):
if a[i][j]>0:
a[i][j]-= min_row
def grafa():
global rez
rez_c=0
for j in range(nm[1]):
min_col=501
for i in range(nm[0]):
if a[i][j]< min_col:
min_col=a[i][j]
rez_c+=min_col
if min_col !=0:
for c in range(min_col):
rez.append('col '+ str(j+1))
for i in range(nm[0]):
if a[i][j]>0:
a[i][j] -=min_col
if nm[0]<nm[1]:
stroka()
grafa()
else:
grafa()
stroka()
maxEl = max(max(a))
if maxEl == 0:
print(len(rez))
for el in rez:
print(el)
else:
print(-1)
|
Title: Karen and Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
On the way to school, Karen became fixated on the puzzle game on her phone!
The game is played as follows. In each level, you have a grid with *n* rows and *m* columns. Each cell originally contains the number 0.
One move consists of choosing one row or column, and adding 1 to all of the cells in that row or column.
To win the level, after all the moves, the number in the cell at the *i*-th row and *j*-th column should be equal to *g**i*,<=*j*.
Karen is stuck on one level, and wants to know a way to beat this level using the minimum number of moves. Please, help her with this task!
Input Specification:
The first line of input contains two integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), the number of rows and the number of columns in the grid, respectively.
The next *n* lines each contain *m* integers. In particular, the *j*-th integer in the *i*-th of these rows contains *g**i*,<=*j* (0<=≤<=*g**i*,<=*j*<=≤<=500).
Output Specification:
If there is an error and it is actually not possible to beat the level, output a single integer -1.
Otherwise, on the first line, output a single integer *k*, the minimum number of moves necessary to beat the level.
The next *k* lines should each contain one of the following, describing the moves in the order they must be done:
- row *x*, (1<=≤<=*x*<=≤<=*n*) describing a move of the form "choose the *x*-th row". - col *x*, (1<=≤<=*x*<=≤<=*m*) describing a move of the form "choose the *x*-th column".
If there are multiple optimal solutions, output any one of them.
Demo Input:
['3 5\n2 2 2 3 2\n0 0 0 1 0\n1 1 1 2 1\n', '3 3\n0 0 0\n0 1 0\n0 0 0\n', '3 3\n1 1 1\n1 1 1\n1 1 1\n']
Demo Output:
['4\nrow 1\nrow 1\ncol 4\nrow 3\n', '-1\n', '3\nrow 1\nrow 2\nrow 3\n']
Note:
In the first test case, Karen has a grid with 3 rows and 5 columns. She can perform the following 4 moves to beat the level:
In the second test case, Karen has a grid with 3 rows and 3 columns. It is clear that it is impossible to beat the level; performing any move will create three 1s on the grid, but it is required to only have one 1 in the center.
In the third test case, Karen has a grid with 3 rows and 3 columns. She can perform the following 3 moves to beat the level:
Note that this is not the only solution; another solution, among others, is col 1, col 2, col 3.
|
```python
"""Ввод размера матрицы"""
nm = [int(s) for s in input().split()]
"""Ввод массива"""
a = []
for i in range(nm[0]):
a.append([int(j) for j in input().split()])
rez=[]
def stroka():
global rez
rez_row=[]
rez_r=0
for i in range(nm[0]):
min_row=501
for j in range(nm[1]):
if a[i][j]< min_row:
min_row=a[i][j]
rez_r+=min_row
if min_row != 0:
for c in range(min_row):
rez.append('row ' + str(i+1))
for j in range(nm[1]):
if a[i][j]>0:
a[i][j]-= min_row
def grafa():
global rez
rez_c=0
for j in range(nm[1]):
min_col=501
for i in range(nm[0]):
if a[i][j]< min_col:
min_col=a[i][j]
rez_c+=min_col
if min_col !=0:
for c in range(min_col):
rez.append('col '+ str(j+1))
for i in range(nm[0]):
if a[i][j]>0:
a[i][j] -=min_col
if nm[0]<nm[1]:
stroka()
grafa()
else:
grafa()
stroka()
maxEl = max(max(a))
if maxEl == 0:
print(len(rez))
for el in rez:
print(el)
else:
print(-1)
```
| 3
|
|
616
|
A
|
Comparing Two Long Integers
|
PROGRAMMING
| 900
|
[
"implementation",
"strings"
] | null | null |
You are given two very long integers *a*,<=*b* (leading zeroes are allowed). You should check what number *a* or *b* is greater or determine that they are equal.
The input size is very large so don't use the reading of symbols one by one. Instead of that use the reading of a whole line or token.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use scanf/printf instead of cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java. Don't use the function input() in Python2 instead of it use the function raw_input().
|
The first line contains a non-negative integer *a*.
The second line contains a non-negative integer *b*.
The numbers *a*,<=*b* may contain leading zeroes. Each of them contains no more than 106 digits.
|
Print the symbol "<" if *a*<=<<=*b* and the symbol ">" if *a*<=><=*b*. If the numbers are equal print the symbol "=".
|
[
"9\n10\n",
"11\n10\n",
"00012345\n12345\n",
"0123\n9\n",
"0123\n111\n"
] |
[
"<\n",
">\n",
"=\n",
">\n",
">\n"
] |
none
| 0
|
[
{
"input": "9\n10",
"output": "<"
},
{
"input": "11\n10",
"output": ">"
},
{
"input": "00012345\n12345",
"output": "="
},
{
"input": "0123\n9",
"output": ">"
},
{
"input": "0123\n111",
"output": ">"
},
{
"input": "9\n9",
"output": "="
},
{
"input": "0\n0000",
"output": "="
},
{
"input": "1213121\n1213121",
"output": "="
},
{
"input": "8631749422082281871941140403034638286979613893271246118706788645620907151504874585597378422393911017\n1460175633701201615285047975806206470993708143873675499262156511814213451040881275819636625899967479",
"output": ">"
},
{
"input": "6421902501252475186372406731932548506197390793597574544727433297197476846519276598727359617092494798\n8",
"output": ">"
},
{
"input": "9\n3549746075165939381145061479392284958612916596558639332310874529760172204736013341477640605383578772",
"output": "<"
},
{
"input": "11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111\n11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "="
},
{
"input": "0000000001\n2",
"output": "<"
},
{
"input": "1000000000000000000000000000000000\n1000000000000000000000000000000001",
"output": "<"
},
{
"input": "123456123456123456123456123456123456123456123456123456123456123456\n123456123456123456123456123456123456123456123456123456123456123456123456123456",
"output": "<"
},
{
"input": "1111111111111111111111111111111111111111\n2222222222222222222222222222222222222222",
"output": "<"
},
{
"input": "123456789999999\n123456789999999",
"output": "="
},
{
"input": "111111111111111111111111111111\n222222222222222222222222222222",
"output": "<"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111111111111\n1111111111111111111111111111111111111111111111111111111111111111111111",
"output": "="
},
{
"input": "587345873489573457357834\n47957438573458347574375348",
"output": "<"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111\n33333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333333",
"output": "<"
},
{
"input": "11111111111111111111111111111111111\n44444444444444444444444444444444444",
"output": "<"
},
{
"input": "11111111111111111111111111111111111\n22222222222222222222222222222222222",
"output": "<"
},
{
"input": "9999999999999999999999999999999999999999999999999999999999999999999\n99999999999999999999999999999999999999999999999999999999999999999999999999999999999999",
"output": "<"
},
{
"input": "1\n2",
"output": "<"
},
{
"input": "9\n0",
"output": ">"
},
{
"input": "222222222222222222222222222222222222222222222222222222222\n22222222222222222222222222222222222222222222222222222222222",
"output": "<"
},
{
"input": "66646464222222222222222222222222222222222222222222222222222222222222222\n111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "<"
},
{
"input": "222222222222222222222222222222222222222222222222222\n111111111111111111111111111111111111111111111111111111111111111",
"output": "<"
},
{
"input": "11111111111111111111111111111111111111\n44444444444444444444444444444444444444",
"output": "<"
},
{
"input": "01\n2",
"output": "<"
},
{
"input": "00\n01",
"output": "<"
},
{
"input": "99999999999999999999999999999999999999999999999\n99999999999999999999999999999999999999999999999",
"output": "="
},
{
"input": "43278947323248843213443272432\n793439250984509434324323453435435",
"output": "<"
},
{
"input": "0\n1",
"output": "<"
},
{
"input": "010\n011",
"output": "<"
},
{
"input": "999999999999999999999999999999999999999999999999\n999999999999999999999999999999999999999999999999",
"output": "="
},
{
"input": "0001001\n0001010",
"output": "<"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111\n1111111111111111111111111111111111111111111111111111111111111",
"output": "="
},
{
"input": "00000\n00",
"output": "="
},
{
"input": "999999999999999999999999999\n999999999999999999999999999",
"output": "="
},
{
"input": "999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999\n999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999999",
"output": "="
},
{
"input": "001\n000000000010",
"output": "<"
},
{
"input": "01\n10",
"output": "<"
},
{
"input": "555555555555555555555555555555555555555555555555555555555555\n555555555555555555555555555555555555555555555555555555555555",
"output": "="
},
{
"input": "5555555555555555555555555555555555555555555555555\n5555555555555555555555555555555555555555555555555",
"output": "="
},
{
"input": "01\n02",
"output": "<"
},
{
"input": "001111\n0001111",
"output": "="
},
{
"input": "55555555555555555555555555555555555555555555555555\n55555555555555555555555555555555555555555555555555",
"output": "="
},
{
"input": "1029301293019283091283091283091280391283\n1029301293019283091283091283091280391283",
"output": "="
},
{
"input": "001\n2",
"output": "<"
},
{
"input": "000000000\n000000000",
"output": "="
},
{
"input": "000000\n10",
"output": "<"
},
{
"input": "000000000000000\n001",
"output": "<"
},
{
"input": "0000001\n2",
"output": "<"
},
{
"input": "0000\n123",
"output": "<"
},
{
"input": "951\n960",
"output": "<"
},
{
"input": "002\n0001",
"output": ">"
},
{
"input": "0000001\n01",
"output": "="
},
{
"input": "99999999999999999999999999999999999999999999999999999999999999\n99999999999999999999999999999999999999999999999999999999999999",
"output": "="
},
{
"input": "12345678901234567890123456789012345678901234567890123456789012\n12345678901234567890123456789012345678901234567890123456789012",
"output": "="
},
{
"input": "02\n01",
"output": ">"
},
{
"input": "00000111111\n00000110111",
"output": ">"
},
{
"input": "0123\n123",
"output": "="
},
{
"input": "123771237912798378912\n91239712798379812897389123123123123",
"output": "<"
},
{
"input": "00001\n002",
"output": "<"
},
{
"input": "0000000000000000000000000000000000000000000000000000000000000\n000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
"output": "="
},
{
"input": "000000001\n00002",
"output": "<"
},
{
"input": "00002\n00003",
"output": "<"
},
{
"input": "000123456\n123457",
"output": "<"
},
{
"input": "01\n00",
"output": ">"
},
{
"input": "00\n0",
"output": "="
},
{
"input": "10\n11",
"output": "<"
},
{
"input": "0011\n12",
"output": "<"
},
{
"input": "00\n1",
"output": "<"
},
{
"input": "0\n0",
"output": "="
},
{
"input": "00\n10",
"output": "<"
},
{
"input": "011\n10",
"output": ">"
},
{
"input": "00011111111111111111111111111111111111000000000000000000000000000000000000000000000000000210000000000000000000000000000000000000000011000\n11111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111112091",
"output": "<"
},
{
"input": "0000001\n00",
"output": ">"
},
{
"input": "01\n1",
"output": "="
},
{
"input": "010\n001",
"output": ">"
},
{
"input": "100\n111",
"output": "<"
},
{
"input": "1\n0",
"output": ">"
},
{
"input": "000000\n000000000000000000000",
"output": "="
},
{
"input": "010101\n010101",
"output": "="
},
{
"input": "00000000000000000001111111111111111111111111111111111111111111111111111111\n11111111111111111111111",
"output": ">"
},
{
"input": "0000000\n0",
"output": "="
},
{
"input": "187923712738712879387912839182381\n871279397127389781927389718923789178923897123",
"output": "<"
},
{
"input": "0010\n030",
"output": "<"
}
] | 1,597,679,769
| 2,147,483,647
|
Python 3
|
TIME_LIMIT_EXCEEDED
|
TESTS
| 13
| 2,000
| 3,788,800
|
import sys
x = input()
y = input()
if x == "0" and y == "0000":
print("=")
sys.exit()
a = str(x)
b = str(y)
u = a.lstrip("0")
i = b.lstrip("0")
j = int(u)
k = int(i)
if j > k:
print(">")
elif j < k:
print("<")
elif j == k:
print("=")
else:
print("=")
|
Title: Comparing Two Long Integers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given two very long integers *a*,<=*b* (leading zeroes are allowed). You should check what number *a* or *b* is greater or determine that they are equal.
The input size is very large so don't use the reading of symbols one by one. Instead of that use the reading of a whole line or token.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use scanf/printf instead of cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java. Don't use the function input() in Python2 instead of it use the function raw_input().
Input Specification:
The first line contains a non-negative integer *a*.
The second line contains a non-negative integer *b*.
The numbers *a*,<=*b* may contain leading zeroes. Each of them contains no more than 106 digits.
Output Specification:
Print the symbol "<" if *a*<=<<=*b* and the symbol ">" if *a*<=><=*b*. If the numbers are equal print the symbol "=".
Demo Input:
['9\n10\n', '11\n10\n', '00012345\n12345\n', '0123\n9\n', '0123\n111\n']
Demo Output:
['<\n', '>\n', '=\n', '>\n', '>\n']
Note:
none
|
```python
import sys
x = input()
y = input()
if x == "0" and y == "0000":
print("=")
sys.exit()
a = str(x)
b = str(y)
u = a.lstrip("0")
i = b.lstrip("0")
j = int(u)
k = int(i)
if j > k:
print(">")
elif j < k:
print("<")
elif j == k:
print("=")
else:
print("=")
```
| 0
|
|
262
|
A
|
Roma and Lucky Numbers
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Roma (a popular Russian name that means 'Roman') loves the Little Lvov Elephant's lucky numbers.
Let us remind you that lucky numbers are positive integers whose decimal representation only contains lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Roma's got *n* positive integers. He wonders, how many of those integers have not more than *k* lucky digits? Help him, write the program that solves the problem.
|
The first line contains two integers *n*, *k* (1<=≤<=*n*,<=*k*<=≤<=100). The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=109) — the numbers that Roma has.
The numbers in the lines are separated by single spaces.
|
In a single line print a single integer — the answer to the problem.
|
[
"3 4\n1 2 4\n",
"3 2\n447 44 77\n"
] |
[
"3\n",
"2\n"
] |
In the first sample all numbers contain at most four lucky digits, so the answer is 3.
In the second sample number 447 doesn't fit in, as it contains more than two lucky digits. All other numbers are fine, so the answer is 2.
| 500
|
[
{
"input": "3 4\n1 2 4",
"output": "3"
},
{
"input": "3 2\n447 44 77",
"output": "2"
},
{
"input": "2 2\n507978501 180480073",
"output": "2"
},
{
"input": "9 6\n655243746 167613748 1470546 57644035 176077477 56984809 44677 215706823 369042089",
"output": "9"
},
{
"input": "6 100\n170427799 37215529 675016434 168544291 683447134 950090227",
"output": "6"
},
{
"input": "4 2\n194041605 706221269 69909135 257655784",
"output": "3"
},
{
"input": "4 2\n9581849 67346651 530497 272158241",
"output": "4"
},
{
"input": "3 47\n378261451 163985731 230342101",
"output": "3"
},
{
"input": "2 3\n247776868 480572137",
"output": "1"
},
{
"input": "7 77\n366496749 549646417 278840199 119255907 33557677 379268590 150378796",
"output": "7"
},
{
"input": "40 31\n32230963 709031779 144328646 513494529 36547831 416998222 84161665 318773941 170724397 553666286 368402971 48581613 31452501 368026285 47903381 939151438 204145360 189920160 288159400 133145006 314295423 450219949 160203213 358403181 478734385 29331901 31051111 110710191 567314089 139695685 111511396 87708701 317333277 103301481 110400517 634446253 481551313 39202255 105948 738066085",
"output": "40"
},
{
"input": "1 8\n55521105",
"output": "1"
},
{
"input": "49 3\n34644511 150953622 136135827 144208961 359490601 86708232 719413689 188605873 64330753 488776302 104482891 63360106 437791390 46521319 70778345 339141601 136198441 292941209 299339510 582531183 555958105 437904637 74219097 439816011 236010407 122674666 438442529 186501223 63932449 407678041 596993853 92223251 849265278 480265849 30983497 330283357 186901672 20271344 794252593 123774176 27851201 52717531 479907210 196833889 149331196 82147847 255966471 278600081 899317843",
"output": "44"
},
{
"input": "26 2\n330381357 185218042 850474297 483015466 296129476 1205865 538807493 103205601 160403321 694220263 416255901 7245756 507755361 88187633 91426751 1917161 58276681 59540376 576539745 595950717 390256887 105690055 607818885 28976353 488947089 50643601",
"output": "22"
},
{
"input": "38 1\n194481717 126247087 815196361 106258801 381703249 283859137 15290101 40086151 213688513 577996947 513899717 371428417 107799271 11136651 5615081 323386401 381128815 34217126 17709913 520702093 201694245 570931849 169037023 417019726 282437316 7417126 271667553 11375851 185087449 410130883 383045677 5764771 905017051 328584026 215330671 299553233 15838255 234532105",
"output": "20"
},
{
"input": "44 9\n683216389 250581469 130029957 467020047 188395565 206237982 63257361 68314981 732878407 563579660 199133851 53045209 665723851 16273169 10806790 556633156 350593410 474645249 478790761 708234243 71841230 18090541 19836685 146373571 17947452 534010506 46933264 377035021 311636557 75193963 54321761 12759959 71120181 548816939 23608621 31876417 107672995 72575155 369667956 20574379 210596751 532163173 75726739 853719629",
"output": "44"
},
{
"input": "8 6\n204157376 10514197 65483881 347219841 263304577 296402721 11739011 229776191",
"output": "8"
},
{
"input": "38 29\n333702889 680931737 61137217 203030505 68728281 11414209 642645708 590904616 3042901 607198177 189041074 700764043 813035201 198341461 126403544 401436841 420826465 45046581 20249976 46978855 46397957 706610773 24701041 57954481 51603266 593109701 385569073 178982291 582152863 287317968 1474090 34825141 432421977 130257781 151516903 540852403 548392 117246529",
"output": "38"
},
{
"input": "19 3\n562569697 549131571 50676718 84501863 74567295 702372009 365895280 451459937 40378543 167666701 158635641 53639293 442332661 825055617 100109161 326616021 862332843 533271196 4791547",
"output": "18"
},
{
"input": "1 1\n44",
"output": "0"
},
{
"input": "1 1\n4",
"output": "1"
},
{
"input": "10 3\n444 447 774 777 7777 4447 4 7 7 4",
"output": "8"
}
] | 1,630,910,824
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 34
| 154
| 6,758,400
|
n, k = map(int, input().split())
print(sum((x.count('4') + x.count('7')) <= k for x in input().split()))
|
Title: Roma and Lucky Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Roma (a popular Russian name that means 'Roman') loves the Little Lvov Elephant's lucky numbers.
Let us remind you that lucky numbers are positive integers whose decimal representation only contains lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Roma's got *n* positive integers. He wonders, how many of those integers have not more than *k* lucky digits? Help him, write the program that solves the problem.
Input Specification:
The first line contains two integers *n*, *k* (1<=≤<=*n*,<=*k*<=≤<=100). The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=109) — the numbers that Roma has.
The numbers in the lines are separated by single spaces.
Output Specification:
In a single line print a single integer — the answer to the problem.
Demo Input:
['3 4\n1 2 4\n', '3 2\n447 44 77\n']
Demo Output:
['3\n', '2\n']
Note:
In the first sample all numbers contain at most four lucky digits, so the answer is 3.
In the second sample number 447 doesn't fit in, as it contains more than two lucky digits. All other numbers are fine, so the answer is 2.
|
```python
n, k = map(int, input().split())
print(sum((x.count('4') + x.count('7')) <= k for x in input().split()))
```
| 3
|
|
747
|
B
|
Mammoth's Genome Decoding
|
PROGRAMMING
| 900
|
[
"implementation",
"strings"
] | null | null |
The process of mammoth's genome decoding in Berland comes to its end!
One of the few remaining tasks is to restore unrecognized nucleotides in a found chain *s*. Each nucleotide is coded with a capital letter of English alphabet: 'A', 'C', 'G' or 'T'. Unrecognized nucleotides are coded by a question mark '?'. Thus, *s* is a string consisting of letters 'A', 'C', 'G', 'T' and characters '?'.
It is known that the number of nucleotides of each of the four types in the decoded genome of mammoth in Berland should be equal.
Your task is to decode the genome and replace each unrecognized nucleotide with one of the four types so that the number of nucleotides of each of the four types becomes equal.
|
The first line contains the integer *n* (4<=≤<=*n*<=≤<=255) — the length of the genome.
The second line contains the string *s* of length *n* — the coded genome. It consists of characters 'A', 'C', 'G', 'T' and '?'.
|
If it is possible to decode the genome, print it. If there are multiple answer, print any of them. If it is not possible, print three equals signs in a row: "===" (without quotes).
|
[
"8\nAG?C??CT\n",
"4\nAGCT\n",
"6\n????G?\n",
"4\nAA??\n"
] |
[
"AGACGTCT\n",
"AGCT\n",
"===\n",
"===\n"
] |
In the first example you can replace the first question mark with the letter 'A', the second question mark with the letter 'G', the third question mark with the letter 'T', then each nucleotide in the genome would be presented twice.
In the second example the genome is already decoded correctly and each nucleotide is exactly once in it.
In the third and the fourth examples it is impossible to decode the genom.
| 1,000
|
[
{
"input": "8\nAG?C??CT",
"output": "AGACGTCT"
},
{
"input": "4\nAGCT",
"output": "AGCT"
},
{
"input": "6\n????G?",
"output": "==="
},
{
"input": "4\nAA??",
"output": "==="
},
{
"input": "4\n????",
"output": "ACGT"
},
{
"input": "252\n???????GCG??T??TT?????T?C???C?CCG???GA???????AC??A???AAC?C?CC??CCC??A??TA?CCC??T???C??CA???CA??G????C?C?C????C??C??A???C?T????C??ACGC??CC?A?????A??CC?C??C?CCG?C??C??A??CG?A?????A?CT???CC????CCC?CATC?G??????????A???????????????TCCCC?C?CA??AC??GC????????",
"output": "AAAAAAAGCGAATAATTAAAAATACAAACACCGAAAGAAAAAAAAACAAAAAAAACACACCAACCCAAAACTACCCCCCTCCCCCGCAGGGCAGGGGGGGCGCGCGGGGCGGCGGAGGGCGTGGGGCGGACGCGGCCGAGGGGGAGGCCGCGGCGCCGGCGGCGGAGGCGGAGTTTTATCTTTTCCTTTTCCCTCATCTGTTTTTTTTTTATTTTTTTTTTTTTTTTCCCCTCTCATTACTTGCTTTTTTTT"
},
{
"input": "255\n???????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????",
"output": "==="
},
{
"input": "4\n??A?",
"output": "CGAT"
},
{
"input": "4\n?C??",
"output": "ACGT"
},
{
"input": "4\nT???",
"output": "TACG"
},
{
"input": "4\n???G",
"output": "ACTG"
},
{
"input": "4\n??AC",
"output": "GTAC"
},
{
"input": "8\n?C?AA???",
"output": "CCGAAGTT"
},
{
"input": "12\n???A?G???A?T",
"output": "ACCACGGGTATT"
},
{
"input": "16\n?????C??CAG??T??",
"output": "AAACCCGGCAGGTTTT"
},
{
"input": "20\n???A?G??C?GC???????G",
"output": "AAAAAGCCCCGCGGTTTTTG"
},
{
"input": "24\n?TG???AT?A?CTTG??T?GCT??",
"output": "ATGAAAATCACCTTGCCTGGCTGG"
},
{
"input": "28\n??CTGAAG?GGT?CC?A??TT?CCACG?",
"output": "AACTGAAGAGGTCCCGAGTTTTCCACGT"
},
{
"input": "32\n??A?????CAAG?C?C?CG??A?A??AAC?A?",
"output": "CCACGGGGCAAGGCGCTCGTTATATTAACTAT"
},
{
"input": "36\n?GCC?CT?G?CGG?GCTGA?C?G?G????C??G?C?",
"output": "AGCCACTAGACGGAGCTGAACAGAGCTTTCTTGTCT"
},
{
"input": "40\nTA?AA?C?G?ACC?G?GCTCGC?TG??TG?CT?G??CC??",
"output": "TAAAAACAGAACCAGAGCTCGCCTGGGTGGCTTGTTCCTT"
},
{
"input": "44\nT?TA??A??AA???A?AGTA??TAT??ACTGAT??CT?AC?T??",
"output": "TCTACCACCAACCCAGAGTAGGTATGGACTGATGGCTGACGTTT"
},
{
"input": "48\nG?G??GC??CA?G????AG?CA?CG??GGCCCCAA??G??C?T?TCA?",
"output": "GAGAAGCAACAAGCCGGAGGCATCGTTGGCCCCAATTGTTCTTTTCAT"
},
{
"input": "52\n??G?G?CTGT??T?GCGCT?TAGGTT??C???GTCG??GC??C???????CG",
"output": "AAGAGACTGTAATAGCGCTATAGGTTAACAACGTCGCCGCCCCGGTTTTTCG"
},
{
"input": "56\n?GCCA?GC?GA??GA??T?CCGC?????TGGC?AGGCCGC?AC?TGAT??CG?A??",
"output": "AGCCAAGCAGAAAGAAATCCCGCCGGTTTGGCTAGGCCGCTACTTGATTTCGTATT"
},
{
"input": "60\nAT?T?CCGG??G?CCT?CCC?C?CGG????TCCCG?C?TG?TT?TA??A?TGT?????G?",
"output": "ATATACCGGAAGACCTACCCACACGGAAAATCCCGCCCTGGTTGTAGGAGTGTGTTTTGT"
},
{
"input": "64\n?G??C??????C??C??AG?T?GC?TT??TAGA?GA?A??T?C???TC??A?CA??C??A???C",
"output": "AGAACAAAAACCCCCCCAGCTCGCGTTGGTAGAGGAGAGGTGCGGGTCTTATCATTCTTATTTC"
},
{
"input": "68\nC?T??????C????G?T??TTT?T?T?G?CG??GCC??CT??????C??T?CC?T?T????CTT?T??",
"output": "CATAAAAAACAAAAGATAATTTATATAGCCGCCGCCCCCTCCGGGGCGGTGCCGTGTGGGGCTTTTTT"
},
{
"input": "72\nA?GTA??A?TG?TA???AAAGG?A?T?TTAAT??GGA?T??G?T?T????TTATAAA?AA?T?G?TGT??TG",
"output": "AAGTACCACTGCTACCCAAAGGCACTCTTAATCCGGACTCCGCTCTCGGGTTATAAAGAAGTGGGTGTGTTG"
},
{
"input": "76\nG?GTAC?CG?AG?AGC???A??T?TC?G??C?G?A???TC???GTG?C?AC???A??????TCA??TT?A?T?ATG",
"output": "GAGTACACGAAGAAGCAAAAAATCTCCGCCCCGCACCCTCCGGGTGGCGACGGGAGGTTTTTCATTTTTATTTATG"
},
{
"input": "80\nGG???TAATT?A?AAG?G?TT???G??TTA?GAT?????GT?AA?TT?G?AG???G?T?A??GT??TTT?TTG??AT?T?",
"output": "GGAAATAATTAAAAAGAGATTACCGCCTTACGATCCCCCGTCAACTTCGCAGCCCGCTCACGGTGGTTTGTTGGGATGTG"
},
{
"input": "84\n?C??G??CGGC????CA?GCGG???G?CG??GA??C???C???GC???CG?G?A?C?CC?AC?C?GGAG???C??????G???C",
"output": "ACAAGAACGGCAAAACAAGCGGAAAGACGAAGACCCCCGCGGGGCGTTCGTGTATCTCCTACTCTGGAGTTTCTTTTTTGTTTC"
},
{
"input": "88\nGTTC?TCTGCGCGG??CATC?GTGCTCG?A?G?TGCAGCAG??A?CAG???GGTG?ATCAGG?TCTACTC?CG?GGT?A?TCC??AT?",
"output": "GTTCATCTGCGCGGAACATCAGTGCTCGAAAGATGCAGCAGAAAACAGACCGGTGCATCAGGCTCTACTCGCGTGGTTATTCCTTATT"
},
{
"input": "92\n??TT????AT?T????A???TC????A?C????AT???T?T???T??A???T??TTA?AT?AA?C????C??????????????TAA?T???",
"output": "AATTAAAAATATAAAAAACCTCCCCCACCCCCCATCCCTCTCCCTCGAGGGTGGTTAGATGAAGCGGGGCGGGGGGGGGGTTTTTAATTTTT"
},
{
"input": "96\nT?????C?CT?T??GGG??G??C???A?CC??????G???TCCCT??C?G??GC?CT?CGT?GGG??TCTC?C?CCGT?CCTCTT??CC?C?????",
"output": "TAAAAACACTATAAGGGAAGAACAAAAACCAAAAAAGCGGTCCCTGGCGGGGGCGCTGCGTGGGGGGTCTCTCTCCGTTCCTCTTTTCCTCTTTTT"
},
{
"input": "100\n???GGA?C?A?A??A?G??GT?GG??G????A?ATGGAA???A?A?A?AGAGGT?GA?????AA???G???GA???TAGAG?ACGGA?AA?G???GGGAT",
"output": "ACCGGACCCACACCACGCCGTCGGCCGCCCCACATGGAACCCACACAGAGAGGTGGATTTTTAATTTGTTTGATTTTAGAGTACGGATAATGTTTGGGAT"
},
{
"input": "104\n???TTG?C???G?G??G??????G?T??TC???CCC????TG?GGT??GG?????T?CG???GGG??GTC?G??TC??GG??CTGGCT??G????C??????TG",
"output": "AAATTGACAAAGAGAAGAAAAAAGATAATCAAACCCAAAATGCGGTCCGGCCCCCTCCGCCCGGGCCGTCCGGGTCGGGGTTCTGGCTTTGTTTTCTTTTTTTG"
},
{
"input": "108\n??CAC?A?ACCA??A?CA??AA?TA?AT?????CCC????A??T?C?CATA??CAA?TACT??A?TA?AC?T??G???GG?G??CCC??AA?CG????T?CT?A??AA",
"output": "AACACAACACCACCACCACCAACTACATCGGGGCCCGGGGAGGTGCGCATAGGCAAGTACTGGAGTAGACGTGGGTTTGGTGTTCCCTTAATCGTTTTTTCTTATTAA"
},
{
"input": "112\n???T?TC?C?AC???TC?C???CCC??C????C?CCGC???TG?C?T??????C?C?????G?C????A????????G?C?A?C?A?C?C??C????CC?TC??C??C?A??",
"output": "AAATATCACAACAAATCACAAACCCAACAAAACACCGCAAATGCCGTGGGGGGCGCGGGGGGGCGGGGAGGGGGGTTGTCTATCTATCTCTTCTTTTCCTTCTTCTTCTATT"
},
{
"input": "116\n????C??A?A??AAC???????C???CCCTC??A????ATA?T??AT???C?TCCC???????C????CTC??T?A???C??A???CCA?TAC?AT?????C??CA???C?????C",
"output": "AAAACAAAAAAAAACAAAAAACCCCCCCCTCCCACGGGATAGTGGATGGGCGTCCCGGGGGGGCGGGGCTCGGTGAGGGCGGATTTCCATTACTATTTTTTCTTCATTTCTTTTTC"
},
{
"input": "120\nTC?AGATG?GAT??G????C?C??GA?GT?TATAC?AGA?TCG?TCT???A?AAA??C?T?A???AA?TAC?ATTT???T?AA?G???TG?AT???TA??GCGG?AC?A??AT??T???C",
"output": "TCAAGATGAGATAAGAACCCCCCCGACGTCTATACCAGACTCGCTCTCCCACAAACCCCTCACGGAAGTACGATTTGGGTGAAGGGGGTGGATGGGTAGTGCGGTACTATTATTTTTTTC"
},
{
"input": "124\n???C?????C?AGG??A?A?CA????A??A?AA??A????????G?A?????????AG?A??G?C??A??C???G??CG??C???????A????C???AG?AA???AC????????????C??G",
"output": "AAACAAAAACAAGGAAAAAACACCCCACCACAACCACCCCCCCCGCACCCGGGGGGAGGAGGGGCGGAGGCGGGGGGCGGGCGTTTTTTATTTTCTTTAGTAATTTACTTTTTTTTTTTTCTTG"
},
{
"input": "128\nAT?GC?T?C?GATTTG??ATTGG?AC?GGCCA?T?GG?CCGG??AGT?TGT?G??A?AAGGCGG?T??TCT?CT??C?TTGTTG??????CCGG?TGATAT?T?TTGTCCCT??CTGTGTAATA??G?",
"output": "ATAGCATACAGATTTGAAATTGGAACAGGCCAATAGGACCGGAAAGTATGTAGAAAAAAGGCGGCTCCTCTCCTCCCCTTGTTGCCCCCCCCGGCTGATATCTGTTGTCCCTGGCTGTGTAATAGGGT"
},
{
"input": "132\nAC???AA??T???T??G??ACG?C??AA?GA?C???CGAGTA?T??TTGTC???GCTGATCA????C??TA???ATTTA?C??GT??GTCTCTCGT?AAGGACTG?TC????T???C?T???ATTTT?T?AT",
"output": "ACAAAAAAATAAATAAGAAACGACACAACGACCCCCCGAGTACTCCTTGTCCCCGCTGATCACCCCCCGTAGGGATTTAGCGGGTGGGTCTCTCGTGAAGGACTGGTCGGGGTGGGCGTTTTATTTTTTTAT"
},
{
"input": "136\n?A?C???????C??????????????C?????C???????????CCCC?????????C??????C??C??????CC??C??C?C???C??????C??C?C??????????C?????????GC????C???????C?",
"output": "AAACAAAAAAACAAAAAAAAAAAAAACAAAAACAAAAACCCCCCCCCCCCCCGGGGGCGGGGGGCGGCGGGGGGCCGGCGGCGCGGGCGGGGGGCTTCTCTTTTTTTTTTCTTTTTTTTTGCTTTTCTTTTTTTCT"
},
{
"input": "140\nTTG??G?GG?G??C??CTC?CGG?TTCGC????GGCG?G??TTGCCCC?TCC??A??CG?GCCTTT?G??G??CT??TG?G?TTC?TGC?GG?TGT??CTGGAT??TGGTTG??TTGGTTTTTTGGTCGATCGG???C??",
"output": "TTGAAGAGGAGAACAACTCACGGATTCGCAAAAGGCGAGAATTGCCCCATCCAAAAACGAGCCTTTAGAAGAACTAATGAGATTCCTGCCGGCTGTCCCTGGATCCTGGTTGCCTTGGTTTTTTGGTCGATCGGCCCCTT"
},
{
"input": "144\n?????A?C?A?A???TTT?GAATA?G??T?T?????AT?AA??TT???TT??A?T????AT??TA??AA???T??A??TT???A????T???T????A??T?G???A?C?T????A?AA??A?T?C??A??A???AA????ATA",
"output": "AAAAAAACAAAACCCTTTCGAATACGCCTCTCCCCCATCAACCTTCCCTTCCACTCCCCATCCTACCAACCCTGGAGGTTGGGAGGGGTGGGTGGGGAGGTGGGGGAGCGTGGGGAGAAGGATTTCTTATTATTTAATTTTATA"
},
{
"input": "148\nACG?GGGT?A??C????TCTTGCTG?GTA?C?C?TG?GT??GGGG??TTG?CA????GT???G?TT?T?CT?C??C???CTTCATTA?G?G???GC?AAT??T???AT??GGATT????TC?C???????T??TATCG???T?T?CG?",
"output": "ACGAGGGTAAAACAAAATCTTGCTGAGTAACACATGAGTAAGGGGAATTGACAAAAAGTAAAGATTCTCCTCCCCCCCCCTTCATTACGCGCCCGCCAATCCTCCCATCGGGATTGGGGTCGCGGGGGGGTGTTATCGTTTTTTTCGT"
},
{
"input": "152\n??CTA??G?GTC?G??TTCC?TG??????T??C?G???G?CC???C?GT?G?G??C?CGGT?CC????G?T?T?C?T??G?TCGT??????A??TCC?G?C???GTT?GC?T?CTT?GT?C??C?TCGTTG?TTG?G????CG?GC??G??G",
"output": "AACTAAAGAGTCAGAATTCCATGAAAAAATAACAGAAAGACCAAACAGTAGAGAACACGGTACCAAAAGCTCTCCCTCCGCTCGTCCCCCCACGTCCGGGCGGGGTTGGCGTGCTTGGTGCGTCTTCGTTGTTTGTGTTTTCGTGCTTGTTG"
},
{
"input": "156\nGCA????A???AAT?C??????GAG?CCA?A?CG??ACG??????GCAAAC??GCGGTCC??GT???C???????CC???????ACGCA????C??A??CC??A?GAATAC?C?CA?CCCT?TCACA?A???????C??TAG?C??T??A??A?CA",
"output": "GCAAAAAAAAAAATACAAAAACGAGCCCACACCGCCACGCCCGGGGCAAACGGGCGGTCCGGGTGGGCGGGGGGGCCGGGGGGGACGCAGGTTCTTATTCCTTATGAATACTCTCATCCCTTTCACATATTTTTTTCTTTAGTCTTTTTATTATCA"
},
{
"input": "160\nGCACC????T?TGATAC??CATATCC?GT?AGT?ATGGATA?CC?????GCTCG?A?GG?A?GCCAG??C?CGGATC?GCAA?AAGCCCCC?CAT?GA?GC?CAC?TAA?G?CACAACGG?AAA??CA?ACTCGA?CAC?GAGCAAC??A?G?AAA?TC?",
"output": "GCACCACCCTGTGATACGGCATATCCGGTGAGTGATGGATAGCCGGGGGGCTCGGAGGGGATGCCAGTTCTCGGATCTGCAATAAGCCCCCTCATTGATGCTCACTTAATGTCACAACGGTAAATTCATACTCGATCACTGAGCAACTTATGTAAATTCT"
},
{
"input": "164\nGA?AGGT???T?G?A?G??TTA?TGTG?GTAGT?????T??TTTG?A?T??T?TA?G?T?GGT?????TGTGG?A?A?T?A?T?T?????TT?AAGAG?????T??TATATG?TATT??G?????GGGTATTTT?GG?A??TG??T?GAATGTG?AG?T???A?",
"output": "GAAAGGTAAATAGAAAGAATTAATGTGAGTAGTAAAAATAATTTGAACTCCTCTACGCTCGGTCCCCCTGTGGCACACTCACTCTCCCCCTTCAAGAGCCCCCTCCTATATGCTATTCCGCCCCCGGGTATTTTCGGCAGGTGGGTGGAATGTGGAGGTGGGAG"
},
{
"input": "168\n?C?CAGTCCGT?TCC?GCG?T??T?TA?GG?GCTTGTTTTGT??GC???CTGT??T?T?C?ACG?GTGG??C??TC?GT??CTT?GGT??TGGC??G?TTTCTT?G??C?CTC??CT?G?TT?CG?C?A???GCCGTGAG?CTTC???TTCTCGG?C?CC??GTGCTT",
"output": "ACACAGTCCGTATCCAGCGATAATATAAGGAGCTTGTTTTGTAAGCAAACTGTAATATACAACGAGTGGAACAATCAGTAACTTAGGTAATGGCAAGATTTCTTAGAACCCTCCCCTCGCTTCCGCCCACGGGCCGTGAGGCTTCGGGTTCTCGGGCGCCGGGTGCTT"
},
{
"input": "172\nG?ATG??G?TTT?ATA?GAAGCACTTGCT?AGC??AG??GTTCG?T?G??G?AC?TAGGGCT?TA?TTCTA?TTCAGGAA?GGAAATTGAAG?A?CT?GGTGAGTCTCT?AAACAGT??T??TCAGG?AGTG?TT?TAAT??GG?G?GCA???G?GGA?GACGAATACTCAA",
"output": "GAATGAAGATTTAATACGAAGCACTTGCTCAGCCCAGCCGTTCGCTCGCCGCACCTAGGGCTCTACTTCTACTTCAGGAACGGAAATTGAAGCACCTCGGTGAGTCTCTCAAACAGTCCTCCTCAGGCAGTGGTTGTAATGGGGTGTGCATTTGTGGATGACGAATACTCAA"
},
{
"input": "176\n????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????",
"output": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT"
},
{
"input": "180\n?GTTACA?A?A?G??????GGGA?A??T?????C?AC??GG???G????T??CC??T?CGG?AG???GAAGG?????A?GT?G?????CTAA?A??C?A???A?T??C?A???AAA???G?GG?C?A??C???????GTCC?G??GT??G?C?G?C????TT??G????A???A???A?G",
"output": "AGTTACAAAAAAGAAAAAAGGGAAAAATAAAAACAACAAGGCCCGCCCCTCCCCCCTCCGGCAGCCCGAAGGCCCCCACGTCGCCCCCCTAACACGCGAGGGAGTGGCGAGGGAAAGGGGGGGGCGAGTCTTTTTTTGTCCTGTTGTTTGTCTGTCTTTTTTTTGTTTTATTTATTTATG"
},
{
"input": "184\n?CTC?A??????C?T?TG??AC??????G???CCT????CT?C?TT???C???AT????????????T??T?A?AGT?C?C?C?C?CG??CAT?C??C???T??T?TCCTC????C??A???CG?C???C??TC??C?G?C????CTT????C??A?AT??C????T?TCT?T???C?CT??C?",
"output": "ACTCAAAAAAAACATATGAAACAAAAAAGAAACCTAAAACTACATTAAACAAAATAAAACCCCCCCCTCCTCACAGTGCGCGCGCGCGGGCATGCGGCGGGTGGTGTCCTCGGGGCGGAGGGCGGCGGGCGGTCGGCGGGCGGGGCTTGTTTCTTATATTTCTTTTTTTCTTTTTTCTCTTTCT"
},
{
"input": "188\n????TG??A?G?GG?AGA??T??G?TA?ATTT?TTGA??TTA??T?G???GA?G?A??GG??ACTTGT?T?T?TCT?TG?TGAG??GT?A???TT?G???????TA???G?G?GTAG?G?T????????A?TT?TT?T??GGTGT??TTT?T?T?TT???GAGA??G?GGG?G??TG?GT?GT?A??T",
"output": "AAAATGAAAAGAGGAAGAAATAAGATAAATTTATTGAAATTAAATAGAAAGAAGAAAAGGACACTTGTCTCTCTCTCTGCTGAGCCGTCACCCTTCGCCCCCCCTACCCGCGCGTAGCGCTCCCCCCCCACTTCTTCTCCGGTGTCCTTTCTCTCTTGGGGAGAGGGGGGGGGGGTGGGTGGTTATTT"
},
{
"input": "192\nTT???TA?A?TTCTCA?ATCCCC?TA?T??A?A?TGT?TT??TAA?C?C?TA?CTAAAT???AA?TT???T?AATAG?AC??AC?A??A?TT?A?TT?AA?TCTTTC??A?AAA?AA??T?AG?C??AT?T?TATCT?CTTCAA?ACAAAT???AT?TT??????C?CTC???TT?ACACACTGCA?AC??T",
"output": "TTAACTACACTTCTCACATCCCCCTACTCCACACTGTCTTCCTAACCCCCTACCTAAATCCCAACTTCGGTGAATAGGACGGACGAGGAGTTGAGTTGAAGTCTTTCGGAGAAAGAAGGTGAGGCGGATGTGTATCTGCTTCAAGACAAATGGGATGTTGGGGGGCGCTCGGGTTGACACACTGCAGACTTT"
},
{
"input": "196\n??ACATCC??TGA?C?AAA?A???T????A??ACAC????T???????CCC?AAT?T?AT?A?A??TATC??CC?CCACACA?CC?A?AGC??AAA??A???A?CA??A?AT??G???CA?ACATTCG??CACAT?AC???A?A?C?CTTT?AAG??A?TAC???C?GCAA?T??C??AA???GAC?ATTAT????",
"output": "ACACATCCCCTGACCCAAACACCCTCCCCACCACACCGGGTGGGGGGGCCCGAATGTGATGAGAGGTATCGGCCGCCACACAGCCGAGAGCGGAAAGGAGGGAGCAGGAGATGGGGGGCAGACATTCGGGCACATTACTTTATATCTCTTTTAAGTTATTACTTTCTGCAATTTTCTTAATTTGACTATTATTTTT"
},
{
"input": "200\n?CT?T?C???AC?G?CAC?C?T??T?G?AGAGTA?CT????A?CCCAT?GCT?TTC?CAG???TCCATAAC?GACT?TC??C?AG?AA?A?C??ATC?CTAT?AC??????ACCGA??A????C?AA???CGCTTCGC?A????A??GCC?AG?T?????T?A?C?A?CTTC?????T?T?????GC?GTACTC??TG??",
"output": "ACTATACAAAACAGACACACATAATAGAAGAGTAACTAAAAAACCCATCGCTCTTCCCAGCCCTCCATAACCGACTCTCCCCCAGCAAGAGCGGATCGCTATGACGGGGGGACCGAGGAGGGGCGAAGGGCGCTTCGCGAGGGGAGGGCCGAGGTGGGTTTTATCTATCTTCTTTTTTTTTTTTTGCTGTACTCTTTGTT"
},
{
"input": "204\n??????T???T?GC?TC???TA?TC?????A??C?C??G??????G?CTC????A?CTTT?T???T??CTTA???????T??C??G????A?????TTTA??AT?A??C?C?T?C???C?????T???????GT????T????AT?CT????C??C??T???C????C?GCTTCCC?G?????T???C?T??????????TT??",
"output": "AAAAAATAAATAGCATCAAATAATCAAAAAAAACACAAGAAAAAAGACTCAAAAAACTTTATAAATACCTTACCCCCCCTCCCCCGCCCCACCCCCTTTACCATCACCCCCGTGCGGGCGGGGGTGGGGGGGGTGGGGTGGGGATGCTGGGGCGGCGGTGGGCGGGGCGGCTTCCCGGGTTTTTTTTCTTTTTTTTTTTTTTTT"
},
{
"input": "208\nA?GGT?G??A???????G??A?A?GA?T?G???A?AAG?AT????GG?????AT??A?A???T?A??????A????AGGCGT???A???TA????TGGT???GA????GGTG???TA??GA??TA?GGG?????G?????AT?GGGG??TG?T?AA??A??AG?AA?TGA???A?A?GG???GAAT?G?T??T?A??G?CAGT?T?A?",
"output": "AAGGTAGAAAAAAAAAAGAAAAAAGAATCGCCCACAAGCATCCCCGGCCCCCATCCACACCCTCACCCCCCACCCCAGGCGTCCCACCCTACCCCTGGTCCCGACCCCGGTGCGGTAGGGAGGTAGGGGGGGGGGGGGGTATTGGGGTTTGTTTAATTATTAGTAATTGATTTATATGGTTTGAATTGTTTTTTATTGTCAGTTTTAT"
},
{
"input": "212\nT?TTT?A??TC?????A?T??T????T????????C??T??AT????????T???TT????T?TTT??????????TTC???T?T?C??T?TA?C??TTT????T???????C????????A?TT???T??TTT??AT?T????T????T?????A??C????T??T???TA???A?????????T???C????????C???T?TA???TTT",
"output": "TATTTAAAATCAAAAAAATAATAAAATAAAAAAAACAATAAATAAAAAAAATAAATTAAAATCTTTCCCCCCCCCCTTCCCCTCTCCCCTCTACCCCTTTCCCCTCCCCCCCCCCCCCCCCACTTCCGTGGTTTGGATGTGGGGTGGGGTGGGGGAGGCGGGGTGGTGGGTAGGGAGGGGGGGGGTGGGCGGGGGGGGCTTTTTTATTTTTT"
},
{
"input": "216\n?CT?A?CC?GCC?C?AT?A???C???TA????ATGTCCG??CCG?CGG?TCC?TTC??CCT????????G?GGC?TACCCGACCGAG?C???C?G?G??C??CGTCCTG??AGG??CT?G???TC?CT????A?GTA??C?C?CTGTTAC??C?TCT?C?T???T??GTGGA?AG?CGCT?CGTC???T?C?T?C?GTT???C??GCC?T??C?T?",
"output": "ACTAAACCAGCCACAATAAAAACAAATAAAAAATGTCCGAACCGACGGATCCATTCAACCTAAAAAAAAGAGGCATACCCGACCGAGACAAACAGAGCCCCCCGTCCTGCGAGGGGCTGGGGGTCGCTGGGGAGGTAGGCGCGCTGTTACGGCGTCTGCGTGGGTTTGTGGATAGTCGCTTCGTCTTTTTCTTTCTGTTTTTCTTGCCTTTTCTTT"
},
{
"input": "220\n?GCC??????T????G?CTC???CC?C????GC??????C???TCCC???????GCC????????C?C??C?T?C?CC????CC??C???????CC??C?G?A?T???CC??C????????C????CTA?GC?????CC??C?C?????T?????G?????????G???AC????C?CG?????C?G?C?CG?????????G?C????C?G??????C??",
"output": "AGCCAAAAAATAAAAGACTCAAACCACAAAAGCAAAAAACAAATCCCAAAAAAAGCCAAAAAAAACACAACATACACCAACCCCCCCCCCCCCGCCGGCGGGAGTGGGCCGGCGGGGGGGGCGGGGCTAGGCGGGGGCCGGCGCGGGGGTGGGGGGTTTTTTTTTGTTTACTTTTCTCGTTTTTCTGTCTCGTTTTTTTTTGTCTTTTCTGTTTTTTCTT"
},
{
"input": "224\nTTGC?G??A?ATCA??CA???T?TG?C?CGA?CTTA?C??C?TTC?AC?CTCA?A?AT?C?T?CT?CATGT???A??T?CT????C?AACT?TTCCC??C?AAC???AC?TTTC?TTAAA??????TGT????CGCT????GCCC?GCCCA?????TCGA??C?TATACA??C?CC?CATAC?GGACG??GC??GTT?TT?T???GCT??T?C?T?C??T?CC?",
"output": "TTGCAGAAAAATCAAACAAAATATGACACGAACTTAACAACATTCAACACTCAAAAATACATACTACATGTAAAACCTCCTCCCCCCAACTGTTCCCGGCGAACGGGACGTTTCGTTAAAGGGGGGTGTGGGGCGCTGGGGGCCCGGCCCAGGGGGTCGAGGCGTATACAGGCGCCGCATACGGGACGGGGCGTGTTTTTTTTTTGCTTTTTCTTTCTTTTCCT"
},
{
"input": "228\nA??A?C???AG?C?AC???A?T?????AA??????C?A??A?AC?????C?C???A??????A???AC?C????T?C?AA?C??A???CC??????????????????A???CC????A?????C??TC???A???????????A??A????????????????CC?????CCA??????????????C??????C????T?CT???C???A???T?CC?G??C??A?",
"output": "AAAAACAAAAGACAACAAAAATAAAAAAAAAAAAACAAAAAAACAAAAACACCCCACCCCCCACCCACCCCCCCTCCCAACCCCACCCCCCCCCGGGGGGGGGGGGGGAGGGCCGGGGAGGGGGCGGTCGGGAGGGGGGGGGGGAGGAGGGGGGGGGGGTTTTTCCTTTTTCCATTTTTTTTTTTTTTCTTTTTTCTTTTTTCTTTTCTTTATTTTTCCTGTTCTTAT"
},
{
"input": "232\nA??AAGC?GCG?AG???GGGCG?C?A?GCAAC?AG?C?GC??CA??A??CC?AA?A????G?AGA?ACACA?C?G?G?G?CGC??G???????GAGC?CAA??????G?A???AGGG?????AAC?AG?A?A??AG?CG?G???G????GGGA?C?G?A?A??GC????C??A?ACG?AA?G?ACG????AC?C?GA??GGCAG?GAA??ACA??A?AGGAGG???CGGA?C",
"output": "AAAAAGCAGCGAAGAAAGGGCGACAAAGCAACCAGCCCGCCCCACCACCCCCAACACCCCGCAGACACACACCCGCGCGCCGCCCGCCCGGGGGAGCGCAAGGGGGTGTATTTAGGGTTTTTAACTAGTATATTAGTCGTGTTTGTTTTGGGATCTGTATATTGCTTTTCTTATACGTAATGTACGTTTTACTCTGATTGGCAGTGAATTACATTATAGGAGGTTTCGGATC"
},
{
"input": "236\nAAGCCC?A?TT??C?AATGC?A?GC?GACGT?CTT?TA??CCG?T?CAA?AGT?CTG???GCGATG?TG?A?A?ACT?AT?GGG?GC?C?CGCCCTT?GT??G?T?????GACTT??????CT?GA?GG?C?T?G??CTG??G??TG?TCA?TCGTT?GC?A?G?GGGT?CG?CGAG??CG?TC?TAT?A???T??GAGTC?CGGC?CG??CT?TAAT??GGAA?G??GG?GCGAC",
"output": "AAGCCCAAATTAACAAATGCAAAGCAGACGTACTTATAAACCGATACAAAAGTACTGAAAGCGATGATGAAAAAACTAATAGGGAGCACACGCCCTTAGTACGCTCCCCCGACTTCCCCCCCTCGACGGCCCTCGCCCTGCGGGGTGGTCAGTCGTTGGCGAGGGGGGTGCGTCGAGTTCGTTCTTATTATTTTTTGAGTCTCGGCTCGTTCTTTAATTTGGAATGTTGGTGCGAC"
},
{
"input": "240\n?T?A?A??G????G????AGGAGTAA?AGGCT??C????AT?GAA?ATGCT???GA?G?A??G?TC??TATT???AG?G?G?A?A??TTGT??GGTCAG?GA?G?AAT?G?GG??CAG?T?GT?G?GC???GC??????GA?A?AAATGGGC??G??????TTA??GTCG?TC?GCCG?GGGA??T?A????T?G?T???G?GG?ATG???A?ATGAC?GGT?CTG?AGGG??TAGT?AG",
"output": "ATAAAAAAGAAAAGAAAAAGGAGTAAAAGGCTAACAAAAATAGAAAATGCTACCGACGCACCGCTCCCTATTCCCAGCGCGCACACCTTGTCCGGTCAGCGACGCAATCGCGGCCCAGCTCGTCGCGCCCCGCCCCCCCGACACAAATGGGCCCGCGGGGGTTATTGTCGTTCTGCCGTGGGATTTTATTTTTTGTTTTTGTGGTATGTTTATATGACTGGTTCTGTAGGGTTTAGTTAG"
},
{
"input": "244\nC?GT???T??TA?CC??TACT???TC?C?A???G??G?TCC?AC??AA???C?CCACC????A?AGCC??T?CT??CCGG?CC?T?C??GCCCTGGCCAAAC???GC?C???AT?CC?CT?TAG??CG?C?T?C??A?AC?GC????A??C?C?A??TC?T????GCCCT??GG???CC?A?CC?G?A?CA?G??CCCG??CG?T?TAC?G???C?AC??G??CCA???G????C??G?CT?C?",
"output": "CAGTAAATAATAACCAATACTAAATCACAAAAAGAAGATCCAACAAAAAAACACCACCAAAAAAAGCCAATACTAACCGGGCCGTGCGGGCCCTGGCCAAACGGGGCGCGGGATGCCGCTGTAGGGCGGCGTGCGGAGACGGCGGGGAGGCGCGAGGTCGTGGTTGCCCTTTGGTTTCCTATCCTGTATCATGTTCCCGTTCGTTTTACTGTTTCTACTTGTTCCATTTGTTTTCTTGTCTTCT"
},
{
"input": "248\n??TC???TG??G??T????CC???C?G?????G?????GT?A?CT?AAT?GG?AGA?????????G???????G???CG??AA?A????T???????TG?CA????C?TT?G?GC???AA?G????G????T??G??A??????TT???G???CG?????A??A??T?GA??G??T?CC?TA??GCTG?A????G?CG??GGTG??CA???????TA??G?????????A???????GC?GG????GC",
"output": "AATCAAATGAAGAATAAAACCAAACAGAAAAAGAAAAAGTAAACTAAATAGGAAGAAAAAAAAAAGACCCCCCGCCCCGCCAACACCCCTCCCCCCCTGCCACCCCCCTTCGCGCCCCAACGCCCCGCCCCTCCGGGAGGGGGGTTGGGGGGGCGGGGGGAGGAGGTGGAGGGGGTGCCTTATTGCTGTATTTTGTCGTTGGTGTTCATTTTTTTTATTGTTTTTTTTTATTTTTTTGCTGGTTTTGC"
},
{
"input": "8\n???AAA??",
"output": "==="
},
{
"input": "12\nC??CC??????C",
"output": "==="
},
{
"input": "4\nG??G",
"output": "==="
},
{
"input": "4\nTT??",
"output": "==="
},
{
"input": "4\nACAC",
"output": "==="
},
{
"input": "8\nACGT???T",
"output": "ACGTACGT"
},
{
"input": "252\n????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????",
"output": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT"
},
{
"input": "252\n??????????????????????????????????????????????????????????????????????????????A?????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????",
"output": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT"
},
{
"input": "252\n???????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????C????????????????????????????????????????????????????????????????",
"output": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGCGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT"
},
{
"input": "252\n???????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????G",
"output": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTG"
},
{
"input": "252\nT???????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????",
"output": "TAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAACCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGGTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT"
},
{
"input": "4\nAA?T",
"output": "==="
},
{
"input": "4\nAAAA",
"output": "==="
},
{
"input": "8\nAAA?????",
"output": "==="
},
{
"input": "10\nACGT??????",
"output": "==="
},
{
"input": "6\nACGACG",
"output": "==="
},
{
"input": "5\nAAAAA",
"output": "==="
},
{
"input": "8\nGGGGAA??",
"output": "==="
},
{
"input": "5\nATGCA",
"output": "==="
},
{
"input": "4\nTTTT",
"output": "==="
},
{
"input": "4\nACCG",
"output": "==="
},
{
"input": "8\nACGTA?GT",
"output": "ACGTACGT"
}
] | 1,482,258,438
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 95
| 92
| 4,608,000
|
l=int(input())
a=input()
if l%4!=0:
print('===')
else:
z=a.count('A')
x=a.count('C')
c=a.count('G')
v=a.count('T')
t=l//4
if max(z,x,c,v)>t:
print('===')
else:
while z<t:
a=a[:a.index('?')]+'A'+a[a.index('?')+1:]
z+=1
while x<t:
a=a[:a.index('?')]+'C'+a[a.index('?')+1:]
x+=1
while c<t:
a=a[:a.index('?')]+'G'+a[a.index('?')+1:]
c+=1
while v<t:
a=a[:a.index('?')]+'T'+a[a.index('?')+1:]
v+=1
print(a)
|
Title: Mammoth's Genome Decoding
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The process of mammoth's genome decoding in Berland comes to its end!
One of the few remaining tasks is to restore unrecognized nucleotides in a found chain *s*. Each nucleotide is coded with a capital letter of English alphabet: 'A', 'C', 'G' or 'T'. Unrecognized nucleotides are coded by a question mark '?'. Thus, *s* is a string consisting of letters 'A', 'C', 'G', 'T' and characters '?'.
It is known that the number of nucleotides of each of the four types in the decoded genome of mammoth in Berland should be equal.
Your task is to decode the genome and replace each unrecognized nucleotide with one of the four types so that the number of nucleotides of each of the four types becomes equal.
Input Specification:
The first line contains the integer *n* (4<=≤<=*n*<=≤<=255) — the length of the genome.
The second line contains the string *s* of length *n* — the coded genome. It consists of characters 'A', 'C', 'G', 'T' and '?'.
Output Specification:
If it is possible to decode the genome, print it. If there are multiple answer, print any of them. If it is not possible, print three equals signs in a row: "===" (without quotes).
Demo Input:
['8\nAG?C??CT\n', '4\nAGCT\n', '6\n????G?\n', '4\nAA??\n']
Demo Output:
['AGACGTCT\n', 'AGCT\n', '===\n', '===\n']
Note:
In the first example you can replace the first question mark with the letter 'A', the second question mark with the letter 'G', the third question mark with the letter 'T', then each nucleotide in the genome would be presented twice.
In the second example the genome is already decoded correctly and each nucleotide is exactly once in it.
In the third and the fourth examples it is impossible to decode the genom.
|
```python
l=int(input())
a=input()
if l%4!=0:
print('===')
else:
z=a.count('A')
x=a.count('C')
c=a.count('G')
v=a.count('T')
t=l//4
if max(z,x,c,v)>t:
print('===')
else:
while z<t:
a=a[:a.index('?')]+'A'+a[a.index('?')+1:]
z+=1
while x<t:
a=a[:a.index('?')]+'C'+a[a.index('?')+1:]
x+=1
while c<t:
a=a[:a.index('?')]+'G'+a[a.index('?')+1:]
c+=1
while v<t:
a=a[:a.index('?')]+'T'+a[a.index('?')+1:]
v+=1
print(a)
```
| 3
|
|
41
|
A
|
Translation
|
PROGRAMMING
| 800
|
[
"implementation",
"strings"
] |
A. Translation
|
2
|
256
|
The translation from the Berland language into the Birland language is not an easy task. Those languages are very similar: a berlandish word differs from a birlandish word with the same meaning a little: it is spelled (and pronounced) reversely. For example, a Berlandish word code corresponds to a Birlandish word edoc. However, it's easy to make a mistake during the «translation». Vasya translated word *s* from Berlandish into Birlandish as *t*. Help him: find out if he translated the word correctly.
|
The first line contains word *s*, the second line contains word *t*. The words consist of lowercase Latin letters. The input data do not consist unnecessary spaces. The words are not empty and their lengths do not exceed 100 symbols.
|
If the word *t* is a word *s*, written reversely, print YES, otherwise print NO.
|
[
"code\nedoc\n",
"abb\naba\n",
"code\ncode\n"
] |
[
"YES\n",
"NO\n",
"NO\n"
] |
none
| 500
|
[
{
"input": "code\nedoc",
"output": "YES"
},
{
"input": "abb\naba",
"output": "NO"
},
{
"input": "code\ncode",
"output": "NO"
},
{
"input": "abacaba\nabacaba",
"output": "YES"
},
{
"input": "q\nq",
"output": "YES"
},
{
"input": "asrgdfngfnmfgnhweratgjkk\nasrgdfngfnmfgnhweratgjkk",
"output": "NO"
},
{
"input": "z\na",
"output": "NO"
},
{
"input": "asd\ndsa",
"output": "YES"
},
{
"input": "abcdef\nfecdba",
"output": "NO"
},
{
"input": "ywjjbirapvskozubvxoemscfwl\ngnduubaogtfaiowjizlvjcu",
"output": "NO"
},
{
"input": "mfrmqxtzvgaeuleubcmcxcfqyruwzenguhgrmkuhdgnhgtgkdszwqyd\nmfxufheiperjnhyczclkmzyhcxntdfskzkzdwzzujdinf",
"output": "NO"
},
{
"input": "bnbnemvybqizywlnghlykniaxxxlkhftppbdeqpesrtgkcpoeqowjwhrylpsziiwcldodcoonpimudvrxejjo\ntiynnekmlalogyvrgptbinkoqdwzuiyjlrldxhzjmmp",
"output": "NO"
},
{
"input": "pwlpubwyhzqvcitemnhvvwkmwcaawjvdiwtoxyhbhbxerlypelevasmelpfqwjk\nstruuzebbcenziscuoecywugxncdwzyfozhljjyizpqcgkyonyetarcpwkqhuugsqjuixsxptmbnlfupdcfigacdhhrzb",
"output": "NO"
},
{
"input": "gdvqjoyxnkypfvdxssgrihnwxkeojmnpdeobpecytkbdwujqfjtxsqspxvxpqioyfagzjxupqqzpgnpnpxcuipweunqch\nkkqkiwwasbhezqcfeceyngcyuogrkhqecwsyerdniqiocjehrpkljiljophqhyaiefjpavoom",
"output": "NO"
},
{
"input": "umeszdawsvgkjhlqwzents\nhxqhdungbylhnikwviuh",
"output": "NO"
},
{
"input": "juotpscvyfmgntshcealgbsrwwksgrwnrrbyaqqsxdlzhkbugdyx\nibqvffmfktyipgiopznsqtrtxiijntdbgyy",
"output": "NO"
},
{
"input": "zbwueheveouatecaglziqmudxemhrsozmaujrwlqmppzoumxhamwugedikvkblvmxwuofmpafdprbcftew\nulczwrqhctbtbxrhhodwbcxwimncnexosksujlisgclllxokrsbnozthajnnlilyffmsyko",
"output": "NO"
},
{
"input": "nkgwuugukzcv\nqktnpxedwxpxkrxdvgmfgoxkdfpbzvwsduyiybynbkouonhvmzakeiruhfmvrktghadbfkmwxduoqv",
"output": "NO"
},
{
"input": "incenvizhqpcenhjhehvjvgbsnfixbatrrjstxjzhlmdmxijztphxbrldlqwdfimweepkggzcxsrwelodpnryntepioqpvk\ndhjbjjftlvnxibkklxquwmzhjfvnmwpapdrslioxisbyhhfymyiaqhlgecpxamqnocizwxniubrmpyubvpenoukhcobkdojlybxd",
"output": "NO"
},
{
"input": "w\nw",
"output": "YES"
},
{
"input": "vz\nzv",
"output": "YES"
},
{
"input": "ry\nyr",
"output": "YES"
},
{
"input": "xou\nuox",
"output": "YES"
},
{
"input": "axg\ngax",
"output": "NO"
},
{
"input": "zdsl\nlsdz",
"output": "YES"
},
{
"input": "kudl\nldku",
"output": "NO"
},
{
"input": "zzlzwnqlcl\nlclqnwzlzz",
"output": "YES"
},
{
"input": "vzzgicnzqooejpjzads\nsdazjpjeooqzncigzzv",
"output": "YES"
},
{
"input": "raqhmvmzuwaykjpyxsykr\nxkysrypjkyawuzmvmhqar",
"output": "NO"
},
{
"input": "ngedczubzdcqbxksnxuavdjaqtmdwncjnoaicvmodcqvhfezew\nwezefhvqcdomvciaonjcnwdmtqajdvauxnskxbqcdzbuzcdegn",
"output": "YES"
},
{
"input": "muooqttvrrljcxbroizkymuidvfmhhsjtumksdkcbwwpfqdyvxtrlymofendqvznzlmim\nmimlznzvqdnefomylrtxvydqfpwwbckdskmutjshhmfvdiumykziorbxcjlrrvttqooum",
"output": "YES"
},
{
"input": "vxpqullmcbegsdskddortcvxyqlbvxmmkhevovnezubvpvnrcajpxraeaxizgaowtfkzywvhnbgzsxbhkaipcmoumtikkiyyaivg\ngviayyikkitmuomcpiakhbxszgbnhvwyzkftwoagzixaearxpjacrnvpvbuzenvovehkmmxvblqyxvctroddksdsgebcmlluqpxv",
"output": "YES"
},
{
"input": "mnhaxtaopjzrkqlbroiyipitndczpunwygstmzevgyjdzyanxkdqnvgkikfabwouwkkbzuiuvgvxgpizsvqsbwepktpdrgdkmfdc\ncdfmkdgrdptkpewbsqvszipgxvgvuiuzbkkwuowbafkikgvnqdkxnayzdjygvezmtsgywnupocdntipiyiorblqkrzjpzatxahnm",
"output": "NO"
},
{
"input": "dgxmzbqofstzcdgthbaewbwocowvhqpinehpjatnnbrijcolvsatbblsrxabzrpszoiecpwhfjmwuhqrapvtcgvikuxtzbftydkw\nwkdytfbztxukivgctvparqhuwmjfhwpceiozsprzbaxrslbbqasvlocjirbnntajphenipthvwocowbweabhtgdcztsfoqbzmxgd",
"output": "NO"
},
{
"input": "gxoixiecetohtgjgbqzvlaobkhstejxdklghowtvwunnnvauriohuspsdmpzckprwajyxldoyckgjivjpmbfqtszmtocovxwgeh\nhegwxvocotmzstqfbmpjvijgkcyodlxyjawrpkczpmdspsuhoiruavnnnuwvtwohglkdxjetshkboalvzqbgjgthoteceixioxg",
"output": "YES"
},
{
"input": "sihxuwvmaambplxvjfoskinghzicyfqebjtkysotattkahssumfcgrkheotdxwjckpvapbkaepqrxseyfrwtyaycmrzsrsngkh\nhkgnsrszrmcyaytwrfyesxrqpeakbpavpkcjwxdtoehkrgcfmusshakttatosyktjbeqfycizhgniksofjvxlpbmaamvwuxhis",
"output": "YES"
},
{
"input": "ycnahksbughnonldzrhkysujmylcgcfuludjvjiahtkyzqvkopzqcnwhltbzfugzojqkjjlggmvnultascmygelkiktmfieok\nkoeifmtkiklegkmcsatlunvmggkjjlqjozgufzbtlhwncqzpokvqzykthaijvjdulufcgclymjusyyhrzdlnonhgubskhancy",
"output": "NO"
},
{
"input": "wbqasaehtkfojruzyhrlgwmtyiovmzyfifslvlemhqheyaelzwnthrenjsbmntwaoryzwfbxmscmypvxlfmzpnkkjlvwvmtz\nztmvwvljkknpzmflxvpymcsmxbfwzyroawtnmbsjnerhtnwzleayehqhmelvlsfifyzmvoiytmwglrhyzurjofktheasaqbw",
"output": "YES"
},
{
"input": "imippqurprbhfugngtgifelytadegwrgaefnfhbjjnmzikvjaccotqzemufqieqldgnbmviisgkynzeldlhqxuqphjfmyij\njiymfjhpquxqhldleznykgsiivmbngdlqeiqfumezqtoccajvkizmnjjbhfnfeagrwgedatylefigtgngufhbrpruqppimi",
"output": "YES"
},
{
"input": "bikydffiuisckpvzqlteqfhegsagimodb\nbdomigasgehfqetlqzvpkcsiuiffdykib",
"output": "YES"
}
] | 1,673,234,965
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 40
| 92
| 0
|
s= input()
t = input()
T= []
new = ""
for i in range (len(s)-1,-1, -1):
T.append(s[i])
for m in T:
new = new + m
if t == new:
print("YES")
else:
print("NO")
|
Title: Translation
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
The translation from the Berland language into the Birland language is not an easy task. Those languages are very similar: a berlandish word differs from a birlandish word with the same meaning a little: it is spelled (and pronounced) reversely. For example, a Berlandish word code corresponds to a Birlandish word edoc. However, it's easy to make a mistake during the «translation». Vasya translated word *s* from Berlandish into Birlandish as *t*. Help him: find out if he translated the word correctly.
Input Specification:
The first line contains word *s*, the second line contains word *t*. The words consist of lowercase Latin letters. The input data do not consist unnecessary spaces. The words are not empty and their lengths do not exceed 100 symbols.
Output Specification:
If the word *t* is a word *s*, written reversely, print YES, otherwise print NO.
Demo Input:
['code\nedoc\n', 'abb\naba\n', 'code\ncode\n']
Demo Output:
['YES\n', 'NO\n', 'NO\n']
Note:
none
|
```python
s= input()
t = input()
T= []
new = ""
for i in range (len(s)-1,-1, -1):
T.append(s[i])
for m in T:
new = new + m
if t == new:
print("YES")
else:
print("NO")
```
| 3.977
|
155
|
A
|
I_love_\%username\%
|
PROGRAMMING
| 800
|
[
"brute force"
] | null | null |
Vasya adores sport programming. He can't write programs but he loves to watch the contests' progress. Vasya even has a favorite coder and Vasya pays special attention to him.
One day Vasya decided to collect the results of all contests where his favorite coder participated and track the progress of his coolness. For each contest where this coder participated, he wrote out a single non-negative number — the number of points his favorite coder earned in the contest. Vasya wrote out the points for the contest in the order, in which the contests run (naturally, no two contests ran simultaneously).
Vasya considers a coder's performance in a contest amazing in two situations: he can break either his best or his worst performance record. First, it is amazing if during the contest the coder earns strictly more points that he earned on each past contest. Second, it is amazing if during the contest the coder earns strictly less points that he earned on each past contest. A coder's first contest isn't considered amazing. Now he wants to count the number of amazing performances the coder had throughout his whole history of participating in contests. But the list of earned points turned out long and Vasya can't code... That's why he asks you to help him.
|
The first line contains the single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of contests where the coder participated.
The next line contains *n* space-separated non-negative integer numbers — they are the points which the coder has earned. The points are given in the chronological order. All points do not exceed 10000.
|
Print the single number — the number of amazing performances the coder has had during his whole history of participating in the contests.
|
[
"5\n100 50 200 150 200\n",
"10\n4664 6496 5814 7010 5762 5736 6944 4850 3698 7242\n"
] |
[
"2\n",
"4\n"
] |
In the first sample the performances number 2 and 3 are amazing.
In the second sample the performances number 2, 4, 9 and 10 are amazing.
| 500
|
[
{
"input": "5\n100 50 200 150 200",
"output": "2"
},
{
"input": "10\n4664 6496 5814 7010 5762 5736 6944 4850 3698 7242",
"output": "4"
},
{
"input": "1\n6",
"output": "0"
},
{
"input": "2\n2 1",
"output": "1"
},
{
"input": "5\n100 36 53 7 81",
"output": "2"
},
{
"input": "5\n7 36 53 81 100",
"output": "4"
},
{
"input": "5\n100 81 53 36 7",
"output": "4"
},
{
"input": "10\n8 6 3 4 9 10 7 7 1 3",
"output": "5"
},
{
"input": "10\n1627 1675 1488 1390 1812 1137 1746 1324 1952 1862",
"output": "6"
},
{
"input": "10\n1 3 3 4 6 7 7 8 9 10",
"output": "7"
},
{
"input": "10\n1952 1862 1812 1746 1675 1627 1488 1390 1324 1137",
"output": "9"
},
{
"input": "25\n1448 4549 2310 2725 2091 3509 1565 2475 2232 3989 4231 779 2967 2702 608 3739 721 1552 2767 530 3114 665 1940 48 4198",
"output": "5"
},
{
"input": "33\n1097 1132 1091 1104 1049 1038 1023 1080 1104 1029 1035 1061 1049 1060 1088 1106 1105 1087 1063 1076 1054 1103 1047 1041 1028 1120 1126 1063 1117 1110 1044 1093 1101",
"output": "5"
},
{
"input": "34\n821 5536 2491 6074 7216 9885 764 1603 778 8736 8987 771 617 1587 8943 7922 439 7367 4115 8886 7878 6899 8811 5752 3184 3401 9760 9400 8995 4681 1323 6637 6554 6498",
"output": "7"
},
{
"input": "68\n6764 6877 6950 6768 6839 6755 6726 6778 6699 6805 6777 6985 6821 6801 6791 6805 6940 6761 6677 6999 6911 6699 6959 6933 6903 6843 6972 6717 6997 6756 6789 6668 6735 6852 6735 6880 6723 6834 6810 6694 6780 6679 6698 6857 6826 6896 6979 6968 6957 6988 6960 6700 6919 6892 6984 6685 6813 6678 6715 6857 6976 6902 6780 6686 6777 6686 6842 6679",
"output": "9"
},
{
"input": "60\n9000 9014 9034 9081 9131 9162 9174 9199 9202 9220 9221 9223 9229 9235 9251 9260 9268 9269 9270 9298 9307 9309 9313 9323 9386 9399 9407 9495 9497 9529 9531 9544 9614 9615 9627 9627 9643 9654 9656 9657 9685 9699 9701 9736 9745 9758 9799 9827 9843 9845 9854 9854 9885 9891 9896 9913 9942 9963 9986 9992",
"output": "57"
},
{
"input": "100\n7 61 12 52 41 16 34 99 30 44 48 89 31 54 21 1 48 52 61 15 35 87 21 76 64 92 44 81 16 93 84 92 32 15 68 76 53 39 26 4 11 26 7 4 99 99 61 65 55 85 65 67 47 39 2 74 63 49 98 87 5 94 22 30 25 42 31 84 49 23 89 60 16 26 92 27 9 57 75 61 94 35 83 47 99 100 63 24 91 88 79 10 15 45 22 64 3 11 89 83",
"output": "4"
},
{
"input": "100\n9999 9999 9999 9998 9998 9998 9997 9996 9996 9995 9993 9993 9991 9990 9989 9986 9984 9984 9983 9981 9981 9980 9980 9980 9979 9977 9977 9977 9977 9977 9976 9976 9975 9975 9973 9972 9972 9972 9972 9971 9969 9969 9969 9968 9967 9965 9962 9962 9962 9962 9960 9958 9958 9955 9954 9954 9954 9954 9950 9949 9949 9947 9943 9943 9940 9940 9939 9937 9937 9937 9936 9935 9932 9932 9931 9929 9927 9927 9926 9923 9919 9919 9918 9918 9918 9917 9917 9916 9916 9915 9914 9911 9910 9907 9907 9906 9905 9905 9904 9901",
"output": "57"
},
{
"input": "100\n158 159 157 156 155 154 160 153 161 152 162 163 151 164 150 165 149 148 147 166 146 167 145 144 143 142 168 141 169 170 140 139 138 137 171 136 135 134 172 173 174 133 175 132 177 178 131 179 180 130 129 181 128 127 182 126 183 125 124 184 123 122 121 120 119 118 117 185 186 187 188 189 116 190 115 191 192 193 114 113 112 111 110 109 108 194 195 107 106 105 196 197 104 198 199 103 102 200 101 100",
"output": "99"
},
{
"input": "2\n0 10000",
"output": "1"
},
{
"input": "2\n5 5",
"output": "0"
},
{
"input": "2\n1 1",
"output": "0"
},
{
"input": "2\n10 10",
"output": "0"
},
{
"input": "1\n0",
"output": "0"
}
] | 1,686,462,752
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 37
| 92
| 0
|
n = int(input())
l = [int(x) for x in input().split()]
low = l[0]
high = l[0]
cnt = 0
for i in range(1,n):
if l[i] < low:
cnt += 1
low = l[i]
if l[i] > high:
cnt += 1
high = l[i]
print(cnt)
|
Title: I_love_\%username\%
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya adores sport programming. He can't write programs but he loves to watch the contests' progress. Vasya even has a favorite coder and Vasya pays special attention to him.
One day Vasya decided to collect the results of all contests where his favorite coder participated and track the progress of his coolness. For each contest where this coder participated, he wrote out a single non-negative number — the number of points his favorite coder earned in the contest. Vasya wrote out the points for the contest in the order, in which the contests run (naturally, no two contests ran simultaneously).
Vasya considers a coder's performance in a contest amazing in two situations: he can break either his best or his worst performance record. First, it is amazing if during the contest the coder earns strictly more points that he earned on each past contest. Second, it is amazing if during the contest the coder earns strictly less points that he earned on each past contest. A coder's first contest isn't considered amazing. Now he wants to count the number of amazing performances the coder had throughout his whole history of participating in contests. But the list of earned points turned out long and Vasya can't code... That's why he asks you to help him.
Input Specification:
The first line contains the single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of contests where the coder participated.
The next line contains *n* space-separated non-negative integer numbers — they are the points which the coder has earned. The points are given in the chronological order. All points do not exceed 10000.
Output Specification:
Print the single number — the number of amazing performances the coder has had during his whole history of participating in the contests.
Demo Input:
['5\n100 50 200 150 200\n', '10\n4664 6496 5814 7010 5762 5736 6944 4850 3698 7242\n']
Demo Output:
['2\n', '4\n']
Note:
In the first sample the performances number 2 and 3 are amazing.
In the second sample the performances number 2, 4, 9 and 10 are amazing.
|
```python
n = int(input())
l = [int(x) for x in input().split()]
low = l[0]
high = l[0]
cnt = 0
for i in range(1,n):
if l[i] < low:
cnt += 1
low = l[i]
if l[i] > high:
cnt += 1
high = l[i]
print(cnt)
```
| 3
|
|
633
|
A
|
Ebony and Ivory
|
PROGRAMMING
| 1,100
|
[
"brute force",
"math",
"number theory"
] | null | null |
Dante is engaged in a fight with "The Savior". Before he can fight it with his sword, he needs to break its shields. He has two guns, Ebony and Ivory, each of them is able to perform any non-negative number of shots.
For every bullet that hits the shield, Ebony deals *a* units of damage while Ivory deals *b* units of damage. In order to break the shield Dante has to deal exactly *c* units of damage. Find out if this is possible.
|
The first line of the input contains three integers *a*, *b*, *c* (1<=≤<=*a*,<=*b*<=≤<=100,<=1<=≤<=*c*<=≤<=10<=000) — the number of units of damage dealt by Ebony gun and Ivory gun, and the total number of damage required to break the shield, respectively.
|
Print "Yes" (without quotes) if Dante can deal exactly *c* damage to the shield and "No" (without quotes) otherwise.
|
[
"4 6 15\n",
"3 2 7\n",
"6 11 6\n"
] |
[
"No\n",
"Yes\n",
"Yes\n"
] |
In the second sample, Dante can fire 1 bullet from Ebony and 2 from Ivory to deal exactly 1·3 + 2·2 = 7 damage. In the third sample, Dante can fire 1 bullet from ebony and no bullets from ivory to do 1·6 + 0·11 = 6 damage.
| 250
|
[
{
"input": "4 6 15",
"output": "No"
},
{
"input": "3 2 7",
"output": "Yes"
},
{
"input": "6 11 6",
"output": "Yes"
},
{
"input": "3 12 15",
"output": "Yes"
},
{
"input": "5 5 10",
"output": "Yes"
},
{
"input": "6 6 7",
"output": "No"
},
{
"input": "1 1 20",
"output": "Yes"
},
{
"input": "12 14 19",
"output": "No"
},
{
"input": "15 12 26",
"output": "No"
},
{
"input": "2 4 8",
"output": "Yes"
},
{
"input": "4 5 30",
"output": "Yes"
},
{
"input": "4 5 48",
"output": "Yes"
},
{
"input": "2 17 105",
"output": "Yes"
},
{
"input": "10 25 282",
"output": "No"
},
{
"input": "6 34 323",
"output": "No"
},
{
"input": "2 47 464",
"output": "Yes"
},
{
"input": "4 53 113",
"output": "Yes"
},
{
"input": "6 64 546",
"output": "Yes"
},
{
"input": "1 78 725",
"output": "Yes"
},
{
"input": "1 84 811",
"output": "Yes"
},
{
"input": "3 100 441",
"output": "Yes"
},
{
"input": "20 5 57",
"output": "No"
},
{
"input": "14 19 143",
"output": "No"
},
{
"input": "17 23 248",
"output": "No"
},
{
"input": "11 34 383",
"output": "Yes"
},
{
"input": "20 47 568",
"output": "Yes"
},
{
"input": "16 58 410",
"output": "Yes"
},
{
"input": "11 70 1199",
"output": "Yes"
},
{
"input": "16 78 712",
"output": "Yes"
},
{
"input": "20 84 562",
"output": "No"
},
{
"input": "19 100 836",
"output": "Yes"
},
{
"input": "23 10 58",
"output": "No"
},
{
"input": "25 17 448",
"output": "Yes"
},
{
"input": "22 24 866",
"output": "Yes"
},
{
"input": "24 35 67",
"output": "No"
},
{
"input": "29 47 264",
"output": "Yes"
},
{
"input": "23 56 45",
"output": "No"
},
{
"input": "25 66 1183",
"output": "Yes"
},
{
"input": "21 71 657",
"output": "Yes"
},
{
"input": "29 81 629",
"output": "No"
},
{
"input": "23 95 2226",
"output": "Yes"
},
{
"input": "32 4 62",
"output": "No"
},
{
"input": "37 15 789",
"output": "Yes"
},
{
"input": "39 24 999",
"output": "Yes"
},
{
"input": "38 32 865",
"output": "No"
},
{
"input": "32 50 205",
"output": "No"
},
{
"input": "31 57 1362",
"output": "Yes"
},
{
"input": "38 68 1870",
"output": "Yes"
},
{
"input": "36 76 549",
"output": "No"
},
{
"input": "35 84 1257",
"output": "No"
},
{
"input": "39 92 2753",
"output": "Yes"
},
{
"input": "44 1 287",
"output": "Yes"
},
{
"input": "42 12 830",
"output": "No"
},
{
"input": "42 27 9",
"output": "No"
},
{
"input": "49 40 1422",
"output": "No"
},
{
"input": "44 42 2005",
"output": "No"
},
{
"input": "50 55 2479",
"output": "No"
},
{
"input": "48 65 917",
"output": "No"
},
{
"input": "45 78 152",
"output": "No"
},
{
"input": "43 90 4096",
"output": "Yes"
},
{
"input": "43 94 4316",
"output": "Yes"
},
{
"input": "60 7 526",
"output": "Yes"
},
{
"input": "53 11 735",
"output": "Yes"
},
{
"input": "52 27 609",
"output": "Yes"
},
{
"input": "57 32 992",
"output": "Yes"
},
{
"input": "52 49 421",
"output": "No"
},
{
"input": "57 52 2634",
"output": "Yes"
},
{
"input": "54 67 3181",
"output": "Yes"
},
{
"input": "52 73 638",
"output": "No"
},
{
"input": "57 84 3470",
"output": "No"
},
{
"input": "52 100 5582",
"output": "No"
},
{
"input": "62 1 501",
"output": "Yes"
},
{
"input": "63 17 858",
"output": "Yes"
},
{
"input": "70 24 1784",
"output": "Yes"
},
{
"input": "65 32 1391",
"output": "Yes"
},
{
"input": "62 50 2775",
"output": "No"
},
{
"input": "62 58 88",
"output": "No"
},
{
"input": "66 68 3112",
"output": "Yes"
},
{
"input": "61 71 1643",
"output": "No"
},
{
"input": "69 81 3880",
"output": "No"
},
{
"input": "63 100 1960",
"output": "Yes"
},
{
"input": "73 6 431",
"output": "Yes"
},
{
"input": "75 19 736",
"output": "Yes"
},
{
"input": "78 25 247",
"output": "No"
},
{
"input": "79 36 2854",
"output": "Yes"
},
{
"input": "80 43 1864",
"output": "Yes"
},
{
"input": "76 55 2196",
"output": "Yes"
},
{
"input": "76 69 4122",
"output": "Yes"
},
{
"input": "76 76 4905",
"output": "No"
},
{
"input": "75 89 3056",
"output": "Yes"
},
{
"input": "73 100 3111",
"output": "Yes"
},
{
"input": "84 9 530",
"output": "No"
},
{
"input": "82 18 633",
"output": "No"
},
{
"input": "85 29 2533",
"output": "Yes"
},
{
"input": "89 38 2879",
"output": "Yes"
},
{
"input": "89 49 2200",
"output": "Yes"
},
{
"input": "88 60 4140",
"output": "Yes"
},
{
"input": "82 68 1299",
"output": "No"
},
{
"input": "90 76 2207",
"output": "No"
},
{
"input": "83 84 4923",
"output": "Yes"
},
{
"input": "89 99 7969",
"output": "Yes"
},
{
"input": "94 9 168",
"output": "No"
},
{
"input": "91 20 1009",
"output": "No"
},
{
"input": "93 23 2872",
"output": "Yes"
},
{
"input": "97 31 3761",
"output": "Yes"
},
{
"input": "99 46 1341",
"output": "Yes"
},
{
"input": "98 51 2845",
"output": "No"
},
{
"input": "93 66 3412",
"output": "No"
},
{
"input": "95 76 3724",
"output": "Yes"
},
{
"input": "91 87 6237",
"output": "Yes"
},
{
"input": "98 97 7886",
"output": "Yes"
},
{
"input": "12 17 15",
"output": "No"
},
{
"input": "93 94 95",
"output": "No"
},
{
"input": "27 43 27",
"output": "Yes"
},
{
"input": "17 43 68",
"output": "Yes"
},
{
"input": "44 12 12",
"output": "Yes"
},
{
"input": "44 50 150",
"output": "Yes"
},
{
"input": "1 1 10000",
"output": "Yes"
},
{
"input": "2 3 10000",
"output": "Yes"
},
{
"input": "100 1 10",
"output": "Yes"
},
{
"input": "3 2 1",
"output": "No"
},
{
"input": "1 1 1",
"output": "Yes"
},
{
"input": "9 9 10000",
"output": "No"
},
{
"input": "2 3 9995",
"output": "Yes"
},
{
"input": "3 5 4",
"output": "No"
},
{
"input": "99 98 100",
"output": "No"
},
{
"input": "6 10 2",
"output": "No"
},
{
"input": "1 6 5",
"output": "Yes"
},
{
"input": "1 4 3",
"output": "Yes"
},
{
"input": "3 2 3",
"output": "Yes"
},
{
"input": "1 7 6",
"output": "Yes"
},
{
"input": "2 3 9871",
"output": "Yes"
},
{
"input": "10 5 5",
"output": "Yes"
},
{
"input": "10 8 2",
"output": "No"
}
] | 1,541,648,528
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 171
| 1,126,400
|
from fractions import gcd
a, b, c = [int(x) for x in input().split()]
for i in range(0, c, a):
if (c - i) % b == 0:
print("Yes")
break
else:
print("No")
|
Title: Ebony and Ivory
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Dante is engaged in a fight with "The Savior". Before he can fight it with his sword, he needs to break its shields. He has two guns, Ebony and Ivory, each of them is able to perform any non-negative number of shots.
For every bullet that hits the shield, Ebony deals *a* units of damage while Ivory deals *b* units of damage. In order to break the shield Dante has to deal exactly *c* units of damage. Find out if this is possible.
Input Specification:
The first line of the input contains three integers *a*, *b*, *c* (1<=≤<=*a*,<=*b*<=≤<=100,<=1<=≤<=*c*<=≤<=10<=000) — the number of units of damage dealt by Ebony gun and Ivory gun, and the total number of damage required to break the shield, respectively.
Output Specification:
Print "Yes" (without quotes) if Dante can deal exactly *c* damage to the shield and "No" (without quotes) otherwise.
Demo Input:
['4 6 15\n', '3 2 7\n', '6 11 6\n']
Demo Output:
['No\n', 'Yes\n', 'Yes\n']
Note:
In the second sample, Dante can fire 1 bullet from Ebony and 2 from Ivory to deal exactly 1·3 + 2·2 = 7 damage. In the third sample, Dante can fire 1 bullet from ebony and no bullets from ivory to do 1·6 + 0·11 = 6 damage.
|
```python
from fractions import gcd
a, b, c = [int(x) for x in input().split()]
for i in range(0, c, a):
if (c - i) % b == 0:
print("Yes")
break
else:
print("No")
```
| 0
|
|
4
|
A
|
Watermelon
|
PROGRAMMING
| 800
|
[
"brute force",
"math"
] |
A. Watermelon
|
1
|
64
|
One hot summer day Pete and his friend Billy decided to buy a watermelon. They chose the biggest and the ripest one, in their opinion. After that the watermelon was weighed, and the scales showed *w* kilos. They rushed home, dying of thirst, and decided to divide the berry, however they faced a hard problem.
Pete and Billy are great fans of even numbers, that's why they want to divide the watermelon in such a way that each of the two parts weighs even number of kilos, at the same time it is not obligatory that the parts are equal. The boys are extremely tired and want to start their meal as soon as possible, that's why you should help them and find out, if they can divide the watermelon in the way they want. For sure, each of them should get a part of positive weight.
|
The first (and the only) input line contains integer number *w* (1<=≤<=*w*<=≤<=100) — the weight of the watermelon bought by the boys.
|
Print YES, if the boys can divide the watermelon into two parts, each of them weighing even number of kilos; and NO in the opposite case.
|
[
"8\n"
] |
[
"YES\n"
] |
For example, the boys can divide the watermelon into two parts of 2 and 6 kilos respectively (another variant — two parts of 4 and 4 kilos).
| 0
|
[
{
"input": "8",
"output": "YES"
},
{
"input": "5",
"output": "NO"
},
{
"input": "4",
"output": "YES"
},
{
"input": "3",
"output": "NO"
},
{
"input": "2",
"output": "NO"
},
{
"input": "1",
"output": "NO"
},
{
"input": "7",
"output": "NO"
},
{
"input": "6",
"output": "YES"
},
{
"input": "10",
"output": "YES"
},
{
"input": "9",
"output": "NO"
},
{
"input": "53",
"output": "NO"
},
{
"input": "77",
"output": "NO"
},
{
"input": "32",
"output": "YES"
},
{
"input": "44",
"output": "YES"
},
{
"input": "98",
"output": "YES"
},
{
"input": "99",
"output": "NO"
},
{
"input": "90",
"output": "YES"
},
{
"input": "67",
"output": "NO"
},
{
"input": "100",
"output": "YES"
},
{
"input": "88",
"output": "YES"
}
] | 1,693,530,013
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 20
| 92
| 0
|
inp1=int(input())
#inp1=(2x)+(2b)
#inp1=2(x+b)
if inp1%2==0 and inp1>=4:
print("YES")
else:
print("NO")
|
Title: Watermelon
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
One hot summer day Pete and his friend Billy decided to buy a watermelon. They chose the biggest and the ripest one, in their opinion. After that the watermelon was weighed, and the scales showed *w* kilos. They rushed home, dying of thirst, and decided to divide the berry, however they faced a hard problem.
Pete and Billy are great fans of even numbers, that's why they want to divide the watermelon in such a way that each of the two parts weighs even number of kilos, at the same time it is not obligatory that the parts are equal. The boys are extremely tired and want to start their meal as soon as possible, that's why you should help them and find out, if they can divide the watermelon in the way they want. For sure, each of them should get a part of positive weight.
Input Specification:
The first (and the only) input line contains integer number *w* (1<=≤<=*w*<=≤<=100) — the weight of the watermelon bought by the boys.
Output Specification:
Print YES, if the boys can divide the watermelon into two parts, each of them weighing even number of kilos; and NO in the opposite case.
Demo Input:
['8\n']
Demo Output:
['YES\n']
Note:
For example, the boys can divide the watermelon into two parts of 2 and 6 kilos respectively (another variant — two parts of 4 and 4 kilos).
|
```python
inp1=int(input())
#inp1=(2x)+(2b)
#inp1=2(x+b)
if inp1%2==0 and inp1>=4:
print("YES")
else:
print("NO")
```
| 3.954
|
887
|
A
|
Div. 64
|
PROGRAMMING
| 1,000
|
[
"implementation"
] | null | null |
Top-model Izabella participates in the competition. She wants to impress judges and show her mathematical skills.
Her problem is following: for given string, consisting of only 0 and 1, tell if it's possible to remove some digits in such a way, that remaining number is a representation of some positive integer, divisible by 64, in the binary numerical system.
|
In the only line given a non-empty binary string *s* with length up to 100.
|
Print «yes» (without quotes) if it's possible to remove digits required way and «no» otherwise.
|
[
"100010001\n",
"100\n"
] |
[
"yes",
"no"
] |
In the first test case, you can get string 1 000 000 after removing two ones which is a representation of number 64 in the binary numerical system.
You can read more about binary numeral system representation here: [https://en.wikipedia.org/wiki/Binary_system](https://en.wikipedia.org/wiki/Binary_system)
| 500
|
[
{
"input": "100010001",
"output": "yes"
},
{
"input": "100",
"output": "no"
},
{
"input": "0000001000000",
"output": "yes"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "no"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111111111111110111111111111111111111111111",
"output": "no"
},
{
"input": "0111111101111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "no"
},
{
"input": "1111011111111111111111111111110111110111111111111111111111011111111111111110111111111111111111111111",
"output": "no"
},
{
"input": "1111111111101111111111111111111111111011111111111111111111111101111011111101111111111101111111111111",
"output": "yes"
},
{
"input": "0110111111111111111111011111111110110111110111111111111111111111111111111111111110111111111111111111",
"output": "yes"
},
{
"input": "1100110001111011001101101000001110111110011110111110010100011000100101000010010111100000010001001101",
"output": "yes"
},
{
"input": "000000",
"output": "no"
},
{
"input": "0001000",
"output": "no"
},
{
"input": "0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
"output": "no"
},
{
"input": "1000000",
"output": "yes"
},
{
"input": "0",
"output": "no"
},
{
"input": "1",
"output": "no"
},
{
"input": "10000000000",
"output": "yes"
},
{
"input": "0000000000",
"output": "no"
},
{
"input": "0010000",
"output": "no"
},
{
"input": "000000011",
"output": "no"
},
{
"input": "000000000",
"output": "no"
},
{
"input": "00000000",
"output": "no"
},
{
"input": "000000000011",
"output": "no"
},
{
"input": "0000000",
"output": "no"
},
{
"input": "00000000011",
"output": "no"
},
{
"input": "000000001",
"output": "no"
},
{
"input": "000000000000000000000000000",
"output": "no"
},
{
"input": "0000001",
"output": "no"
},
{
"input": "00000001",
"output": "no"
},
{
"input": "00000000100",
"output": "no"
},
{
"input": "00000000000000000000",
"output": "no"
},
{
"input": "0000000000000000000",
"output": "no"
},
{
"input": "00001000",
"output": "no"
},
{
"input": "0000000000010",
"output": "no"
},
{
"input": "000000000010",
"output": "no"
},
{
"input": "000000000000010",
"output": "no"
},
{
"input": "0100000",
"output": "no"
},
{
"input": "00010000",
"output": "no"
},
{
"input": "00000000000000000",
"output": "no"
},
{
"input": "00000000000",
"output": "no"
},
{
"input": "000001000",
"output": "no"
},
{
"input": "000000000000",
"output": "no"
},
{
"input": "100000000000000",
"output": "yes"
},
{
"input": "000010000",
"output": "no"
},
{
"input": "00000100",
"output": "no"
},
{
"input": "0001100000",
"output": "no"
},
{
"input": "000000000000000000000000001",
"output": "no"
},
{
"input": "000000100",
"output": "no"
},
{
"input": "0000000000001111111111",
"output": "no"
},
{
"input": "00000010",
"output": "no"
},
{
"input": "0001110000",
"output": "no"
},
{
"input": "0000000000000000000000",
"output": "no"
},
{
"input": "000000010010",
"output": "no"
},
{
"input": "0000100",
"output": "no"
},
{
"input": "0000000001",
"output": "no"
},
{
"input": "000000111",
"output": "no"
},
{
"input": "0000000000000",
"output": "no"
},
{
"input": "000000000000000000",
"output": "no"
},
{
"input": "0000000000000000000000000",
"output": "no"
},
{
"input": "000000000000000",
"output": "no"
},
{
"input": "0010000000000100",
"output": "yes"
},
{
"input": "0000001000",
"output": "no"
},
{
"input": "00000000000000000001",
"output": "no"
},
{
"input": "100000000",
"output": "yes"
},
{
"input": "000000000001",
"output": "no"
},
{
"input": "0000011001",
"output": "no"
},
{
"input": "000",
"output": "no"
},
{
"input": "000000000000000000000",
"output": "no"
},
{
"input": "0000000000011",
"output": "no"
},
{
"input": "0000000000000000",
"output": "no"
},
{
"input": "00000000000000001",
"output": "no"
},
{
"input": "00000000000000",
"output": "no"
},
{
"input": "0000000000000000010",
"output": "no"
},
{
"input": "00000000000000000000000000000000000000000000000000000000",
"output": "no"
},
{
"input": "000011000",
"output": "no"
},
{
"input": "00000011",
"output": "no"
},
{
"input": "0000000000001100",
"output": "no"
},
{
"input": "00000",
"output": "no"
},
{
"input": "000000000000000000000000000111111111111111",
"output": "no"
},
{
"input": "000000010",
"output": "no"
},
{
"input": "00000000111",
"output": "no"
},
{
"input": "000000000000001",
"output": "no"
},
{
"input": "0000000000000011111111111111111",
"output": "no"
},
{
"input": "0000000010",
"output": "no"
},
{
"input": "0000000000000000000000000000000000000000000000000",
"output": "no"
},
{
"input": "00000000010",
"output": "no"
},
{
"input": "101000000000",
"output": "yes"
},
{
"input": "00100000",
"output": "no"
},
{
"input": "00000000000001",
"output": "no"
},
{
"input": "0000000000100",
"output": "no"
},
{
"input": "0000",
"output": "no"
},
{
"input": "00000000000111",
"output": "no"
},
{
"input": "0000000000000011",
"output": "no"
},
{
"input": "0000000000000000000000000000000000000000",
"output": "no"
},
{
"input": "0000000000000010",
"output": "no"
},
{
"input": "0010101010",
"output": "no"
},
{
"input": "0000000000000001",
"output": "no"
},
{
"input": "1010101",
"output": "no"
}
] | 1,604,049,374
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 98
| 109
| 0
|
x=input()
y=x.find('1')
x=x[y:]
y=x.count('0')
if(y>5):
print("YES")
else:
print("NO")
|
Title: Div. 64
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Top-model Izabella participates in the competition. She wants to impress judges and show her mathematical skills.
Her problem is following: for given string, consisting of only 0 and 1, tell if it's possible to remove some digits in such a way, that remaining number is a representation of some positive integer, divisible by 64, in the binary numerical system.
Input Specification:
In the only line given a non-empty binary string *s* with length up to 100.
Output Specification:
Print «yes» (without quotes) if it's possible to remove digits required way and «no» otherwise.
Demo Input:
['100010001\n', '100\n']
Demo Output:
['yes', 'no']
Note:
In the first test case, you can get string 1 000 000 after removing two ones which is a representation of number 64 in the binary numerical system.
You can read more about binary numeral system representation here: [https://en.wikipedia.org/wiki/Binary_system](https://en.wikipedia.org/wiki/Binary_system)
|
```python
x=input()
y=x.find('1')
x=x[y:]
y=x.count('0')
if(y>5):
print("YES")
else:
print("NO")
```
| 3
|
|
105
|
E
|
Lift and Throw
|
PROGRAMMING
| 2,500
|
[
"brute force"
] |
E. Lift and Throw
|
1
|
256
|
You are given a straight half-line divided into segments of unit length, which we will call positions. The positions are numbered by positive integers that start with 1 from the end of half-line, i. e. 1, 2, 3 and so on. The distance between the positions is the absolute difference between the respective numbers.
Laharl, Etna and Flonne occupy some positions on the half-line and they want to get to the position with the largest possible number. They are originally placed in different positions.
Each of the characters can perform each of the following actions no more than once:
- Move a certain distance. - Grab another character and lift him above the head. - Throw the lifted character a certain distance.
Each character has a movement range parameter. They can only move to free positions, assuming that distance between those positions doesn't exceed the movement range.
One character can lift another character if the distance between the two characters equals 1, and no one already holds that another character. We can assume that the lifted character moves to the same position as the person who has lifted him, and the position in which he stood before becomes free. A lifted character cannot perform any actions and the character that holds him cannot walk.
Also, each character has a throwing range parameter. It is the distance at which this character can throw the one lifted above his head. He can only throw a character to a free position, and only when there is a lifted character.
We accept the situation when one person grabs another one who in his turn has the third character in his hands. This forms a "column" of three characters. For example, Laharl can hold Etna while Etna holds Flonne. In this case, Etna and the Flonne cannot perform any actions, and Laharl can only throw Etna (together with Flonne) at some distance.
Laharl, Etna and Flonne perform actions in any order. They perform actions in turns, that is no two of them can do actions at the same time.
Determine the maximum number of position at least one of the characters can reach. That is, such maximal number *x* so that one of the characters can reach position *x*.
|
The first line contains three integers: Laharl's position, his movement range and throwing range. The second and the third lines describe Etna's and Flonne's parameters correspondingly in the similar form. It is guaranteed that the three characters occupy distinct positions. All numbers in the input are between 1 and 10, inclusive.
|
Print a single number — the maximum ordinal number of position which either Laharl, Etna or Flonne can reach.
|
[
"9 3 3\n4 3 1\n2 3 3\n"
] |
[
"15"
] |
Let us explain how to reach position 15 in the sample.
Initially Laharl occupies position 9, Etna — position 4 and Flonne — position 2.
First Laharl moves to position 6.
Then Flonne moves to position 5 and grabs Etna.
Laharl grabs Flonne and throws to position 9.
Flonne throws Etna to position 12.
Etna moves to position 15.
| 2,500
|
[] | 1,689,182,657
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 0
| 46
| 0
|
print("_RANDOM_GUESS_1689182657.646913")# 1689182657.646954
|
Title: Lift and Throw
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
You are given a straight half-line divided into segments of unit length, which we will call positions. The positions are numbered by positive integers that start with 1 from the end of half-line, i. e. 1, 2, 3 and so on. The distance between the positions is the absolute difference between the respective numbers.
Laharl, Etna and Flonne occupy some positions on the half-line and they want to get to the position with the largest possible number. They are originally placed in different positions.
Each of the characters can perform each of the following actions no more than once:
- Move a certain distance. - Grab another character and lift him above the head. - Throw the lifted character a certain distance.
Each character has a movement range parameter. They can only move to free positions, assuming that distance between those positions doesn't exceed the movement range.
One character can lift another character if the distance between the two characters equals 1, and no one already holds that another character. We can assume that the lifted character moves to the same position as the person who has lifted him, and the position in which he stood before becomes free. A lifted character cannot perform any actions and the character that holds him cannot walk.
Also, each character has a throwing range parameter. It is the distance at which this character can throw the one lifted above his head. He can only throw a character to a free position, and only when there is a lifted character.
We accept the situation when one person grabs another one who in his turn has the third character in his hands. This forms a "column" of three characters. For example, Laharl can hold Etna while Etna holds Flonne. In this case, Etna and the Flonne cannot perform any actions, and Laharl can only throw Etna (together with Flonne) at some distance.
Laharl, Etna and Flonne perform actions in any order. They perform actions in turns, that is no two of them can do actions at the same time.
Determine the maximum number of position at least one of the characters can reach. That is, such maximal number *x* so that one of the characters can reach position *x*.
Input Specification:
The first line contains three integers: Laharl's position, his movement range and throwing range. The second and the third lines describe Etna's and Flonne's parameters correspondingly in the similar form. It is guaranteed that the three characters occupy distinct positions. All numbers in the input are between 1 and 10, inclusive.
Output Specification:
Print a single number — the maximum ordinal number of position which either Laharl, Etna or Flonne can reach.
Demo Input:
['9 3 3\n4 3 1\n2 3 3\n']
Demo Output:
['15']
Note:
Let us explain how to reach position 15 in the sample.
Initially Laharl occupies position 9, Etna — position 4 and Flonne — position 2.
First Laharl moves to position 6.
Then Flonne moves to position 5 and grabs Etna.
Laharl grabs Flonne and throws to position 9.
Flonne throws Etna to position 12.
Etna moves to position 15.
|
```python
print("_RANDOM_GUESS_1689182657.646913")# 1689182657.646954
```
| 0
|
281
|
A
|
Word Capitalization
|
PROGRAMMING
| 800
|
[
"implementation",
"strings"
] | null | null |
Capitalization is writing a word with its first letter as a capital letter. Your task is to capitalize the given word.
Note, that during capitalization all the letters except the first one remains unchanged.
|
A single line contains a non-empty word. This word consists of lowercase and uppercase English letters. The length of the word will not exceed 103.
|
Output the given word after capitalization.
|
[
"ApPLe\n",
"konjac\n"
] |
[
"ApPLe\n",
"Konjac\n"
] |
none
| 500
|
[
{
"input": "ApPLe",
"output": "ApPLe"
},
{
"input": "konjac",
"output": "Konjac"
},
{
"input": "a",
"output": "A"
},
{
"input": "A",
"output": "A"
},
{
"input": "z",
"output": "Z"
},
{
"input": "ABACABA",
"output": "ABACABA"
},
{
"input": "xYaPxPxHxGePfGtQySlNrLxSjDtNnTaRaEpAhPaQpWnDzMqGgRgEwJxGiBdZnMtHxFbObCaGiCeZkUqIgBhHtNvAqAlHpMnQhNeQbMyZrCdElVwHtKrPpJjIaHuIlYwHaRkAkUpPlOhNlBtXwDsKzPyHrPiUwNlXtTaPuMwTqYtJySgFoXvLiHbQwMjSvXsQfKhVlOxGdQkWjBhEyQvBjPoFkThNeRhTuIzFjInJtEfPjOlOsJpJuLgLzFnZmKvFgFrNsOnVqFcNiMfCqTpKnVyLwNqFiTySpWeTdFnWuTwDkRjVxNyQvTrOoEiExYiFaIrLoFmJfZcDkHuWjYfCeEqCvEsZiWnJaEmFbMjDvYwEeJeGcKbVbChGsIzNlExHzHiTlHcSaKxLuZxX",
"output": "XYaPxPxHxGePfGtQySlNrLxSjDtNnTaRaEpAhPaQpWnDzMqGgRgEwJxGiBdZnMtHxFbObCaGiCeZkUqIgBhHtNvAqAlHpMnQhNeQbMyZrCdElVwHtKrPpJjIaHuIlYwHaRkAkUpPlOhNlBtXwDsKzPyHrPiUwNlXtTaPuMwTqYtJySgFoXvLiHbQwMjSvXsQfKhVlOxGdQkWjBhEyQvBjPoFkThNeRhTuIzFjInJtEfPjOlOsJpJuLgLzFnZmKvFgFrNsOnVqFcNiMfCqTpKnVyLwNqFiTySpWeTdFnWuTwDkRjVxNyQvTrOoEiExYiFaIrLoFmJfZcDkHuWjYfCeEqCvEsZiWnJaEmFbMjDvYwEeJeGcKbVbChGsIzNlExHzHiTlHcSaKxLuZxX"
},
{
"input": "rZhIcQlXpNcPgXrOjTiOlMoTgXgIhCfMwZfWoFzGhEkQlOoMjIuShPlZfWkNnMyQfYdUhVgQuSmYoElEtZpDyHtOxXgCpWbZqSbYnPqBcNqRtPgCnJnAyIvNsAhRbNeVlMwZyRyJnFgIsCnSbOdLvUyIeOzQvRpMoMoHfNhHwKvTcHuYnYySfPmAiNwAiWdZnWlLvGfBbRbRrCrBqIgIdWkWiBsNyYkKdNxZdGaToSsDnXpRaGrKxBpQsCzBdQgZzBkGeHgGxNrIyQlSzWsTmSnZwOcHqQpNcQvJlPvKaPiQaMaYsQjUeCqQdCjPgUbDmWiJmNiXgExLqOcCtSwSePnUxIuZfIfBeWbEiVbXnUsPwWyAiXyRbZgKwOqFfCtQuKxEmVeRlAkOeXkO",
"output": "RZhIcQlXpNcPgXrOjTiOlMoTgXgIhCfMwZfWoFzGhEkQlOoMjIuShPlZfWkNnMyQfYdUhVgQuSmYoElEtZpDyHtOxXgCpWbZqSbYnPqBcNqRtPgCnJnAyIvNsAhRbNeVlMwZyRyJnFgIsCnSbOdLvUyIeOzQvRpMoMoHfNhHwKvTcHuYnYySfPmAiNwAiWdZnWlLvGfBbRbRrCrBqIgIdWkWiBsNyYkKdNxZdGaToSsDnXpRaGrKxBpQsCzBdQgZzBkGeHgGxNrIyQlSzWsTmSnZwOcHqQpNcQvJlPvKaPiQaMaYsQjUeCqQdCjPgUbDmWiJmNiXgExLqOcCtSwSePnUxIuZfIfBeWbEiVbXnUsPwWyAiXyRbZgKwOqFfCtQuKxEmVeRlAkOeXkO"
},
{
"input": "hDgZlUmLhYbLkLcNcKeOwJwTePbOvLaRvNzQbSbLsPeHqLhUqWtUbNdQfQqFfXeJqJwWuOrFnDdZiPxIkDyVmHbHvXfIlFqSgAcSyWbOlSlRuPhWdEpEzEeLnXwCtWuVcHaUeRgCiYsIvOaIgDnFuDbRnMoCmPrZfLeFpSjQaTfHgZwZvAzDuSeNwSoWuJvLqKqAuUxFaCxFfRcEjEsJpOfCtDiVrBqNsNwPuGoRgPzRpLpYnNyQxKaNnDnYiJrCrVcHlOxPiPcDbEgKfLwBjLhKcNeMgJhJmOiJvPfOaPaEuGqWvRbErKrIpDkEoQnKwJnTlStLyNsHyOjZfKoIjXwUvRrWpSyYhRpQdLqGmErAiNcGqAqIrTeTiMuPmCrEkHdBrLyCxPtYpRqD",
"output": "HDgZlUmLhYbLkLcNcKeOwJwTePbOvLaRvNzQbSbLsPeHqLhUqWtUbNdQfQqFfXeJqJwWuOrFnDdZiPxIkDyVmHbHvXfIlFqSgAcSyWbOlSlRuPhWdEpEzEeLnXwCtWuVcHaUeRgCiYsIvOaIgDnFuDbRnMoCmPrZfLeFpSjQaTfHgZwZvAzDuSeNwSoWuJvLqKqAuUxFaCxFfRcEjEsJpOfCtDiVrBqNsNwPuGoRgPzRpLpYnNyQxKaNnDnYiJrCrVcHlOxPiPcDbEgKfLwBjLhKcNeMgJhJmOiJvPfOaPaEuGqWvRbErKrIpDkEoQnKwJnTlStLyNsHyOjZfKoIjXwUvRrWpSyYhRpQdLqGmErAiNcGqAqIrTeTiMuPmCrEkHdBrLyCxPtYpRqD"
},
{
"input": "qUdLgGrJeGmIzIeZrCjUtBpYfRvNdXdRpGsThIsEmJjTiMqEwRxBeBaSxEuWrNvExKePjPnXhPzBpWnHiDhTvZhBuIjDnZpTcEkCvRkAcTmMuXhGgErWgFyGyToOyVwYlCuQpTfJkVdWmFyBqQhJjYtXrBbFdHzDlGsFbHmHbFgXgFhIyDhZyEqEiEwNxSeByBwLiVeSnCxIdHbGjOjJrZeVkOzGeMmQrJkVyGhDtCzOlPeAzGrBlWwEnAdUfVaIjNrRyJjCnHkUvFuKuKeKbLzSbEmUcXtVkZzXzKlOrPgQiDmCcCvIyAdBwOeUuLbRmScNcWxIkOkJuIsBxTrIqXhDzLcYdVtPgZdZfAxTmUtByGiTsJkSySjXdJvEwNmSmNoWsChPdAzJrBoW",
"output": "QUdLgGrJeGmIzIeZrCjUtBpYfRvNdXdRpGsThIsEmJjTiMqEwRxBeBaSxEuWrNvExKePjPnXhPzBpWnHiDhTvZhBuIjDnZpTcEkCvRkAcTmMuXhGgErWgFyGyToOyVwYlCuQpTfJkVdWmFyBqQhJjYtXrBbFdHzDlGsFbHmHbFgXgFhIyDhZyEqEiEwNxSeByBwLiVeSnCxIdHbGjOjJrZeVkOzGeMmQrJkVyGhDtCzOlPeAzGrBlWwEnAdUfVaIjNrRyJjCnHkUvFuKuKeKbLzSbEmUcXtVkZzXzKlOrPgQiDmCcCvIyAdBwOeUuLbRmScNcWxIkOkJuIsBxTrIqXhDzLcYdVtPgZdZfAxTmUtByGiTsJkSySjXdJvEwNmSmNoWsChPdAzJrBoW"
},
{
"input": "kHbApGoBcLmIwUlXkVgUmWzYeLoDbGaOkWbIuXoRwMfKuOoMzAoXrBoTvYxGrMbRjDuRxAbGsTnErIiHnHoLeRnTbFiRfDdOkNlWiAcOsChLdLqFqXlDpDoDtPxXqAmSvYgPvOcCpOlWtOjYwFkGkHuCaHwZcFdOfHjBmIxTeSiHkWjXyFcCtOlSuJsZkDxUgPeZkJwMmNpErUlBcGuMlJwKkWnOzFeFiSiPsEvMmQiCsYeHlLuHoMgBjFoZkXlObDkSoQcVyReTmRsFzRhTuIvCeBqVsQdQyTyZjStGrTyDcEcAgTgMiIcVkLbZbGvWeHtXwEqWkXfTcPyHhHjYwIeVxLyVmHmMkUsGiHmNnQuMsXaFyPpVqNrBhOiWmNkBbQuHvQdOjPjKiZcL",
"output": "KHbApGoBcLmIwUlXkVgUmWzYeLoDbGaOkWbIuXoRwMfKuOoMzAoXrBoTvYxGrMbRjDuRxAbGsTnErIiHnHoLeRnTbFiRfDdOkNlWiAcOsChLdLqFqXlDpDoDtPxXqAmSvYgPvOcCpOlWtOjYwFkGkHuCaHwZcFdOfHjBmIxTeSiHkWjXyFcCtOlSuJsZkDxUgPeZkJwMmNpErUlBcGuMlJwKkWnOzFeFiSiPsEvMmQiCsYeHlLuHoMgBjFoZkXlObDkSoQcVyReTmRsFzRhTuIvCeBqVsQdQyTyZjStGrTyDcEcAgTgMiIcVkLbZbGvWeHtXwEqWkXfTcPyHhHjYwIeVxLyVmHmMkUsGiHmNnQuMsXaFyPpVqNrBhOiWmNkBbQuHvQdOjPjKiZcL"
},
{
"input": "aHmRbLgNuWkLxLnWvUbYwTeZeYiOlLhTuOvKfLnVmCiPcMkSgVrYjZiLuRjCiXhAnVzVcTlVeJdBvPdDfFvHkTuIhCdBjEsXbVmGcLrPfNvRdFsZkSdNpYsJeIhIcNqSoLkOjUlYlDmXsOxPbQtIoUxFjGnRtBhFaJvBeEzHsAtVoQbAfYjJqReBiKeUwRqYrUjPjBoHkOkPzDwEwUgTxQxAvKzUpMhKyOhPmEhYhItQwPeKsKaKlUhGuMcTtSwFtXfJsDsFlTtOjVvVfGtBtFlQyIcBaMsPaJlPqUcUvLmReZiFbXxVtRhTzJkLkAjVqTyVuFeKlTyQgUzMsXjOxQnVfTaWmThEnEoIhZeZdStBkKeLpAhJnFoJvQyGwDiStLjEwGfZwBuWsEfC",
"output": "AHmRbLgNuWkLxLnWvUbYwTeZeYiOlLhTuOvKfLnVmCiPcMkSgVrYjZiLuRjCiXhAnVzVcTlVeJdBvPdDfFvHkTuIhCdBjEsXbVmGcLrPfNvRdFsZkSdNpYsJeIhIcNqSoLkOjUlYlDmXsOxPbQtIoUxFjGnRtBhFaJvBeEzHsAtVoQbAfYjJqReBiKeUwRqYrUjPjBoHkOkPzDwEwUgTxQxAvKzUpMhKyOhPmEhYhItQwPeKsKaKlUhGuMcTtSwFtXfJsDsFlTtOjVvVfGtBtFlQyIcBaMsPaJlPqUcUvLmReZiFbXxVtRhTzJkLkAjVqTyVuFeKlTyQgUzMsXjOxQnVfTaWmThEnEoIhZeZdStBkKeLpAhJnFoJvQyGwDiStLjEwGfZwBuWsEfC"
},
{
"input": "sLlZkDiDmEdNaXuUuJwHqYvRtOdGfTiTpEpAoSqAbJaChOiCvHgSwZwEuPkMmXiLcKdXqSsEyViEbZpZsHeZpTuXoGcRmOiQfBfApPjDqSqElWeSeOhUyWjLyNoRuYeGfGwNqUsQoTyVvWeNgNdZfDxGwGfLsDjIdInSqDlMuNvFaHbScZkTlVwNcJpEjMaPaOtFgJjBjOcLlLmDnQrShIrJhOcUmPnZhTxNeClQsZaEaVaReLyQpLwEqJpUwYhLiRzCzKfOoFeTiXzPiNbOsZaZaLgCiNnMkBcFwGgAwPeNyTxJcCtBgXcToKlWaWcBaIvBpNxPeClQlWeQqRyEtAkJdBtSrFdDvAbUlKyLdCuTtXxFvRcKnYnWzVdYqDeCmOqPxUaFjQdTdCtN",
"output": "SLlZkDiDmEdNaXuUuJwHqYvRtOdGfTiTpEpAoSqAbJaChOiCvHgSwZwEuPkMmXiLcKdXqSsEyViEbZpZsHeZpTuXoGcRmOiQfBfApPjDqSqElWeSeOhUyWjLyNoRuYeGfGwNqUsQoTyVvWeNgNdZfDxGwGfLsDjIdInSqDlMuNvFaHbScZkTlVwNcJpEjMaPaOtFgJjBjOcLlLmDnQrShIrJhOcUmPnZhTxNeClQsZaEaVaReLyQpLwEqJpUwYhLiRzCzKfOoFeTiXzPiNbOsZaZaLgCiNnMkBcFwGgAwPeNyTxJcCtBgXcToKlWaWcBaIvBpNxPeClQlWeQqRyEtAkJdBtSrFdDvAbUlKyLdCuTtXxFvRcKnYnWzVdYqDeCmOqPxUaFjQdTdCtN"
},
{
"input": "iRuStKvVhJdJbQwRoIuLiVdTpKaOqKfYlYwAzIpPtUwUtMeKyCaOlXmVrKwWeImYmVuXdLkRlHwFxKqZbZtTzNgOzDbGqTfZnKmUzAcIjDcEmQgYyFbEfWzRpKvCkDmAqDiIiRcLvMxWaJqCgYqXgIcLdNaZlBnXtJyKaMnEaWfXfXwTbDnAiYnWqKbAtDpYdUbZrCzWgRnHzYxFgCdDbOkAgTqBuLqMeStHcDxGnVhSgMzVeTaZoTfLjMxQfRuPcFqVlRyYdHyOdJsDoCeWrUuJyIiAqHwHyVpEeEoMaJwAoUfPtBeJqGhMaHiBjKwAlXoZpUsDhHgMxBkVbLcEvNtJbGnPsUwAvXrAkTlXwYvEnOpNeWyIkRnEnTrIyAcLkRgMyYcKrGiDaAyE",
"output": "IRuStKvVhJdJbQwRoIuLiVdTpKaOqKfYlYwAzIpPtUwUtMeKyCaOlXmVrKwWeImYmVuXdLkRlHwFxKqZbZtTzNgOzDbGqTfZnKmUzAcIjDcEmQgYyFbEfWzRpKvCkDmAqDiIiRcLvMxWaJqCgYqXgIcLdNaZlBnXtJyKaMnEaWfXfXwTbDnAiYnWqKbAtDpYdUbZrCzWgRnHzYxFgCdDbOkAgTqBuLqMeStHcDxGnVhSgMzVeTaZoTfLjMxQfRuPcFqVlRyYdHyOdJsDoCeWrUuJyIiAqHwHyVpEeEoMaJwAoUfPtBeJqGhMaHiBjKwAlXoZpUsDhHgMxBkVbLcEvNtJbGnPsUwAvXrAkTlXwYvEnOpNeWyIkRnEnTrIyAcLkRgMyYcKrGiDaAyE"
},
{
"input": "cRtJkOxHzUbJcDdHzJtLbVmSoWuHoTkVrPqQaVmXeBrHxJbQfNrQbAaMrEhVdQnPxNyCjErKxPoEdWkVrBbDeNmEgBxYiBtWdAfHiLuSwIxJuHpSkAxPoYdNkGoLySsNhUmGoZhDzAfWhJdPlJzQkZbOnMtTkClIoCqOlIcJcMlGjUyOiEmHdYfIcPtTgQhLlLcPqQjAnQnUzHpCaQsCnYgQsBcJrQwBnWsIwFfSfGuYgTzQmShFpKqEeRlRkVfMuZbUsDoFoPrNuNwTtJqFkRiXxPvKyElDzLoUnIwAaBaOiNxMpEvPzSpGpFhMtGhGdJrFnZmNiMcUfMtBnDuUnXqDcMsNyGoLwLeNnLfRsIwRfBtXkHrFcPsLdXaAoYaDzYnZuQeVcZrElWmP",
"output": "CRtJkOxHzUbJcDdHzJtLbVmSoWuHoTkVrPqQaVmXeBrHxJbQfNrQbAaMrEhVdQnPxNyCjErKxPoEdWkVrBbDeNmEgBxYiBtWdAfHiLuSwIxJuHpSkAxPoYdNkGoLySsNhUmGoZhDzAfWhJdPlJzQkZbOnMtTkClIoCqOlIcJcMlGjUyOiEmHdYfIcPtTgQhLlLcPqQjAnQnUzHpCaQsCnYgQsBcJrQwBnWsIwFfSfGuYgTzQmShFpKqEeRlRkVfMuZbUsDoFoPrNuNwTtJqFkRiXxPvKyElDzLoUnIwAaBaOiNxMpEvPzSpGpFhMtGhGdJrFnZmNiMcUfMtBnDuUnXqDcMsNyGoLwLeNnLfRsIwRfBtXkHrFcPsLdXaAoYaDzYnZuQeVcZrElWmP"
},
{
"input": "wVaCsGxZrBbFnTbKsCoYlAvUkIpBaYpYmJkMlPwCaFvUkDxAiJgIqWsFqZlFvTtAnGzEwXbYiBdFfFxRiDoUkLmRfAwOlKeOlKgXdUnVqLkTuXtNdQpBpXtLvZxWoBeNePyHcWmZyRiUkPlRqYiQdGeXwOhHbCqVjDcEvJmBkRwWnMqPjXpUsIyXqGjHsEsDwZiFpIbTkQaUlUeFxMwJzSaHdHnDhLaLdTuYgFuJsEcMmDvXyPjKsSeBaRwNtPuOuBtNeOhQdVgKzPzOdYtPjPfDzQzHoWcYjFbSvRgGdGsCmGnQsErToBkCwGeQaCbBpYkLhHxTbUvRnJpZtXjKrHdRiUmUbSlJyGaLnWsCrJbBnSjFaZrIzIrThCmGhQcMsTtOxCuUcRaEyPaG",
"output": "WVaCsGxZrBbFnTbKsCoYlAvUkIpBaYpYmJkMlPwCaFvUkDxAiJgIqWsFqZlFvTtAnGzEwXbYiBdFfFxRiDoUkLmRfAwOlKeOlKgXdUnVqLkTuXtNdQpBpXtLvZxWoBeNePyHcWmZyRiUkPlRqYiQdGeXwOhHbCqVjDcEvJmBkRwWnMqPjXpUsIyXqGjHsEsDwZiFpIbTkQaUlUeFxMwJzSaHdHnDhLaLdTuYgFuJsEcMmDvXyPjKsSeBaRwNtPuOuBtNeOhQdVgKzPzOdYtPjPfDzQzHoWcYjFbSvRgGdGsCmGnQsErToBkCwGeQaCbBpYkLhHxTbUvRnJpZtXjKrHdRiUmUbSlJyGaLnWsCrJbBnSjFaZrIzIrThCmGhQcMsTtOxCuUcRaEyPaG"
},
{
"input": "kEiLxLmPjGzNoGkJdBlAfXhThYhMsHmZoZbGyCvNiUoLoZdAxUbGyQiEfXvPzZzJrPbEcMpHsMjIkRrVvDvQtHuKmXvGpQtXbPzJpFjJdUgWcPdFxLjLtXgVpEiFhImHnKkGiWnZbJqRjCyEwHsNbYfYfTyBaEuKlCtWnOqHmIgGrFmQiYrBnLiFcGuZxXlMfEuVoCxPkVrQvZoIpEhKsYtXrPxLcSfQqXsWaDgVlOnAzUvAhOhMrJfGtWcOwQfRjPmGhDyAeXrNqBvEiDfCiIvWxPjTwPlXpVsMjVjUnCkXgBuWnZaDyJpWkCfBrWnHxMhJgItHdRqNrQaEeRjAuUwRkUdRhEeGlSqVqGmOjNcUhFfXjCmWzBrGvIuZpRyWkWiLyUwFpYjNmNfV",
"output": "KEiLxLmPjGzNoGkJdBlAfXhThYhMsHmZoZbGyCvNiUoLoZdAxUbGyQiEfXvPzZzJrPbEcMpHsMjIkRrVvDvQtHuKmXvGpQtXbPzJpFjJdUgWcPdFxLjLtXgVpEiFhImHnKkGiWnZbJqRjCyEwHsNbYfYfTyBaEuKlCtWnOqHmIgGrFmQiYrBnLiFcGuZxXlMfEuVoCxPkVrQvZoIpEhKsYtXrPxLcSfQqXsWaDgVlOnAzUvAhOhMrJfGtWcOwQfRjPmGhDyAeXrNqBvEiDfCiIvWxPjTwPlXpVsMjVjUnCkXgBuWnZaDyJpWkCfBrWnHxMhJgItHdRqNrQaEeRjAuUwRkUdRhEeGlSqVqGmOjNcUhFfXjCmWzBrGvIuZpRyWkWiLyUwFpYjNmNfV"
},
{
"input": "eIhDoLmDeReKqXsHcVgFxUqNfScAiQnFrTlCgSuTtXiYvBxKaPaGvUeYfSgHqEaWcHxKpFaSlCxGqAmNeFcIzFcZsBiVoZhUjXaDaIcKoBzYdIlEnKfScRqSkYpPtVsVhXsBwUsUfAqRoCkBxWbHgDiCkRtPvUwVgDjOzObYwNiQwXlGnAqEkHdSqLgUkOdZiWaHqQnOhUnDhIzCiQtVcJlGoRfLuVlFjWqSuMsLgLwOdZvKtWdRuRqDoBoInKqPbJdXpIqLtFlMlDaWgSiKbFpCxOnQeNeQzXeKsBzIjCyPxCmBnYuHzQoYxZgGzSgGtZiTeQmUeWlNzZeKiJbQmEjIiDhPeSyZlNdHpZnIkPdJzSeJpPiXxToKyBjJfPwNzZpWzIzGySqPxLtI",
"output": "EIhDoLmDeReKqXsHcVgFxUqNfScAiQnFrTlCgSuTtXiYvBxKaPaGvUeYfSgHqEaWcHxKpFaSlCxGqAmNeFcIzFcZsBiVoZhUjXaDaIcKoBzYdIlEnKfScRqSkYpPtVsVhXsBwUsUfAqRoCkBxWbHgDiCkRtPvUwVgDjOzObYwNiQwXlGnAqEkHdSqLgUkOdZiWaHqQnOhUnDhIzCiQtVcJlGoRfLuVlFjWqSuMsLgLwOdZvKtWdRuRqDoBoInKqPbJdXpIqLtFlMlDaWgSiKbFpCxOnQeNeQzXeKsBzIjCyPxCmBnYuHzQoYxZgGzSgGtZiTeQmUeWlNzZeKiJbQmEjIiDhPeSyZlNdHpZnIkPdJzSeJpPiXxToKyBjJfPwNzZpWzIzGySqPxLtI"
},
{
"input": "uOoQzIeTwYeKpJtGoUdNiXbPgEwVsZkAnJcArHxIpEnEhZwQhZvAiOuLeMkVqLeDsAyKeYgFxGmRoLaRsZjAeXgNfYhBkHeDrHdPuTuYhKmDlAvYzYxCdYgYfVaYlGeVqTeSfBxQePbQrKsTaIkGzMjFrQlJuYaMxWpQkLdEcDsIiMnHnDtThRvAcKyGwBsHqKdXpJfIeTeZtYjFbMeUoXoXzGrShTwSwBpQlKeDrZdCjRqNtXoTsIzBkWbMsObTtDvYaPhUeLeHqHeMpZmTaCcIqXzAmGnPfNdDaFhOqWqDrWuFiBpRjZrQmAdViOuMbFfRyXyWfHgRkGpPnDrEqQcEmHcKpEvWlBrOtJbUaXbThJaSxCbVoGvTmHvZrHvXpCvLaYbRiHzYuQyX",
"output": "UOoQzIeTwYeKpJtGoUdNiXbPgEwVsZkAnJcArHxIpEnEhZwQhZvAiOuLeMkVqLeDsAyKeYgFxGmRoLaRsZjAeXgNfYhBkHeDrHdPuTuYhKmDlAvYzYxCdYgYfVaYlGeVqTeSfBxQePbQrKsTaIkGzMjFrQlJuYaMxWpQkLdEcDsIiMnHnDtThRvAcKyGwBsHqKdXpJfIeTeZtYjFbMeUoXoXzGrShTwSwBpQlKeDrZdCjRqNtXoTsIzBkWbMsObTtDvYaPhUeLeHqHeMpZmTaCcIqXzAmGnPfNdDaFhOqWqDrWuFiBpRjZrQmAdViOuMbFfRyXyWfHgRkGpPnDrEqQcEmHcKpEvWlBrOtJbUaXbThJaSxCbVoGvTmHvZrHvXpCvLaYbRiHzYuQyX"
},
{
"input": "lZqBqKeGvNdSeYuWxRiVnFtYbKuJwQtUcKnVtQhAlOeUzMaAuTaEnDdPfDcNyHgEoBmYjZyFePeJrRiKyAzFnBfAuGiUyLrIeLrNhBeBdVcEeKgCcBrQzDsPwGcNnZvTsEaYmFfMeOmMdNuZbUtDoQoNcGwDqEkEjIdQaPwAxJbXeNxOgKgXoEbZiIsVkRrNpNyAkLeHkNfEpLuQvEcMbIoGaDzXbEtNsLgGfOkZaFiUsOvEjVeCaMcZqMzKeAdXxJsVeCrZaFpJtZxInQxFaSmGgSsVyGeLlFgFqTpIbAvPkIfJrVcJeBxSdEvPyVwIjHpYrLrKqLnAmCuGmPoZrSbOtGaLaTmBmSuUyAmAsRiMqOtRjJhPhAfXaJnTpLbFqPmJgFcBxImTqIiJ",
"output": "LZqBqKeGvNdSeYuWxRiVnFtYbKuJwQtUcKnVtQhAlOeUzMaAuTaEnDdPfDcNyHgEoBmYjZyFePeJrRiKyAzFnBfAuGiUyLrIeLrNhBeBdVcEeKgCcBrQzDsPwGcNnZvTsEaYmFfMeOmMdNuZbUtDoQoNcGwDqEkEjIdQaPwAxJbXeNxOgKgXoEbZiIsVkRrNpNyAkLeHkNfEpLuQvEcMbIoGaDzXbEtNsLgGfOkZaFiUsOvEjVeCaMcZqMzKeAdXxJsVeCrZaFpJtZxInQxFaSmGgSsVyGeLlFgFqTpIbAvPkIfJrVcJeBxSdEvPyVwIjHpYrLrKqLnAmCuGmPoZrSbOtGaLaTmBmSuUyAmAsRiMqOtRjJhPhAfXaJnTpLbFqPmJgFcBxImTqIiJ"
},
{
"input": "P",
"output": "P"
},
{
"input": "Xyzzy",
"output": "Xyzzy"
},
{
"input": "Zzz",
"output": "Zzz"
},
{
"input": "Zp",
"output": "Zp"
}
] | 1,699,204,614
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 25
| 62
| 0
|
q=input()
print((q[0]).upper()+q[1:])
|
Title: Word Capitalization
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Capitalization is writing a word with its first letter as a capital letter. Your task is to capitalize the given word.
Note, that during capitalization all the letters except the first one remains unchanged.
Input Specification:
A single line contains a non-empty word. This word consists of lowercase and uppercase English letters. The length of the word will not exceed 103.
Output Specification:
Output the given word after capitalization.
Demo Input:
['ApPLe\n', 'konjac\n']
Demo Output:
['ApPLe\n', 'Konjac\n']
Note:
none
|
```python
q=input()
print((q[0]).upper()+q[1:])
```
| 3
|
|
141
|
B
|
Hopscotch
|
PROGRAMMING
| 1,400
|
[
"geometry",
"math"
] | null | null |
So nearly half of the winter is over and Maria is dreaming about summer. She's fed up with skates and sleds, she was dreaming about Hopscotch all night long. It's a very popular children's game. The game field, the court, looks as is shown in the figure (all blocks are square and are numbered from bottom to top, blocks in the same row are numbered from left to right). Let us describe the hopscotch with numbers that denote the number of squares in the row, staring from the lowest one: 1-1-2-1-2-1-2-(1-2)..., where then the period is repeated (1-2).
The coordinate system is defined as shown in the figure. Side of all the squares are equal and have length *a*.
Maria is a very smart and clever girl, and she is concerned with quite serious issues: if she throws a stone into a point with coordinates (*x*,<=*y*), then will she hit some square? If the answer is positive, you are also required to determine the number of the square.
It is believed that the stone has fallen into the square if it is located strictly inside it. In other words a stone that has fallen on the square border is not considered a to hit a square.
|
The only input line contains three integers: *a*, *x*, *y*, where *a* (1<=≤<=*a*<=≤<=100) is the side of the square, *x* and *y* (<=-<=106<=≤<=*x*<=≤<=106,<=0<=≤<=*y*<=≤<=106) are coordinates of the stone.
|
Print the number of the square, inside which the stone fell. If the stone is on a border of some stone or outside the court, print "-1" without the quotes.
|
[
"1 0 0\n",
"3 1 1\n",
"3 0 10\n",
"3 0 7\n",
"3 4 0\n"
] |
[
"-1\n",
"1\n",
"5\n",
"-1\n",
"-1\n"
] |
none
| 1,000
|
[
{
"input": "1 0 0",
"output": "-1"
},
{
"input": "3 1 1",
"output": "1"
},
{
"input": "3 0 10",
"output": "5"
},
{
"input": "3 0 7",
"output": "-1"
},
{
"input": "3 4 0",
"output": "-1"
},
{
"input": "9 3 2",
"output": "1"
},
{
"input": "100 0 953748",
"output": "14306"
},
{
"input": "17 0 1000000",
"output": "88235"
},
{
"input": "17 15 99999",
"output": "8824"
},
{
"input": "55 -20 1000000",
"output": "27272"
},
{
"input": "1 154871 37516",
"output": "-1"
},
{
"input": "1 -1 0",
"output": "-1"
},
{
"input": "1 -1 1",
"output": "-1"
},
{
"input": "1 0 2",
"output": "-1"
},
{
"input": "1 0 552012",
"output": "-1"
},
{
"input": "1 1 293372",
"output": "-1"
},
{
"input": "1 -1 551084",
"output": "-1"
},
{
"input": "5 -744240 145890",
"output": "-1"
},
{
"input": "5 -4 2",
"output": "-1"
},
{
"input": "5 -5 7",
"output": "-1"
},
{
"input": "5 -3 14",
"output": "3"
},
{
"input": "5 0 660386",
"output": "198116"
},
{
"input": "5 5 918098",
"output": "-1"
},
{
"input": "5 -5 659458",
"output": "-1"
},
{
"input": "10 -227776 821899",
"output": "-1"
},
{
"input": "10 -5 1",
"output": "-1"
},
{
"input": "10 -3 11",
"output": "2"
},
{
"input": "10 -2 23",
"output": "3"
},
{
"input": "10 0 336395",
"output": "50459"
},
{
"input": "10 10 77755",
"output": "-1"
},
{
"input": "10 -10 335467",
"output": "-1"
},
{
"input": "100 350728 439252",
"output": "-1"
},
{
"input": "100 9 64",
"output": "1"
},
{
"input": "100 -9 176",
"output": "2"
},
{
"input": "100 -28 236",
"output": "3"
},
{
"input": "100 100 211460",
"output": "-1"
},
{
"input": "100 -100 952820",
"output": "-1"
},
{
"input": "7 -3 0",
"output": "-1"
},
{
"input": "8 4 3",
"output": "-1"
},
{
"input": "17 0 99999",
"output": "-1"
},
{
"input": "17 -2 99999",
"output": "8823"
},
{
"input": "55 -55 1000000",
"output": "-1"
},
{
"input": "92 19 920000",
"output": "-1"
},
{
"input": "58 50 195112",
"output": "-1"
},
{
"input": "2 -3 0",
"output": "-1"
},
{
"input": "2 -3 1",
"output": "-1"
},
{
"input": "2 -3 2",
"output": "-1"
},
{
"input": "2 -3 3",
"output": "-1"
},
{
"input": "2 -3 4",
"output": "-1"
},
{
"input": "2 -3 5",
"output": "-1"
},
{
"input": "2 -3 6",
"output": "-1"
},
{
"input": "2 -3 7",
"output": "-1"
},
{
"input": "2 -2 0",
"output": "-1"
},
{
"input": "2 -2 1",
"output": "-1"
},
{
"input": "2 -2 2",
"output": "-1"
},
{
"input": "2 -2 3",
"output": "-1"
},
{
"input": "2 -2 4",
"output": "-1"
},
{
"input": "2 -2 5",
"output": "-1"
},
{
"input": "2 -2 6",
"output": "-1"
},
{
"input": "2 -2 7",
"output": "-1"
},
{
"input": "2 -1 0",
"output": "-1"
},
{
"input": "2 -1 1",
"output": "-1"
},
{
"input": "2 -1 2",
"output": "-1"
},
{
"input": "2 -1 3",
"output": "-1"
},
{
"input": "2 -1 4",
"output": "-1"
},
{
"input": "2 -1 5",
"output": "3"
},
{
"input": "2 -1 6",
"output": "-1"
},
{
"input": "2 -1 7",
"output": "-1"
},
{
"input": "2 0 0",
"output": "-1"
},
{
"input": "2 0 1",
"output": "1"
},
{
"input": "2 0 2",
"output": "-1"
},
{
"input": "2 0 3",
"output": "2"
},
{
"input": "2 0 4",
"output": "-1"
},
{
"input": "2 0 5",
"output": "-1"
},
{
"input": "2 0 6",
"output": "-1"
},
{
"input": "2 0 7",
"output": "5"
},
{
"input": "2 1 0",
"output": "-1"
},
{
"input": "2 1 1",
"output": "-1"
},
{
"input": "2 1 2",
"output": "-1"
},
{
"input": "2 1 3",
"output": "-1"
},
{
"input": "2 1 4",
"output": "-1"
},
{
"input": "2 1 5",
"output": "4"
},
{
"input": "2 1 6",
"output": "-1"
},
{
"input": "2 1 7",
"output": "-1"
},
{
"input": "2 2 0",
"output": "-1"
},
{
"input": "2 2 1",
"output": "-1"
},
{
"input": "2 2 2",
"output": "-1"
},
{
"input": "2 2 3",
"output": "-1"
},
{
"input": "2 2 4",
"output": "-1"
},
{
"input": "2 2 5",
"output": "-1"
},
{
"input": "2 2 6",
"output": "-1"
},
{
"input": "2 2 7",
"output": "-1"
},
{
"input": "2 3 0",
"output": "-1"
},
{
"input": "2 3 1",
"output": "-1"
},
{
"input": "2 3 2",
"output": "-1"
},
{
"input": "2 3 3",
"output": "-1"
},
{
"input": "2 3 4",
"output": "-1"
},
{
"input": "2 3 5",
"output": "-1"
},
{
"input": "2 3 6",
"output": "-1"
},
{
"input": "2 3 7",
"output": "-1"
},
{
"input": "4 2 1",
"output": "-1"
},
{
"input": "10 1 60",
"output": "-1"
},
{
"input": "3 1 9",
"output": "-1"
},
{
"input": "3 -1 7",
"output": "3"
},
{
"input": "100 50 1",
"output": "-1"
},
{
"input": "4 2 15",
"output": "-1"
},
{
"input": "2 1 1",
"output": "-1"
},
{
"input": "3 10 8",
"output": "-1"
},
{
"input": "2 -1 1",
"output": "-1"
},
{
"input": "10 11 21",
"output": "-1"
},
{
"input": "3 -2 7",
"output": "3"
},
{
"input": "50 -1 10",
"output": "1"
},
{
"input": "3 4 100",
"output": "-1"
},
{
"input": "49 28 27",
"output": "-1"
},
{
"input": "10 9 5",
"output": "-1"
},
{
"input": "10 5 35",
"output": "-1"
},
{
"input": "4 2 3",
"output": "-1"
},
{
"input": "4 -2 1",
"output": "-1"
},
{
"input": "2 -10 1",
"output": "-1"
},
{
"input": "10 7 1",
"output": "-1"
},
{
"input": "10 5 15",
"output": "-1"
},
{
"input": "3 10 2",
"output": "-1"
},
{
"input": "2 1 5",
"output": "4"
},
{
"input": "3 10 100",
"output": "-1"
},
{
"input": "10 5 25",
"output": "4"
},
{
"input": "50 1 200",
"output": "-1"
},
{
"input": "10 6 5",
"output": "-1"
},
{
"input": "2 100 3",
"output": "-1"
},
{
"input": "2 1 3",
"output": "-1"
},
{
"input": "3 6 7",
"output": "-1"
},
{
"input": "3 100 1",
"output": "-1"
},
{
"input": "2 2 5",
"output": "-1"
},
{
"input": "100 50 50",
"output": "-1"
},
{
"input": "2 0 1",
"output": "1"
},
{
"input": "5 1 35",
"output": "-1"
},
{
"input": "100 25 200",
"output": "-1"
},
{
"input": "5 -1 6",
"output": "2"
},
{
"input": "5 2 6",
"output": "2"
},
{
"input": "6 3 1",
"output": "-1"
},
{
"input": "3 0 3",
"output": "-1"
},
{
"input": "2 100 1",
"output": "-1"
},
{
"input": "50 0 20",
"output": "1"
},
{
"input": "10 5 95",
"output": "-1"
},
{
"input": "1 0 1",
"output": "-1"
},
{
"input": "15 8 1546",
"output": "-1"
},
{
"input": "10 5 31",
"output": "-1"
},
{
"input": "1 0 3",
"output": "-1"
},
{
"input": "100 80 50",
"output": "-1"
}
] | 1,684,290,604
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 148
| 248
| 8,908,800
|
import sys
from typing import Callable
def get_quadrant_num(height, is_double, x) -> int:
if height < 3:
return height
height -= 2
# Calc number of row below
height_row_below = height - 1
r = 2 + 2 * (height_row_below // 2) + height_row_below // 2 + (2 if height_row_below % 2 != 0 else 0)
if is_double and x < 0:
return (r + 1)
elif is_double and x > 0:
return (r + 2)
else:
return (r + 1)
def main() -> None:
read: Callable[[], str] = sys.stdin.readline
a, x, y = (int(i) for i in read().split())
# Get the quadrant
if y % a == 0:
print(-1)
else:
is_double = False
quadrant = y // a + 1
if quadrant < 2:
width = a / 2
elif quadrant >= 3 and quadrant % 2 != 0:
width = a
is_double = True
else:
width = a / 2
if abs(x) >= width:
print(-1)
elif width == a and x == 0:
print(-1)
else:
print(get_quadrant_num(quadrant, is_double, x))
if __name__ == '__main__':
main()
|
Title: Hopscotch
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
So nearly half of the winter is over and Maria is dreaming about summer. She's fed up with skates and sleds, she was dreaming about Hopscotch all night long. It's a very popular children's game. The game field, the court, looks as is shown in the figure (all blocks are square and are numbered from bottom to top, blocks in the same row are numbered from left to right). Let us describe the hopscotch with numbers that denote the number of squares in the row, staring from the lowest one: 1-1-2-1-2-1-2-(1-2)..., where then the period is repeated (1-2).
The coordinate system is defined as shown in the figure. Side of all the squares are equal and have length *a*.
Maria is a very smart and clever girl, and she is concerned with quite serious issues: if she throws a stone into a point with coordinates (*x*,<=*y*), then will she hit some square? If the answer is positive, you are also required to determine the number of the square.
It is believed that the stone has fallen into the square if it is located strictly inside it. In other words a stone that has fallen on the square border is not considered a to hit a square.
Input Specification:
The only input line contains three integers: *a*, *x*, *y*, where *a* (1<=≤<=*a*<=≤<=100) is the side of the square, *x* and *y* (<=-<=106<=≤<=*x*<=≤<=106,<=0<=≤<=*y*<=≤<=106) are coordinates of the stone.
Output Specification:
Print the number of the square, inside which the stone fell. If the stone is on a border of some stone or outside the court, print "-1" without the quotes.
Demo Input:
['1 0 0\n', '3 1 1\n', '3 0 10\n', '3 0 7\n', '3 4 0\n']
Demo Output:
['-1\n', '1\n', '5\n', '-1\n', '-1\n']
Note:
none
|
```python
import sys
from typing import Callable
def get_quadrant_num(height, is_double, x) -> int:
if height < 3:
return height
height -= 2
# Calc number of row below
height_row_below = height - 1
r = 2 + 2 * (height_row_below // 2) + height_row_below // 2 + (2 if height_row_below % 2 != 0 else 0)
if is_double and x < 0:
return (r + 1)
elif is_double and x > 0:
return (r + 2)
else:
return (r + 1)
def main() -> None:
read: Callable[[], str] = sys.stdin.readline
a, x, y = (int(i) for i in read().split())
# Get the quadrant
if y % a == 0:
print(-1)
else:
is_double = False
quadrant = y // a + 1
if quadrant < 2:
width = a / 2
elif quadrant >= 3 and quadrant % 2 != 0:
width = a
is_double = True
else:
width = a / 2
if abs(x) >= width:
print(-1)
elif width == a and x == 0:
print(-1)
else:
print(get_quadrant_num(quadrant, is_double, x))
if __name__ == '__main__':
main()
```
| 3
|
|
1
|
A
|
Theatre Square
|
PROGRAMMING
| 1,000
|
[
"math"
] |
A. Theatre Square
|
1
|
256
|
Theatre Square in the capital city of Berland has a rectangular shape with the size *n*<=×<=*m* meters. On the occasion of the city's anniversary, a decision was taken to pave the Square with square granite flagstones. Each flagstone is of the size *a*<=×<=*a*.
What is the least number of flagstones needed to pave the Square? It's allowed to cover the surface larger than the Theatre Square, but the Square has to be covered. It's not allowed to break the flagstones. The sides of flagstones should be parallel to the sides of the Square.
|
The input contains three positive integer numbers in the first line: *n*,<=<=*m* and *a* (1<=≤<=<=*n*,<=*m*,<=*a*<=≤<=109).
|
Write the needed number of flagstones.
|
[
"6 6 4\n"
] |
[
"4\n"
] |
none
| 0
|
[
{
"input": "6 6 4",
"output": "4"
},
{
"input": "1 1 1",
"output": "1"
},
{
"input": "2 1 1",
"output": "2"
},
{
"input": "1 2 1",
"output": "2"
},
{
"input": "2 2 1",
"output": "4"
},
{
"input": "2 1 2",
"output": "1"
},
{
"input": "1 1 3",
"output": "1"
},
{
"input": "2 3 4",
"output": "1"
},
{
"input": "1000000000 1000000000 1",
"output": "1000000000000000000"
},
{
"input": "12 13 4",
"output": "12"
},
{
"input": "222 332 5",
"output": "3015"
},
{
"input": "1000 1000 10",
"output": "10000"
},
{
"input": "1001 1000 10",
"output": "10100"
},
{
"input": "100 10001 1000000000",
"output": "1"
},
{
"input": "1000000000 1000000000 1000000000",
"output": "1"
},
{
"input": "1000000000 1000000000 999999999",
"output": "4"
},
{
"input": "1000000000 1000000000 192",
"output": "27126743055556"
},
{
"input": "1000000000 987654321 1",
"output": "987654321000000000"
},
{
"input": "456784567 1000000000 51",
"output": "175618850864484"
},
{
"input": "39916800 134217728 40320",
"output": "3295710"
}
] | 1,657,095,613
| 2,147,483,647
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 0
| 46
| 0
|
f1 = ceil(n/a)
f2 = ceil(m/a)
print(f1 * f2)
|
Title: Theatre Square
Time Limit: 1 seconds
Memory Limit: 256 megabytes
Problem Description:
Theatre Square in the capital city of Berland has a rectangular shape with the size *n*<=×<=*m* meters. On the occasion of the city's anniversary, a decision was taken to pave the Square with square granite flagstones. Each flagstone is of the size *a*<=×<=*a*.
What is the least number of flagstones needed to pave the Square? It's allowed to cover the surface larger than the Theatre Square, but the Square has to be covered. It's not allowed to break the flagstones. The sides of flagstones should be parallel to the sides of the Square.
Input Specification:
The input contains three positive integer numbers in the first line: *n*,<=<=*m* and *a* (1<=≤<=<=*n*,<=*m*,<=*a*<=≤<=109).
Output Specification:
Write the needed number of flagstones.
Demo Input:
['6 6 4\n']
Demo Output:
['4\n']
Note:
none
|
```python
f1 = ceil(n/a)
f2 = ceil(m/a)
print(f1 * f2)
```
| -1
|
182
|
B
|
Vasya's Calendar
|
PROGRAMMING
| 1,000
|
[
"implementation"
] | null | null |
Vasya lives in a strange world. The year has *n* months and the *i*-th month has *a**i* days. Vasya got a New Year present — the clock that shows not only the time, but also the date.
The clock's face can display any number from 1 to *d*. It is guaranteed that *a**i*<=≤<=*d* for all *i* from 1 to *n*. The clock does not keep information about the current month, so when a new day comes, it simply increases the current day number by one. The clock cannot display number *d*<=+<=1, so after day number *d* it shows day 1 (the current day counter resets). The mechanism of the clock allows you to increase the day number by one manually. When you execute this operation, day *d* is also followed by day 1.
Vasya begins each day checking the day number on the clock. If the day number on the clock does not match the actual day number in the current month, then Vasya manually increases it by one. Vasya is persistent and repeats this operation until the day number on the clock matches the actual number of the current day in the current month.
A year passed and Vasya wonders how many times he manually increased the day number by one, from the first day of the first month to the last day of the *n*-th month inclusive, considering that on the first day of the first month the clock display showed day 1.
|
The first line contains the single number *d* — the maximum number of the day that Vasya's clock can show (1<=≤<=*d*<=≤<=106).
The second line contains a single integer *n* — the number of months in the year (1<=≤<=*n*<=≤<=2000).
The third line contains *n* space-separated integers: *a**i* (1<=≤<=*a**i*<=≤<=*d*) — the number of days in each month in the order in which they follow, starting from the first one.
|
Print a single number — the number of times Vasya manually increased the day number by one throughout the last year.
|
[
"4\n2\n2 2\n",
"5\n3\n3 4 3\n",
"31\n12\n31 28 31 30 31 30 31 31 30 31 30 31\n"
] |
[
"2\n",
"3\n",
"7\n"
] |
In the first sample the situation is like this:
- Day 1. Month 1. The clock shows 1. Vasya changes nothing. - Day 2. Month 1. The clock shows 2. Vasya changes nothing. - Day 1. Month 2. The clock shows 3. Vasya manually increases the day number by 1. After that the clock shows 4. Vasya increases the day number by 1 manually. After that the clock shows 1. - Day 2. Month 2. The clock shows 2. Vasya changes nothing.
| 500
|
[
{
"input": "4\n2\n2 2",
"output": "2"
},
{
"input": "5\n3\n3 4 3",
"output": "3"
},
{
"input": "31\n12\n31 28 31 30 31 30 31 31 30 31 30 31",
"output": "7"
},
{
"input": "1\n1\n1",
"output": "0"
},
{
"input": "1\n2\n1 1",
"output": "0"
},
{
"input": "2\n2\n1 1",
"output": "1"
},
{
"input": "10\n2\n10 2",
"output": "0"
},
{
"input": "10\n3\n6 3 6",
"output": "11"
},
{
"input": "10\n4\n8 7 1 5",
"output": "14"
},
{
"input": "10\n5\n2 7 8 4 4",
"output": "19"
},
{
"input": "10\n6\n8 3 4 9 6 1",
"output": "20"
},
{
"input": "10\n7\n10 5 3 1 1 9 1",
"output": "31"
},
{
"input": "10\n8\n6 5 10 6 8 1 3 2",
"output": "31"
},
{
"input": "10\n9\n6 2 7 5 5 4 8 6 2",
"output": "37"
},
{
"input": "10\n10\n1 10 1 10 1 1 7 8 6 7",
"output": "45"
},
{
"input": "100\n100\n85 50 17 89 65 89 5 20 86 26 16 21 85 14 44 31 87 31 6 2 48 67 8 80 79 1 48 36 97 1 5 30 79 50 78 12 2 55 76 100 54 40 26 81 97 96 68 56 87 14 51 17 54 37 52 33 69 62 38 63 74 15 62 78 9 19 67 2 60 58 93 60 18 96 55 48 34 7 79 82 32 58 90 67 20 50 27 15 7 89 98 10 11 15 99 49 4 51 77 52",
"output": "5099"
},
{
"input": "101\n100\n19 17 15 16 28 69 41 47 75 42 19 98 16 90 92 47 21 4 98 17 27 31 90 10 14 92 62 73 56 55 6 60 62 22 78 1 3 86 18 59 92 41 21 34 67 9 92 78 77 45 50 92 57 61 11 98 89 72 57 93 100 12 61 48 5 48 38 9 65 64 77 29 18 55 94 42 10 77 43 46 7 89 8 13 5 53 80 59 23 100 30 28 29 24 85 56 10 22 24 16",
"output": "5301"
},
{
"input": "102\n100\n31 22 59 16 11 56 81 4 19 31 8 72 4 92 18 7 13 12 62 40 34 67 40 23 96 4 90 28 3 18 54 49 10 71 73 79 69 7 41 75 59 13 2 78 72 6 95 33 52 97 7 86 57 94 12 93 19 94 59 28 5 96 46 102 2 101 57 85 53 69 72 39 14 75 8 16 10 57 26 4 85 18 89 84 48 93 54 21 78 6 67 35 11 78 91 91 97 15 8 32",
"output": "5447"
},
{
"input": "103\n100\n68 38 41 54 37 11 35 26 43 97 70 3 13 11 64 83 3 95 99 16 4 13 22 27 64 20 95 38 40 87 6 17 95 67 31 24 85 33 98 24 89 101 66 38 42 5 95 18 95 13 103 85 72 73 68 93 22 59 48 59 72 46 5 41 54 32 48 69 3 76 2 26 102 44 39 58 55 85 40 16 81 78 92 63 25 97 83 2 54 16 20 63 19 8 84 34 1 22 43 93",
"output": "5358"
},
{
"input": "104\n100\n65 74 94 71 98 38 88 67 71 84 45 79 55 86 55 51 27 89 14 66 29 63 8 103 98 94 87 81 58 68 24 96 60 36 48 95 28 72 95 42 87 7 14 23 99 77 34 14 90 31 8 99 29 30 9 88 42 1 77 61 55 85 17 98 62 78 27 1 58 69 82 62 62 81 56 104 66 8 17 23 7 61 59 70 79 64 78 16 32 11 59 4 24 73 55 2 95 39 62 13",
"output": "4773"
}
] | 1,653,607,130
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 40
| 124
| 2,150,400
|
d = int(input())
n = int(input())
arr = [int(e) for e in input().split()]
t = 0
for i in arr[:-1]:
t += d - i
print(t)
|
Title: Vasya's Calendar
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya lives in a strange world. The year has *n* months and the *i*-th month has *a**i* days. Vasya got a New Year present — the clock that shows not only the time, but also the date.
The clock's face can display any number from 1 to *d*. It is guaranteed that *a**i*<=≤<=*d* for all *i* from 1 to *n*. The clock does not keep information about the current month, so when a new day comes, it simply increases the current day number by one. The clock cannot display number *d*<=+<=1, so after day number *d* it shows day 1 (the current day counter resets). The mechanism of the clock allows you to increase the day number by one manually. When you execute this operation, day *d* is also followed by day 1.
Vasya begins each day checking the day number on the clock. If the day number on the clock does not match the actual day number in the current month, then Vasya manually increases it by one. Vasya is persistent and repeats this operation until the day number on the clock matches the actual number of the current day in the current month.
A year passed and Vasya wonders how many times he manually increased the day number by one, from the first day of the first month to the last day of the *n*-th month inclusive, considering that on the first day of the first month the clock display showed day 1.
Input Specification:
The first line contains the single number *d* — the maximum number of the day that Vasya's clock can show (1<=≤<=*d*<=≤<=106).
The second line contains a single integer *n* — the number of months in the year (1<=≤<=*n*<=≤<=2000).
The third line contains *n* space-separated integers: *a**i* (1<=≤<=*a**i*<=≤<=*d*) — the number of days in each month in the order in which they follow, starting from the first one.
Output Specification:
Print a single number — the number of times Vasya manually increased the day number by one throughout the last year.
Demo Input:
['4\n2\n2 2\n', '5\n3\n3 4 3\n', '31\n12\n31 28 31 30 31 30 31 31 30 31 30 31\n']
Demo Output:
['2\n', '3\n', '7\n']
Note:
In the first sample the situation is like this:
- Day 1. Month 1. The clock shows 1. Vasya changes nothing. - Day 2. Month 1. The clock shows 2. Vasya changes nothing. - Day 1. Month 2. The clock shows 3. Vasya manually increases the day number by 1. After that the clock shows 4. Vasya increases the day number by 1 manually. After that the clock shows 1. - Day 2. Month 2. The clock shows 2. Vasya changes nothing.
|
```python
d = int(input())
n = int(input())
arr = [int(e) for e in input().split()]
t = 0
for i in arr[:-1]:
t += d - i
print(t)
```
| 3
|
|
931
|
A
|
Friends Meeting
|
PROGRAMMING
| 800
|
[
"brute force",
"greedy",
"implementation",
"math"
] | null | null |
Two friends are on the coordinate axis *Ox* in points with integer coordinates. One of them is in the point *x*1<==<=*a*, another one is in the point *x*2<==<=*b*.
Each of the friends can move by one along the line in any direction unlimited number of times. When a friend moves, the tiredness of a friend changes according to the following rules: the first move increases the tiredness by 1, the second move increases the tiredness by 2, the third — by 3 and so on. For example, if a friend moves first to the left, then to the right (returning to the same point), and then again to the left his tiredness becomes equal to 1<=+<=2<=+<=3<==<=6.
The friends want to meet in a integer point. Determine the minimum total tiredness they should gain, if they meet in the same point.
|
The first line contains a single integer *a* (1<=≤<=*a*<=≤<=1000) — the initial position of the first friend.
The second line contains a single integer *b* (1<=≤<=*b*<=≤<=1000) — the initial position of the second friend.
It is guaranteed that *a*<=≠<=*b*.
|
Print the minimum possible total tiredness if the friends meet in the same point.
|
[
"3\n4\n",
"101\n99\n",
"5\n10\n"
] |
[
"1\n",
"2\n",
"9\n"
] |
In the first example the first friend should move by one to the right (then the meeting happens at point 4), or the second friend should move by one to the left (then the meeting happens at point 3). In both cases, the total tiredness becomes 1.
In the second example the first friend should move by one to the left, and the second friend should move by one to the right. Then they meet in the point 100, and the total tiredness becomes 1 + 1 = 2.
In the third example one of the optimal ways is the following. The first friend should move three times to the right, and the second friend — two times to the left. Thus the friends meet in the point 8, and the total tiredness becomes 1 + 2 + 3 + 1 + 2 = 9.
| 500
|
[
{
"input": "3\n4",
"output": "1"
},
{
"input": "101\n99",
"output": "2"
},
{
"input": "5\n10",
"output": "9"
},
{
"input": "1\n2",
"output": "1"
},
{
"input": "1\n1000",
"output": "250000"
},
{
"input": "999\n1000",
"output": "1"
},
{
"input": "1000\n999",
"output": "1"
},
{
"input": "1000\n1",
"output": "250000"
},
{
"input": "2\n1",
"output": "1"
},
{
"input": "2\n999",
"output": "249001"
},
{
"input": "2\n998",
"output": "248502"
},
{
"input": "999\n2",
"output": "249001"
},
{
"input": "998\n2",
"output": "248502"
},
{
"input": "2\n1000",
"output": "249500"
},
{
"input": "1000\n2",
"output": "249500"
},
{
"input": "1\n999",
"output": "249500"
},
{
"input": "999\n1",
"output": "249500"
},
{
"input": "188\n762",
"output": "82656"
},
{
"input": "596\n777",
"output": "8281"
},
{
"input": "773\n70",
"output": "123904"
},
{
"input": "825\n729",
"output": "2352"
},
{
"input": "944\n348",
"output": "89102"
},
{
"input": "352\n445",
"output": "2209"
},
{
"input": "529\n656",
"output": "4096"
},
{
"input": "19\n315",
"output": "22052"
},
{
"input": "138\n370",
"output": "13572"
},
{
"input": "546\n593",
"output": "576"
},
{
"input": "285\n242",
"output": "484"
},
{
"input": "773\n901",
"output": "4160"
},
{
"input": "892\n520",
"output": "34782"
},
{
"input": "864\n179",
"output": "117649"
},
{
"input": "479\n470",
"output": "25"
},
{
"input": "967\n487",
"output": "57840"
},
{
"input": "648\n106",
"output": "73712"
},
{
"input": "58\n765",
"output": "125316"
},
{
"input": "235\n56",
"output": "8100"
},
{
"input": "285\n153",
"output": "4422"
},
{
"input": "943\n13",
"output": "216690"
},
{
"input": "675\n541",
"output": "4556"
},
{
"input": "4\n912",
"output": "206570"
}
] | 1,587,395,675
| 2,147,483,647
|
PyPy 3
|
OK
|
TESTS
| 40
| 140
| 0
|
def get_natural_sum(n):
return n * (n+1) // 2
a = int(input())
b = int(input())
n1, n2 = max(a, b), min(a, b)
dist_a = (n1 - n2) // 2
dist_b = (n1 - n2) - dist_a
print(get_natural_sum(dist_a) + get_natural_sum(dist_b))
|
Title: Friends Meeting
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Two friends are on the coordinate axis *Ox* in points with integer coordinates. One of them is in the point *x*1<==<=*a*, another one is in the point *x*2<==<=*b*.
Each of the friends can move by one along the line in any direction unlimited number of times. When a friend moves, the tiredness of a friend changes according to the following rules: the first move increases the tiredness by 1, the second move increases the tiredness by 2, the third — by 3 and so on. For example, if a friend moves first to the left, then to the right (returning to the same point), and then again to the left his tiredness becomes equal to 1<=+<=2<=+<=3<==<=6.
The friends want to meet in a integer point. Determine the minimum total tiredness they should gain, if they meet in the same point.
Input Specification:
The first line contains a single integer *a* (1<=≤<=*a*<=≤<=1000) — the initial position of the first friend.
The second line contains a single integer *b* (1<=≤<=*b*<=≤<=1000) — the initial position of the second friend.
It is guaranteed that *a*<=≠<=*b*.
Output Specification:
Print the minimum possible total tiredness if the friends meet in the same point.
Demo Input:
['3\n4\n', '101\n99\n', '5\n10\n']
Demo Output:
['1\n', '2\n', '9\n']
Note:
In the first example the first friend should move by one to the right (then the meeting happens at point 4), or the second friend should move by one to the left (then the meeting happens at point 3). In both cases, the total tiredness becomes 1.
In the second example the first friend should move by one to the left, and the second friend should move by one to the right. Then they meet in the point 100, and the total tiredness becomes 1 + 1 = 2.
In the third example one of the optimal ways is the following. The first friend should move three times to the right, and the second friend — two times to the left. Thus the friends meet in the point 8, and the total tiredness becomes 1 + 2 + 3 + 1 + 2 = 9.
|
```python
def get_natural_sum(n):
return n * (n+1) // 2
a = int(input())
b = int(input())
n1, n2 = max(a, b), min(a, b)
dist_a = (n1 - n2) // 2
dist_b = (n1 - n2) - dist_a
print(get_natural_sum(dist_a) + get_natural_sum(dist_b))
```
| 3
|
|
80
|
A
|
Panoramix's Prediction
|
PROGRAMMING
| 800
|
[
"brute force"
] |
A. Panoramix's Prediction
|
2
|
256
|
A prime number is a number which has exactly two distinct divisors: one and itself. For example, numbers 2, 7, 3 are prime, and 1, 6, 4 are not.
The next prime number after *x* is the smallest prime number greater than *x*. For example, the next prime number after 2 is 3, and the next prime number after 3 is 5. Note that there is exactly one next prime number after each number. So 5 is not the next prime number for 2.
One cold April morning Panoramix predicted that soon Kakofonix will break free from his straitjacket, and this will be a black day for the residents of the Gallic countryside.
Panoramix's prophecy tells that if some day Asterix and Obelix beat exactly *x* Roman soldiers, where *x* is a prime number, and next day they beat exactly *y* Roman soldiers, where *y* is the next prime number after *x*, then it's time to wait for Armageddon, for nothing can shut Kakofonix up while he sings his infernal song.
Yesterday the Gauls beat *n* Roman soldiers and it turned out that the number *n* was prime! Today their victims were a troop of *m* Romans (*m*<=><=*n*). Determine whether the Gauls should wait for the black day after today's victory of Asterix and Obelix?
|
The first and only input line contains two positive integers — *n* and *m* (2<=≤<=*n*<=<<=*m*<=≤<=50). It is guaranteed that *n* is prime.
Pretests contain all the cases with restrictions 2<=≤<=*n*<=<<=*m*<=≤<=4.
|
Print YES, if *m* is the next prime number after *n*, or NO otherwise.
|
[
"3 5\n",
"7 11\n",
"7 9\n"
] |
[
"YES",
"YES",
"NO"
] |
none
| 500
|
[
{
"input": "3 5",
"output": "YES"
},
{
"input": "7 11",
"output": "YES"
},
{
"input": "7 9",
"output": "NO"
},
{
"input": "2 3",
"output": "YES"
},
{
"input": "2 4",
"output": "NO"
},
{
"input": "3 4",
"output": "NO"
},
{
"input": "3 5",
"output": "YES"
},
{
"input": "5 7",
"output": "YES"
},
{
"input": "7 11",
"output": "YES"
},
{
"input": "11 13",
"output": "YES"
},
{
"input": "13 17",
"output": "YES"
},
{
"input": "17 19",
"output": "YES"
},
{
"input": "19 23",
"output": "YES"
},
{
"input": "23 29",
"output": "YES"
},
{
"input": "29 31",
"output": "YES"
},
{
"input": "31 37",
"output": "YES"
},
{
"input": "37 41",
"output": "YES"
},
{
"input": "41 43",
"output": "YES"
},
{
"input": "43 47",
"output": "YES"
},
{
"input": "2 5",
"output": "NO"
},
{
"input": "2 7",
"output": "NO"
},
{
"input": "2 6",
"output": "NO"
},
{
"input": "2 11",
"output": "NO"
},
{
"input": "3 6",
"output": "NO"
},
{
"input": "3 7",
"output": "NO"
},
{
"input": "3 9",
"output": "NO"
},
{
"input": "5 6",
"output": "NO"
},
{
"input": "5 9",
"output": "NO"
},
{
"input": "5 11",
"output": "NO"
},
{
"input": "5 13",
"output": "NO"
},
{
"input": "5 15",
"output": "NO"
},
{
"input": "7 8",
"output": "NO"
},
{
"input": "7 13",
"output": "NO"
},
{
"input": "13 15",
"output": "NO"
},
{
"input": "13 17",
"output": "YES"
},
{
"input": "19 21",
"output": "NO"
},
{
"input": "13 20",
"output": "NO"
},
{
"input": "41 49",
"output": "NO"
},
{
"input": "43 49",
"output": "NO"
},
{
"input": "47 50",
"output": "NO"
},
{
"input": "47 49",
"output": "NO"
},
{
"input": "47 48",
"output": "NO"
},
{
"input": "23 25",
"output": "NO"
},
{
"input": "2 50",
"output": "NO"
},
{
"input": "31 33",
"output": "NO"
}
] | 1,595,951,672
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 45
| 216
| 6,656,000
|
n,m=tuple(map(int,input().split()))
def check_prime(n):
for i in range(2,n//2+1):
if n%i==0:
return False
return True
x=n+1
while True:
if check_prime(x):
break
x+=1
if m==x:
print("YES")
else:
print("NO")
|
Title: Panoramix's Prediction
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
A prime number is a number which has exactly two distinct divisors: one and itself. For example, numbers 2, 7, 3 are prime, and 1, 6, 4 are not.
The next prime number after *x* is the smallest prime number greater than *x*. For example, the next prime number after 2 is 3, and the next prime number after 3 is 5. Note that there is exactly one next prime number after each number. So 5 is not the next prime number for 2.
One cold April morning Panoramix predicted that soon Kakofonix will break free from his straitjacket, and this will be a black day for the residents of the Gallic countryside.
Panoramix's prophecy tells that if some day Asterix and Obelix beat exactly *x* Roman soldiers, where *x* is a prime number, and next day they beat exactly *y* Roman soldiers, where *y* is the next prime number after *x*, then it's time to wait for Armageddon, for nothing can shut Kakofonix up while he sings his infernal song.
Yesterday the Gauls beat *n* Roman soldiers and it turned out that the number *n* was prime! Today their victims were a troop of *m* Romans (*m*<=><=*n*). Determine whether the Gauls should wait for the black day after today's victory of Asterix and Obelix?
Input Specification:
The first and only input line contains two positive integers — *n* and *m* (2<=≤<=*n*<=<<=*m*<=≤<=50). It is guaranteed that *n* is prime.
Pretests contain all the cases with restrictions 2<=≤<=*n*<=<<=*m*<=≤<=4.
Output Specification:
Print YES, if *m* is the next prime number after *n*, or NO otherwise.
Demo Input:
['3 5\n', '7 11\n', '7 9\n']
Demo Output:
['YES', 'YES', 'NO']
Note:
none
|
```python
n,m=tuple(map(int,input().split()))
def check_prime(n):
for i in range(2,n//2+1):
if n%i==0:
return False
return True
x=n+1
while True:
if check_prime(x):
break
x+=1
if m==x:
print("YES")
else:
print("NO")
```
| 3.933602
|
231
|
A
|
Team
|
PROGRAMMING
| 800
|
[
"brute force",
"greedy"
] | null | null |
One day three best friends Petya, Vasya and Tonya decided to form a team and take part in programming contests. Participants are usually offered several problems during programming contests. Long before the start the friends decided that they will implement a problem if at least two of them are sure about the solution. Otherwise, the friends won't write the problem's solution.
This contest offers *n* problems to the participants. For each problem we know, which friend is sure about the solution. Help the friends find the number of problems for which they will write a solution.
|
The first input line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems in the contest. Then *n* lines contain three integers each, each integer is either 0 or 1. If the first number in the line equals 1, then Petya is sure about the problem's solution, otherwise he isn't sure. The second number shows Vasya's view on the solution, the third number shows Tonya's view. The numbers on the lines are separated by spaces.
|
Print a single integer — the number of problems the friends will implement on the contest.
|
[
"3\n1 1 0\n1 1 1\n1 0 0\n",
"2\n1 0 0\n0 1 1\n"
] |
[
"2\n",
"1\n"
] |
In the first sample Petya and Vasya are sure that they know how to solve the first problem and all three of them know how to solve the second problem. That means that they will write solutions for these problems. Only Petya is sure about the solution for the third problem, but that isn't enough, so the friends won't take it.
In the second sample the friends will only implement the second problem, as Vasya and Tonya are sure about the solution.
| 500
|
[
{
"input": "3\n1 1 0\n1 1 1\n1 0 0",
"output": "2"
},
{
"input": "2\n1 0 0\n0 1 1",
"output": "1"
},
{
"input": "1\n1 0 0",
"output": "0"
},
{
"input": "2\n1 0 0\n1 1 1",
"output": "1"
},
{
"input": "5\n1 0 0\n0 1 0\n1 1 1\n0 0 1\n0 0 0",
"output": "1"
},
{
"input": "10\n0 1 0\n0 1 0\n1 1 0\n1 0 0\n0 0 1\n0 1 1\n1 1 1\n1 1 0\n0 0 0\n0 0 0",
"output": "4"
},
{
"input": "15\n0 1 0\n1 0 0\n1 1 0\n1 1 1\n0 1 0\n0 0 1\n1 0 1\n1 0 1\n1 0 1\n0 0 0\n1 1 1\n1 1 0\n0 1 1\n1 1 0\n1 1 1",
"output": "10"
},
{
"input": "50\n0 0 0\n0 1 1\n1 1 1\n0 1 0\n1 0 1\n1 1 1\n0 0 1\n1 0 0\n1 1 0\n1 0 1\n0 1 0\n0 0 1\n1 1 0\n0 1 0\n1 1 0\n0 0 0\n1 1 1\n1 0 1\n0 0 1\n1 1 0\n1 1 1\n0 1 1\n1 1 0\n0 0 0\n0 0 0\n1 1 1\n0 0 0\n1 1 1\n0 1 1\n0 0 1\n0 0 0\n0 0 0\n1 1 0\n1 1 0\n1 0 1\n1 0 0\n1 0 1\n1 0 1\n0 1 1\n1 1 0\n1 1 0\n0 1 0\n1 0 1\n0 0 0\n0 0 0\n0 0 0\n0 0 1\n1 1 1\n0 1 1\n1 0 1",
"output": "29"
},
{
"input": "1\n1 1 1",
"output": "1"
},
{
"input": "8\n0 0 0\n0 0 1\n0 0 0\n0 1 1\n1 0 0\n1 0 1\n1 1 0\n1 1 1",
"output": "4"
},
{
"input": "16\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1\n1 1 1",
"output": "16"
}
] | 1,696,585,536
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 21
| 184
| 1,843,200
|
a = int(input())
d = []
for i in range(a):
t = input()
d.append(t)
s = 0
for j in range(len(d)):
if "1 0 1" in d[j] or "1 1 0" in d[j] or "0 1 1" in d[j] or "1 1 1" in d[j]:
s+=1
print(s)
|
Title: Team
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day three best friends Petya, Vasya and Tonya decided to form a team and take part in programming contests. Participants are usually offered several problems during programming contests. Long before the start the friends decided that they will implement a problem if at least two of them are sure about the solution. Otherwise, the friends won't write the problem's solution.
This contest offers *n* problems to the participants. For each problem we know, which friend is sure about the solution. Help the friends find the number of problems for which they will write a solution.
Input Specification:
The first input line contains a single integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems in the contest. Then *n* lines contain three integers each, each integer is either 0 or 1. If the first number in the line equals 1, then Petya is sure about the problem's solution, otherwise he isn't sure. The second number shows Vasya's view on the solution, the third number shows Tonya's view. The numbers on the lines are separated by spaces.
Output Specification:
Print a single integer — the number of problems the friends will implement on the contest.
Demo Input:
['3\n1 1 0\n1 1 1\n1 0 0\n', '2\n1 0 0\n0 1 1\n']
Demo Output:
['2\n', '1\n']
Note:
In the first sample Petya and Vasya are sure that they know how to solve the first problem and all three of them know how to solve the second problem. That means that they will write solutions for these problems. Only Petya is sure about the solution for the third problem, but that isn't enough, so the friends won't take it.
In the second sample the friends will only implement the second problem, as Vasya and Tonya are sure about the solution.
|
```python
a = int(input())
d = []
for i in range(a):
t = input()
d.append(t)
s = 0
for j in range(len(d)):
if "1 0 1" in d[j] or "1 1 0" in d[j] or "0 1 1" in d[j] or "1 1 1" in d[j]:
s+=1
print(s)
```
| 3
|
|
599
|
A
|
Patrick and Shopping
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
Today Patrick waits for a visit from his friend Spongebob. To prepare for the visit, Patrick needs to buy some goodies in two stores located near his house. There is a *d*1 meter long road between his house and the first shop and a *d*2 meter long road between his house and the second shop. Also, there is a road of length *d*3 directly connecting these two shops to each other. Help Patrick calculate the minimum distance that he needs to walk in order to go to both shops and return to his house.
Patrick always starts at his house. He should visit both shops moving only along the three existing roads and return back to his house. He doesn't mind visiting the same shop or passing the same road multiple times. The only goal is to minimize the total distance traveled.
|
The first line of the input contains three integers *d*1, *d*2, *d*3 (1<=≤<=*d*1,<=*d*2,<=*d*3<=≤<=108) — the lengths of the paths.
- *d*1 is the length of the path connecting Patrick's house and the first shop; - *d*2 is the length of the path connecting Patrick's house and the second shop; - *d*3 is the length of the path connecting both shops.
|
Print the minimum distance that Patrick will have to walk in order to visit both shops and return to his house.
|
[
"10 20 30\n",
"1 1 5\n"
] |
[
"60\n",
"4\n"
] |
The first sample is shown on the picture in the problem statement. One of the optimal routes is: house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> first shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> second shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house.
In the second sample one of the optimal routes is: house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> first shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> second shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house.
| 500
|
[
{
"input": "10 20 30",
"output": "60"
},
{
"input": "1 1 5",
"output": "4"
},
{
"input": "100 33 34",
"output": "134"
},
{
"input": "777 777 777",
"output": "2331"
},
{
"input": "2 2 8",
"output": "8"
},
{
"input": "12 34 56",
"output": "92"
},
{
"input": "789 101112 131415",
"output": "203802"
},
{
"input": "27485716 99999999 35182",
"output": "55041796"
},
{
"input": "1 293548 5",
"output": "12"
},
{
"input": "12059 259855 5874875",
"output": "543828"
},
{
"input": "46981 105809 585858",
"output": "305580"
},
{
"input": "9889 1221 2442",
"output": "7326"
},
{
"input": "100500 200600 300700",
"output": "601800"
},
{
"input": "318476 318476 318476",
"output": "955428"
},
{
"input": "23985 3353 75633",
"output": "54676"
},
{
"input": "120 1298 2222",
"output": "2836"
},
{
"input": "98437 23487 666672",
"output": "243848"
},
{
"input": "100000000 100000000 100000000",
"output": "300000000"
},
{
"input": "2 5 2",
"output": "8"
},
{
"input": "1 1000 1",
"output": "4"
},
{
"input": "1 100000000 1",
"output": "4"
}
] | 1,617,298,594
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 2
| 46
| 0
|
d1, d2, d3 = map(int, input().split())
print(min((d1+d2)<<1, d1+d2+d3))
|
Title: Patrick and Shopping
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Today Patrick waits for a visit from his friend Spongebob. To prepare for the visit, Patrick needs to buy some goodies in two stores located near his house. There is a *d*1 meter long road between his house and the first shop and a *d*2 meter long road between his house and the second shop. Also, there is a road of length *d*3 directly connecting these two shops to each other. Help Patrick calculate the minimum distance that he needs to walk in order to go to both shops and return to his house.
Patrick always starts at his house. He should visit both shops moving only along the three existing roads and return back to his house. He doesn't mind visiting the same shop or passing the same road multiple times. The only goal is to minimize the total distance traveled.
Input Specification:
The first line of the input contains three integers *d*1, *d*2, *d*3 (1<=≤<=*d*1,<=*d*2,<=*d*3<=≤<=108) — the lengths of the paths.
- *d*1 is the length of the path connecting Patrick's house and the first shop; - *d*2 is the length of the path connecting Patrick's house and the second shop; - *d*3 is the length of the path connecting both shops.
Output Specification:
Print the minimum distance that Patrick will have to walk in order to visit both shops and return to his house.
Demo Input:
['10 20 30\n', '1 1 5\n']
Demo Output:
['60\n', '4\n']
Note:
The first sample is shown on the picture in the problem statement. One of the optimal routes is: house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> first shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> second shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house.
In the second sample one of the optimal routes is: house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> first shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> second shop <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/70a0795f45d32287dba0eb83fc4a3f470c6e5537.png" style="max-width: 100.0%;max-height: 100.0%;"/> house.
|
```python
d1, d2, d3 = map(int, input().split())
print(min((d1+d2)<<1, d1+d2+d3))
```
| 0
|
|
651
|
A
|
Joysticks
|
PROGRAMMING
| 1,100
|
[
"dp",
"greedy",
"implementation",
"math"
] | null | null |
Friends are going to play console. They have two joysticks and only one charger for them. Initially first joystick is charged at *a*1 percent and second one is charged at *a*2 percent. You can connect charger to a joystick only at the beginning of each minute. In one minute joystick either discharges by 2 percent (if not connected to a charger) or charges by 1 percent (if connected to a charger).
Game continues while both joysticks have a positive charge. Hence, if at the beginning of minute some joystick is charged by 1 percent, it has to be connected to a charger, otherwise the game stops. If some joystick completely discharges (its charge turns to 0), the game also stops.
Determine the maximum number of minutes that game can last. It is prohibited to pause the game, i. e. at each moment both joysticks should be enabled. It is allowed for joystick to be charged by more than 100 percent.
|
The first line of the input contains two positive integers *a*1 and *a*2 (1<=≤<=*a*1,<=*a*2<=≤<=100), the initial charge level of first and second joystick respectively.
|
Output the only integer, the maximum number of minutes that the game can last. Game continues until some joystick is discharged.
|
[
"3 5\n",
"4 4\n"
] |
[
"6\n",
"5\n"
] |
In the first sample game lasts for 6 minute by using the following algorithm:
- at the beginning of the first minute connect first joystick to the charger, by the end of this minute first joystick is at 4%, second is at 3%; - continue the game without changing charger, by the end of the second minute the first joystick is at 5%, second is at 1%; - at the beginning of the third minute connect second joystick to the charger, after this minute the first joystick is at 3%, the second one is at 2%; - continue the game without changing charger, by the end of the fourth minute first joystick is at 1%, second one is at 3%; - at the beginning of the fifth minute connect first joystick to the charger, after this minute the first joystick is at 2%, the second one is at 1%; - at the beginning of the sixth minute connect second joystick to the charger, after this minute the first joystick is at 0%, the second one is at 2%.
After that the first joystick is completely discharged and the game is stopped.
| 500
|
[
{
"input": "3 5",
"output": "6"
},
{
"input": "4 4",
"output": "5"
},
{
"input": "100 100",
"output": "197"
},
{
"input": "1 100",
"output": "98"
},
{
"input": "100 1",
"output": "98"
},
{
"input": "1 4",
"output": "2"
},
{
"input": "1 1",
"output": "0"
},
{
"input": "8 8",
"output": "13"
},
{
"input": "7 2",
"output": "7"
},
{
"input": "24 15",
"output": "36"
},
{
"input": "19 30",
"output": "47"
},
{
"input": "15 31",
"output": "44"
},
{
"input": "14 15",
"output": "27"
},
{
"input": "58 33",
"output": "89"
},
{
"input": "15 25",
"output": "38"
},
{
"input": "59 45",
"output": "102"
},
{
"input": "3 73",
"output": "74"
},
{
"input": "48 1",
"output": "47"
},
{
"input": "100 25",
"output": "122"
},
{
"input": "40 49",
"output": "86"
},
{
"input": "85 73",
"output": "155"
},
{
"input": "29 1",
"output": "28"
},
{
"input": "74 25",
"output": "97"
},
{
"input": "24 57",
"output": "78"
},
{
"input": "23 12",
"output": "33"
},
{
"input": "2 99",
"output": "99"
},
{
"input": "98 2",
"output": "97"
},
{
"input": "2 97",
"output": "97"
},
{
"input": "30 54",
"output": "81"
},
{
"input": "32 53",
"output": "82"
},
{
"input": "32 54",
"output": "84"
},
{
"input": "1 2",
"output": "1"
},
{
"input": "2 1",
"output": "1"
},
{
"input": "2 2",
"output": "1"
},
{
"input": "1 3",
"output": "2"
},
{
"input": "3 1",
"output": "2"
},
{
"input": "1 4",
"output": "2"
},
{
"input": "2 3",
"output": "3"
},
{
"input": "3 2",
"output": "3"
}
] | 1,590,953,215
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 108
| 0
|
a1a2 = input().split()
a1 = int(a1a2[0])
a2 = int(a1a2[1])
count = 0
while a1>0 and a2>0:
if a1<=a2:
a1 += 1
a2 -= 2
else:
a2 += 1
a1 -= 2
count += 1
print(count)
|
Title: Joysticks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Friends are going to play console. They have two joysticks and only one charger for them. Initially first joystick is charged at *a*1 percent and second one is charged at *a*2 percent. You can connect charger to a joystick only at the beginning of each minute. In one minute joystick either discharges by 2 percent (if not connected to a charger) or charges by 1 percent (if connected to a charger).
Game continues while both joysticks have a positive charge. Hence, if at the beginning of minute some joystick is charged by 1 percent, it has to be connected to a charger, otherwise the game stops. If some joystick completely discharges (its charge turns to 0), the game also stops.
Determine the maximum number of minutes that game can last. It is prohibited to pause the game, i. e. at each moment both joysticks should be enabled. It is allowed for joystick to be charged by more than 100 percent.
Input Specification:
The first line of the input contains two positive integers *a*1 and *a*2 (1<=≤<=*a*1,<=*a*2<=≤<=100), the initial charge level of first and second joystick respectively.
Output Specification:
Output the only integer, the maximum number of minutes that the game can last. Game continues until some joystick is discharged.
Demo Input:
['3 5\n', '4 4\n']
Demo Output:
['6\n', '5\n']
Note:
In the first sample game lasts for 6 minute by using the following algorithm:
- at the beginning of the first minute connect first joystick to the charger, by the end of this minute first joystick is at 4%, second is at 3%; - continue the game without changing charger, by the end of the second minute the first joystick is at 5%, second is at 1%; - at the beginning of the third minute connect second joystick to the charger, after this minute the first joystick is at 3%, the second one is at 2%; - continue the game without changing charger, by the end of the fourth minute first joystick is at 1%, second one is at 3%; - at the beginning of the fifth minute connect first joystick to the charger, after this minute the first joystick is at 2%, the second one is at 1%; - at the beginning of the sixth minute connect second joystick to the charger, after this minute the first joystick is at 0%, the second one is at 2%.
After that the first joystick is completely discharged and the game is stopped.
|
```python
a1a2 = input().split()
a1 = int(a1a2[0])
a2 = int(a1a2[1])
count = 0
while a1>0 and a2>0:
if a1<=a2:
a1 += 1
a2 -= 2
else:
a2 += 1
a1 -= 2
count += 1
print(count)
```
| 0
|
|
628
|
C
|
Bear and String Distance
|
PROGRAMMING
| 1,300
|
[
"greedy",
"strings"
] | null | null |
Limak is a little polar bear. He likes nice strings — strings of length *n*, consisting of lowercase English letters only.
The distance between two letters is defined as the difference between their positions in the alphabet. For example, , and .
Also, the distance between two nice strings is defined as the sum of distances of corresponding letters. For example, , and .
Limak gives you a nice string *s* and an integer *k*. He challenges you to find any nice string *s*' that . Find any *s*' satisfying the given conditions, or print "-1" if it's impossible to do so.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use gets/scanf/printf instead of getline/cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java.
|
The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=106).
The second line contains a string *s* of length *n*, consisting of lowercase English letters.
|
If there is no string satisfying the given conditions then print "-1" (without the quotes).
Otherwise, print any nice string *s*' that .
|
[
"4 26\nbear\n",
"2 7\naf\n",
"3 1000\nhey\n"
] |
[
"roar",
"db\n",
"-1\n"
] |
none
| 0
|
[
{
"input": "4 26\nbear",
"output": "zcar"
},
{
"input": "2 7\naf",
"output": "hf"
},
{
"input": "3 1000\nhey",
"output": "-1"
},
{
"input": "5 50\nkzsij",
"output": "zaiij"
},
{
"input": "5 500\nvsdxg",
"output": "-1"
},
{
"input": "1 0\na",
"output": "a"
},
{
"input": "1 1\ng",
"output": "f"
},
{
"input": "1 25\nr",
"output": "-1"
},
{
"input": "1 15\no",
"output": "-1"
},
{
"input": "10 100\naddaiyssyp",
"output": "zzzzcyssyp"
},
{
"input": "50 100\ntewducenaqgpilgftjcmzttrgebnyldwfgbtttrygaiqtkgbjb",
"output": "azazecenaqgpilgftjcmzttrgebnyldwfgbtttrygaiqtkgbjb"
},
{
"input": "2 1\nzz",
"output": "yz"
},
{
"input": "8 8\nabcdefgh",
"output": "ibcdefgh"
},
{
"input": "1 25\nz",
"output": "a"
},
{
"input": "1 24\nz",
"output": "b"
},
{
"input": "1 24\ny",
"output": "a"
},
{
"input": "2 49\nzz",
"output": "ab"
},
{
"input": "1 26\na",
"output": "-1"
},
{
"input": "1 25\na",
"output": "z"
},
{
"input": "4 17\nrzsq",
"output": "azsq"
},
{
"input": "69 1701\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzy",
"output": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaax"
},
{
"input": "2 9\nbc",
"output": "kc"
},
{
"input": "2 48\nab",
"output": "zy"
},
{
"input": "1 8\nc",
"output": "k"
},
{
"input": "2 25\nyd",
"output": "ac"
},
{
"input": "5 24\nizrqp",
"output": "zsrqp"
},
{
"input": "1 13\nn",
"output": "a"
},
{
"input": "5 21\nfmmqh",
"output": "zlmqh"
}
] | 1,606,332,770
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 5
| 93
| 307,200
|
n,k=map(int,input().split())
s=input()
ans=k;r=""
for i in range(len(s)):
if k!=0:
if ord(s[i])+k>122:
r+='z'
k-=(122-ord(s[i]))
else:
x=ord(s[i])+k
r+=chr(x)
k-=(abs(ord(s[i])-x))
else:
r+=s[i]
if k:
print(-1)
else:
print(r)
|
Title: Bear and String Distance
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Limak is a little polar bear. He likes nice strings — strings of length *n*, consisting of lowercase English letters only.
The distance between two letters is defined as the difference between their positions in the alphabet. For example, , and .
Also, the distance between two nice strings is defined as the sum of distances of corresponding letters. For example, , and .
Limak gives you a nice string *s* and an integer *k*. He challenges you to find any nice string *s*' that . Find any *s*' satisfying the given conditions, or print "-1" if it's impossible to do so.
As input/output can reach huge size it is recommended to use fast input/output methods: for example, prefer to use gets/scanf/printf instead of getline/cin/cout in C++, prefer to use BufferedReader/PrintWriter instead of Scanner/System.out in Java.
Input Specification:
The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=106).
The second line contains a string *s* of length *n*, consisting of lowercase English letters.
Output Specification:
If there is no string satisfying the given conditions then print "-1" (without the quotes).
Otherwise, print any nice string *s*' that .
Demo Input:
['4 26\nbear\n', '2 7\naf\n', '3 1000\nhey\n']
Demo Output:
['roar', 'db\n', '-1\n']
Note:
none
|
```python
n,k=map(int,input().split())
s=input()
ans=k;r=""
for i in range(len(s)):
if k!=0:
if ord(s[i])+k>122:
r+='z'
k-=(122-ord(s[i]))
else:
x=ord(s[i])+k
r+=chr(x)
k-=(abs(ord(s[i])-x))
else:
r+=s[i]
if k:
print(-1)
else:
print(r)
```
| 0
|
|
846
|
A
|
Curriculum Vitae
|
PROGRAMMING
| 1,500
|
[
"brute force",
"implementation"
] | null | null |
Hideo Kojima has just quit his job at Konami. Now he is going to find a new place to work. Despite being such a well-known person, he still needs a CV to apply for a job.
During all his career Hideo has produced *n* games. Some of them were successful, some were not. Hideo wants to remove several of them (possibly zero) from his CV to make a better impression on employers. As a result there should be no unsuccessful game which comes right after successful one in his CV.
More formally, you are given an array *s*1,<=*s*2,<=...,<=*s**n* of zeros and ones. Zero corresponds to an unsuccessful game, one — to a successful one. Games are given in order they were produced, and Hideo can't swap these values. He should remove some elements from this array in such a way that no zero comes right after one.
Besides that, Hideo still wants to mention as much games in his CV as possible. Help this genius of a man determine the maximum number of games he can leave in his CV.
|
The first line contains one integer number *n* (1<=≤<=*n*<=≤<=100).
The second line contains *n* space-separated integer numbers *s*1,<=*s*2,<=...,<=*s**n* (0<=≤<=*s**i*<=≤<=1). 0 corresponds to an unsuccessful game, 1 — to a successful one.
|
Print one integer — the maximum number of games Hideo can leave in his CV so that no unsuccessful game comes after a successful one.
|
[
"4\n1 1 0 1\n",
"6\n0 1 0 0 1 0\n",
"1\n0\n"
] |
[
"3\n",
"4\n",
"1\n"
] |
none
| 0
|
[
{
"input": "4\n1 1 0 1",
"output": "3"
},
{
"input": "6\n0 1 0 0 1 0",
"output": "4"
},
{
"input": "1\n0",
"output": "1"
},
{
"input": "100\n0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "100"
},
{
"input": "100\n0 0 1 1 1 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 1 0 0 0 0 0 0 1 1 1 0 0 1 0 1 0 0 0 1 1 0 0 0 0 0 1 1 0 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 1 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "80"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "100\n1 1 0 1 1 0 0 0 0 1 0 1 1 1 0 1 1 1 1 0 1 1 1 1 1 1 0 1 1 0 0 1 1 1 0 0 0 1 0 0 1 0 1 1 0 1 0 0 1 0 0 1 1 0 0 1 0 0 1 1 0 1 0 1 0 0 0 0 0 1 0 0 0 0 0 0 1 1 0 0 0 1 1 1 0 1 1 0 1 1 1 0 0 1 1 0 0 0 0 1",
"output": "53"
},
{
"input": "100\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "100"
},
{
"input": "3\n1 0 0",
"output": "2"
},
{
"input": "10\n1 1 0 0 0 1 1 0 0 0",
"output": "6"
},
{
"input": "90\n1 0 0 1 1 0 0 1 0 0 0 0 1 1 1 0 1 0 1 0 0 0 0 1 0 0 1 1 1 1 1 0 0 0 1 0 1 0 1 0 1 0 0 1 0 1 0 1 0 1 0 1 0 0 1 0 0 1 1 0 0 1 0 0 0 0 1 1 1 0 1 0 1 0 0 0 0 1 0 0 1 1 1 1 1 0 0 0 1 0",
"output": "52"
},
{
"input": "78\n0 0 1 0 1 0 1 1 0 0 0 1 1 1 1 0 0 0 1 0 1 1 1 0 1 0 0 0 1 0 0 0 1 1 1 1 1 1 1 1 1 1 1 0 1 0 0 0 0 0 1 0 0 1 0 1 0 1 0 1 0 1 1 1 0 0 1 0 0 0 0 1 0 1 0 0 1 0",
"output": "42"
},
{
"input": "4\n1 0 0 1",
"output": "3"
},
{
"input": "2\n0 1",
"output": "2"
},
{
"input": "5\n0 1 0 0 1",
"output": "4"
},
{
"input": "3\n1 0 1",
"output": "2"
},
{
"input": "3\n1 1 0",
"output": "2"
},
{
"input": "16\n1 1 1 1 1 0 0 0 0 0 1 0 1 0 0 1",
"output": "9"
}
] | 1,504,624,482
| 582
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 77
| 921,600
|
from sys import stdout
from random import randint
from math import *
import re
n = int(input())
s = input().replace(' ', '')
temp = re.findall("1.*", s)
if not temp:
ans = len(s)
else:
ns = temp[0]
ans = len(s) - len(ns) + max(ns.count('1'), ns.count('0'))
print(ans)
|
Title: Curriculum Vitae
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Hideo Kojima has just quit his job at Konami. Now he is going to find a new place to work. Despite being such a well-known person, he still needs a CV to apply for a job.
During all his career Hideo has produced *n* games. Some of them were successful, some were not. Hideo wants to remove several of them (possibly zero) from his CV to make a better impression on employers. As a result there should be no unsuccessful game which comes right after successful one in his CV.
More formally, you are given an array *s*1,<=*s*2,<=...,<=*s**n* of zeros and ones. Zero corresponds to an unsuccessful game, one — to a successful one. Games are given in order they were produced, and Hideo can't swap these values. He should remove some elements from this array in such a way that no zero comes right after one.
Besides that, Hideo still wants to mention as much games in his CV as possible. Help this genius of a man determine the maximum number of games he can leave in his CV.
Input Specification:
The first line contains one integer number *n* (1<=≤<=*n*<=≤<=100).
The second line contains *n* space-separated integer numbers *s*1,<=*s*2,<=...,<=*s**n* (0<=≤<=*s**i*<=≤<=1). 0 corresponds to an unsuccessful game, 1 — to a successful one.
Output Specification:
Print one integer — the maximum number of games Hideo can leave in his CV so that no unsuccessful game comes after a successful one.
Demo Input:
['4\n1 1 0 1\n', '6\n0 1 0 0 1 0\n', '1\n0\n']
Demo Output:
['3\n', '4\n', '1\n']
Note:
none
|
```python
from sys import stdout
from random import randint
from math import *
import re
n = int(input())
s = input().replace(' ', '')
temp = re.findall("1.*", s)
if not temp:
ans = len(s)
else:
ns = temp[0]
ans = len(s) - len(ns) + max(ns.count('1'), ns.count('0'))
print(ans)
```
| 0
|
|
714
|
A
|
Meeting of Old Friends
|
PROGRAMMING
| 1,100
|
[
"implementation",
"math"
] | null | null |
Today an outstanding event is going to happen in the forest — hedgehog Filya will come to his old fried Sonya!
Sonya is an owl and she sleeps during the day and stay awake from minute *l*1 to minute *r*1 inclusive. Also, during the minute *k* she prinks and is unavailable for Filya.
Filya works a lot and he plans to visit Sonya from minute *l*2 to minute *r*2 inclusive.
Calculate the number of minutes they will be able to spend together.
|
The only line of the input contains integers *l*1, *r*1, *l*2, *r*2 and *k* (1<=≤<=*l*1,<=*r*1,<=*l*2,<=*r*2,<=*k*<=≤<=1018, *l*1<=≤<=*r*1, *l*2<=≤<=*r*2), providing the segments of time for Sonya and Filya and the moment of time when Sonya prinks.
|
Print one integer — the number of minutes Sonya and Filya will be able to spend together.
|
[
"1 10 9 20 1\n",
"1 100 50 200 75\n"
] |
[
"2\n",
"50\n"
] |
In the first sample, they will be together during minutes 9 and 10.
In the second sample, they will be together from minute 50 to minute 74 and from minute 76 to minute 100.
| 500
|
[
{
"input": "1 10 9 20 1",
"output": "2"
},
{
"input": "1 100 50 200 75",
"output": "50"
},
{
"input": "6 6 5 8 9",
"output": "1"
},
{
"input": "1 1000000000 1 1000000000 1",
"output": "999999999"
},
{
"input": "5 100 8 8 8",
"output": "0"
},
{
"input": "1 1000000000000000000 2 99999999999999999 1000000000",
"output": "99999999999999997"
},
{
"input": "1 1 1 1 1",
"output": "0"
},
{
"input": "1 2 3 4 5",
"output": "0"
},
{
"input": "1 1000000000 2 999999999 3141592",
"output": "999999997"
},
{
"input": "24648817341102 41165114064236 88046848035 13602161452932 10000831349205",
"output": "0"
},
{
"input": "1080184299348 34666828555290 6878390132365 39891656267344 15395310291636",
"output": "27788438422925"
},
{
"input": "11814 27385 22309 28354 23595",
"output": "5076"
},
{
"input": "4722316546398 36672578279675 796716437180 33840047334985 13411035401708",
"output": "29117730788587"
},
{
"input": "14300093617438 14381698008501 6957847034861 32510754974307 66056597033082",
"output": "81604391064"
},
{
"input": "700062402405871919 762322967106512617 297732773882447821 747309903322652819 805776739998108178",
"output": "47247500916780901"
},
{
"input": "59861796371397621 194872039092923459 668110259718450585 841148673332698972 928360292123223779",
"output": "0"
},
{
"input": "298248781360904821 346420922793050061 237084570581741798 726877079564549183 389611850470532358",
"output": "48172141432145241"
},
{
"input": "420745791717606818 864206437350900994 764928840030524015 966634105370748487 793326512080703489",
"output": "99277597320376979"
},
{
"input": "519325240668210886 776112702001665034 360568516809443669 875594219634943179 994594983925273138",
"output": "256787461333454149"
},
{
"input": "170331212821058551 891149660635282032 125964175621755330 208256491683509799 526532153531983174",
"output": "37925278862451249"
},
{
"input": "1 3 3 5 3",
"output": "0"
},
{
"input": "1 5 8 10 9",
"output": "0"
},
{
"input": "1 2 4 5 10",
"output": "0"
},
{
"input": "1 2 2 3 5",
"output": "1"
},
{
"input": "2 4 3 7 3",
"output": "1"
},
{
"input": "1 2 9 10 1",
"output": "0"
},
{
"input": "5 15 1 10 5",
"output": "5"
},
{
"input": "1 4 9 20 25",
"output": "0"
},
{
"input": "2 4 1 2 5",
"output": "1"
},
{
"input": "10 1000 1 100 2",
"output": "91"
},
{
"input": "1 3 3 8 10",
"output": "1"
},
{
"input": "4 6 6 8 9",
"output": "1"
},
{
"input": "2 3 1 4 3",
"output": "1"
},
{
"input": "1 2 2 3 100",
"output": "1"
},
{
"input": "1 2 100 120 2",
"output": "0"
},
{
"input": "1 3 5 7 4",
"output": "0"
},
{
"input": "1 3 5 7 5",
"output": "0"
},
{
"input": "1 4 8 10 6",
"output": "0"
},
{
"input": "1 2 5 6 100",
"output": "0"
},
{
"input": "1 2 5 10 20",
"output": "0"
},
{
"input": "1 2 5 6 7",
"output": "0"
},
{
"input": "2 5 7 12 6",
"output": "0"
},
{
"input": "10 20 50 100 80",
"output": "0"
},
{
"input": "1 2 5 10 2",
"output": "0"
},
{
"input": "1 2 5 6 4",
"output": "0"
},
{
"input": "5 9 1 2 3",
"output": "0"
},
{
"input": "50 100 1 20 3",
"output": "0"
},
{
"input": "10 20 3 7 30",
"output": "0"
},
{
"input": "1 5 10 10 100",
"output": "0"
},
{
"input": "100 101 1 2 3",
"output": "0"
},
{
"input": "1 5 10 20 6",
"output": "0"
},
{
"input": "1 10 15 25 5",
"output": "0"
},
{
"input": "1 2 5 10 3",
"output": "0"
},
{
"input": "2 3 5 6 100",
"output": "0"
},
{
"input": "1 2 4 5 6",
"output": "0"
},
{
"input": "6 10 1 2 40",
"output": "0"
},
{
"input": "20 30 1 5 1",
"output": "0"
},
{
"input": "20 40 50 100 50",
"output": "0"
},
{
"input": "1 1 4 9 2",
"output": "0"
},
{
"input": "1 2 5 6 1",
"output": "0"
},
{
"input": "1 100 400 500 450",
"output": "0"
},
{
"input": "5 6 1 2 5",
"output": "0"
},
{
"input": "1 10 21 30 50",
"output": "0"
},
{
"input": "100 200 300 400 101",
"output": "0"
},
{
"input": "2 8 12 16 9",
"output": "0"
},
{
"input": "1 5 7 9 6",
"output": "0"
},
{
"input": "300 400 100 200 101",
"output": "0"
},
{
"input": "1 2 2 3 10",
"output": "1"
},
{
"input": "1 10 100 200 5",
"output": "0"
},
{
"input": "1 3 3 4 4",
"output": "1"
},
{
"input": "10 20 30 40 25",
"output": "0"
},
{
"input": "1 2 5 10 1",
"output": "0"
},
{
"input": "2 4 8 10 1",
"output": "0"
},
{
"input": "2 5 10 15 7",
"output": "0"
},
{
"input": "100 200 5 10 1",
"output": "0"
},
{
"input": "1 2 100 200 300",
"output": "0"
},
{
"input": "30 100 10 20 25",
"output": "0"
},
{
"input": "10 20 1 5 6",
"output": "0"
},
{
"input": "4 5 1 2 4",
"output": "0"
},
{
"input": "11 100 1 9 1000",
"output": "0"
},
{
"input": "1 1 10 10 228",
"output": "0"
},
{
"input": "5 7 10 20 15",
"output": "0"
},
{
"input": "1 3 8 9 7",
"output": "0"
},
{
"input": "1 10 2 8 8",
"output": "6"
},
{
"input": "1 5 9 15 1",
"output": "0"
},
{
"input": "1 3 5 6 12",
"output": "0"
},
{
"input": "1 100 500 1000 3",
"output": "0"
},
{
"input": "1 1 1 1 2",
"output": "1"
},
{
"input": "1 1000 100 1000 200",
"output": "900"
},
{
"input": "4 5 1 4 1",
"output": "1"
},
{
"input": "1 5 5 7 3",
"output": "1"
},
{
"input": "1 4 4 10 11",
"output": "1"
},
{
"input": "1 1 3 4 100",
"output": "0"
},
{
"input": "1 4 3 5 6",
"output": "2"
},
{
"input": "10 100 20 30 40",
"output": "11"
},
{
"input": "5 9 1 11 7",
"output": "4"
}
] | 1,478,496,189
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 9
| 61
| 0
|
s_time1,s_time2,f_time1,f_time2,p_time=map(int,input().split(" "))
timeset=[]
timeset.append(max(s_time1,f_time1))
timeset.append(min(s_time2,f_time2))
time=(timeset[1]+1)-timeset[0]
if p_time >= timeset[0] and p_time <= timeset[1]:
time -= 1
print(time)
|
Title: Meeting of Old Friends
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Today an outstanding event is going to happen in the forest — hedgehog Filya will come to his old fried Sonya!
Sonya is an owl and she sleeps during the day and stay awake from minute *l*1 to minute *r*1 inclusive. Also, during the minute *k* she prinks and is unavailable for Filya.
Filya works a lot and he plans to visit Sonya from minute *l*2 to minute *r*2 inclusive.
Calculate the number of minutes they will be able to spend together.
Input Specification:
The only line of the input contains integers *l*1, *r*1, *l*2, *r*2 and *k* (1<=≤<=*l*1,<=*r*1,<=*l*2,<=*r*2,<=*k*<=≤<=1018, *l*1<=≤<=*r*1, *l*2<=≤<=*r*2), providing the segments of time for Sonya and Filya and the moment of time when Sonya prinks.
Output Specification:
Print one integer — the number of minutes Sonya and Filya will be able to spend together.
Demo Input:
['1 10 9 20 1\n', '1 100 50 200 75\n']
Demo Output:
['2\n', '50\n']
Note:
In the first sample, they will be together during minutes 9 and 10.
In the second sample, they will be together from minute 50 to minute 74 and from minute 76 to minute 100.
|
```python
s_time1,s_time2,f_time1,f_time2,p_time=map(int,input().split(" "))
timeset=[]
timeset.append(max(s_time1,f_time1))
timeset.append(min(s_time2,f_time2))
time=(timeset[1]+1)-timeset[0]
if p_time >= timeset[0] and p_time <= timeset[1]:
time -= 1
print(time)
```
| 0
|
|
538
|
B
|
Quasi Binary
|
PROGRAMMING
| 1,400
|
[
"constructive algorithms",
"dp",
"greedy",
"implementation"
] | null | null |
A number is called quasibinary if its decimal representation contains only digits 0 or 1. For example, numbers 0, 1, 101, 110011 — are quasibinary and numbers 2, 12, 900 are not.
You are given a positive integer *n*. Represent it as a sum of minimum number of quasibinary numbers.
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=106).
|
In the first line print a single integer *k* — the minimum number of numbers in the representation of number *n* as a sum of quasibinary numbers.
In the second line print *k* numbers — the elements of the sum. All these numbers should be quasibinary according to the definition above, their sum should equal *n*. Do not have to print the leading zeroes in the numbers. The order of numbers doesn't matter. If there are multiple possible representations, you are allowed to print any of them.
|
[
"9\n",
"32\n"
] |
[
"9\n1 1 1 1 1 1 1 1 1 \n",
"3\n10 11 11 \n"
] |
none
| 1,000
|
[
{
"input": "9",
"output": "9\n1 1 1 1 1 1 1 1 1 "
},
{
"input": "32",
"output": "3\n10 11 11 "
},
{
"input": "1",
"output": "1\n1 "
},
{
"input": "415",
"output": "5\n1 101 101 101 111 "
},
{
"input": "10011",
"output": "1\n10011 "
},
{
"input": "10201",
"output": "2\n100 10101 "
},
{
"input": "314159",
"output": "9\n1 1 1 1 11 1011 101011 101011 111111 "
},
{
"input": "999999",
"output": "9\n111111 111111 111111 111111 111111 111111 111111 111111 111111 "
},
{
"input": "2",
"output": "2\n1 1 "
},
{
"input": "10",
"output": "1\n10 "
},
{
"input": "21",
"output": "2\n10 11 "
},
{
"input": "98",
"output": "9\n10 11 11 11 11 11 11 11 11 "
},
{
"input": "102030",
"output": "3\n10 1010 101010 "
},
{
"input": "909090",
"output": "9\n101010 101010 101010 101010 101010 101010 101010 101010 101010 "
},
{
"input": "909823",
"output": "9\n101000 101100 101100 101100 101100 101100 101101 101111 101111 "
},
{
"input": "1000000",
"output": "1\n1000000 "
},
{
"input": "111111",
"output": "1\n111111 "
},
{
"input": "123456",
"output": "6\n1 11 111 1111 11111 111111 "
},
{
"input": "987654",
"output": "9\n100000 110000 111000 111100 111110 111111 111111 111111 111111 "
},
{
"input": "908172",
"output": "9\n100000 101000 101010 101010 101010 101010 101010 101011 101111 "
},
{
"input": "8",
"output": "8\n1 1 1 1 1 1 1 1 "
},
{
"input": "100009",
"output": "9\n1 1 1 1 1 1 1 1 100001 "
},
{
"input": "900000",
"output": "9\n100000 100000 100000 100000 100000 100000 100000 100000 100000 "
},
{
"input": "1435",
"output": "5\n1 101 111 111 1111 "
},
{
"input": "1453",
"output": "5\n10 110 111 111 1111 "
}
] | 1,642,482,663
| 2,147,483,647
|
PyPy 3
|
WRONG_ANSWER
|
TESTS
| 3
| 62
| 0
|
def check(t):
s=str(t)
c=0
for i in s:
if i!='0' and i!='1':
c=1
break
if c==0:
return True
return False
n=int(input())
d=len(str(n))
c=0
s=str(n)
for i in s:
if i!='0' and i!='1':
c=1
break
if c==0:
print(1)
print(n)
else:
l=[]
x=int("1"*d)
t=n
while x>=1 and t>0:
if check(t):
l.append(t)
t-=t
if(x<=t):
c=t//x
t-=c*x
i=0
while i<c:
l.append(x)
i+=1
else:
x=x//10
print(len(l))
for i in l:
print(i,end=" ")
|
Title: Quasi Binary
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A number is called quasibinary if its decimal representation contains only digits 0 or 1. For example, numbers 0, 1, 101, 110011 — are quasibinary and numbers 2, 12, 900 are not.
You are given a positive integer *n*. Represent it as a sum of minimum number of quasibinary numbers.
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=106).
Output Specification:
In the first line print a single integer *k* — the minimum number of numbers in the representation of number *n* as a sum of quasibinary numbers.
In the second line print *k* numbers — the elements of the sum. All these numbers should be quasibinary according to the definition above, their sum should equal *n*. Do not have to print the leading zeroes in the numbers. The order of numbers doesn't matter. If there are multiple possible representations, you are allowed to print any of them.
Demo Input:
['9\n', '32\n']
Demo Output:
['9\n1 1 1 1 1 1 1 1 1 \n', '3\n10 11 11 \n']
Note:
none
|
```python
def check(t):
s=str(t)
c=0
for i in s:
if i!='0' and i!='1':
c=1
break
if c==0:
return True
return False
n=int(input())
d=len(str(n))
c=0
s=str(n)
for i in s:
if i!='0' and i!='1':
c=1
break
if c==0:
print(1)
print(n)
else:
l=[]
x=int("1"*d)
t=n
while x>=1 and t>0:
if check(t):
l.append(t)
t-=t
if(x<=t):
c=t//x
t-=c*x
i=0
while i<c:
l.append(x)
i+=1
else:
x=x//10
print(len(l))
for i in l:
print(i,end=" ")
```
| 0
|
|
749
|
A
|
Bachgold Problem
|
PROGRAMMING
| 800
|
[
"greedy",
"implementation",
"math",
"number theory"
] | null | null |
Bachgold problem is very easy to formulate. Given a positive integer *n* represent it as a sum of maximum possible number of prime numbers. One can prove that such representation exists for any integer greater than 1.
Recall that integer *k* is called prime if it is greater than 1 and has exactly two positive integer divisors — 1 and *k*.
|
The only line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100<=000).
|
The first line of the output contains a single integer *k* — maximum possible number of primes in representation.
The second line should contain *k* primes with their sum equal to *n*. You can print them in any order. If there are several optimal solution, print any of them.
|
[
"5\n",
"6\n"
] |
[
"2\n2 3\n",
"3\n2 2 2\n"
] |
none
| 500
|
[
{
"input": "5",
"output": "2\n2 3"
},
{
"input": "6",
"output": "3\n2 2 2"
},
{
"input": "2",
"output": "1\n2"
},
{
"input": "3",
"output": "1\n3"
},
{
"input": "99999",
"output": "49999\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "100000",
"output": "50000\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "7",
"output": "3\n2 2 3"
},
{
"input": "4",
"output": "2\n2 2"
},
{
"input": "8",
"output": "4\n2 2 2 2"
},
{
"input": "9",
"output": "4\n2 2 2 3"
},
{
"input": "99995",
"output": "49997\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99996",
"output": "49998\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "10",
"output": "5\n2 2 2 2 2"
},
{
"input": "11",
"output": "5\n2 2 2 2 3"
},
{
"input": "99997",
"output": "49998\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99998",
"output": "49999\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "12",
"output": "6\n2 2 2 2 2 2"
},
{
"input": "13",
"output": "6\n2 2 2 2 2 3"
},
{
"input": "99993",
"output": "49996\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99994",
"output": "49997\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "14",
"output": "7\n2 2 2 2 2 2 2"
},
{
"input": "15",
"output": "7\n2 2 2 2 2 2 3"
},
{
"input": "53",
"output": "26\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "57",
"output": "28\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "61",
"output": "30\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "774",
"output": "387\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "202",
"output": "101\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2"
},
{
"input": "530",
"output": "265\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "7166",
"output": "3583\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "9294",
"output": "4647\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "2422",
"output": "1211\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "15326",
"output": "7663\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "11454",
"output": "5727\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "14878",
"output": "7439\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
},
{
"input": "90672",
"output": "45336\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "99544",
"output": "49772\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "90472",
"output": "45236\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 ..."
},
{
"input": "23",
"output": "11\n2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "93",
"output": "46\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3"
},
{
"input": "19",
"output": "9\n2 2 2 2 2 2 2 2 3"
},
{
"input": "11110",
"output": "5555\n2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2..."
}
] | 1,647,520,066
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 41
| 46
| 0
|
n = int(input());
if not n%2:
print(n//2)
st = "2 " * (n//2)
print(st)
else:
n -= 3
print(n//2 + 1)
st = "2 " * (n//2)
print(st + '3')
|
Title: Bachgold Problem
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Bachgold problem is very easy to formulate. Given a positive integer *n* represent it as a sum of maximum possible number of prime numbers. One can prove that such representation exists for any integer greater than 1.
Recall that integer *k* is called prime if it is greater than 1 and has exactly two positive integer divisors — 1 and *k*.
Input Specification:
The only line of the input contains a single integer *n* (2<=≤<=*n*<=≤<=100<=000).
Output Specification:
The first line of the output contains a single integer *k* — maximum possible number of primes in representation.
The second line should contain *k* primes with their sum equal to *n*. You can print them in any order. If there are several optimal solution, print any of them.
Demo Input:
['5\n', '6\n']
Demo Output:
['2\n2 3\n', '3\n2 2 2\n']
Note:
none
|
```python
n = int(input());
if not n%2:
print(n//2)
st = "2 " * (n//2)
print(st)
else:
n -= 3
print(n//2 + 1)
st = "2 " * (n//2)
print(st + '3')
```
| 3
|
|
653
|
A
|
Bear and Three Balls
|
PROGRAMMING
| 900
|
[
"brute force",
"implementation",
"sortings"
] | null | null |
Limak is a little polar bear. He has *n* balls, the *i*-th ball has size *t**i*.
Limak wants to give one ball to each of his three friends. Giving gifts isn't easy — there are two rules Limak must obey to make friends happy:
- No two friends can get balls of the same size. - No two friends can get balls of sizes that differ by more than 2.
For example, Limak can choose balls with sizes 4, 5 and 3, or balls with sizes 90, 91 and 92. But he can't choose balls with sizes 5, 5 and 6 (two friends would get balls of the same size), and he can't choose balls with sizes 30, 31 and 33 (because sizes 30 and 33 differ by more than 2).
Your task is to check whether Limak can choose three balls that satisfy conditions above.
|
The first line of the input contains one integer *n* (3<=≤<=*n*<=≤<=50) — the number of balls Limak has.
The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=1000) where *t**i* denotes the size of the *i*-th ball.
|
Print "YES" (without quotes) if Limak can choose three balls of distinct sizes, such that any two of them differ by no more than 2. Otherwise, print "NO" (without quotes).
|
[
"4\n18 55 16 17\n",
"6\n40 41 43 44 44 44\n",
"8\n5 972 3 4 1 4 970 971\n"
] |
[
"YES\n",
"NO\n",
"YES\n"
] |
In the first sample, there are 4 balls and Limak is able to choose three of them to satisfy the rules. He must must choose balls with sizes 18, 16 and 17.
In the second sample, there is no way to give gifts to three friends without breaking the rules.
In the third sample, there is even more than one way to choose balls:
1. Choose balls with sizes 3, 4 and 5. 1. Choose balls with sizes 972, 970, 971.
| 500
|
[
{
"input": "4\n18 55 16 17",
"output": "YES"
},
{
"input": "6\n40 41 43 44 44 44",
"output": "NO"
},
{
"input": "8\n5 972 3 4 1 4 970 971",
"output": "YES"
},
{
"input": "3\n959 747 656",
"output": "NO"
},
{
"input": "4\n1 2 2 3",
"output": "YES"
},
{
"input": "50\n998 30 384 289 505 340 872 223 663 31 929 625 864 699 735 589 676 399 745 635 963 381 75 97 324 612 597 797 103 382 25 894 219 458 337 572 201 355 294 275 278 311 586 573 965 704 936 237 715 543",
"output": "NO"
},
{
"input": "50\n941 877 987 982 966 979 984 810 811 909 872 980 957 897 845 995 924 905 984 914 824 840 868 910 815 808 872 858 883 952 823 835 860 874 959 972 931 867 866 987 982 837 800 921 887 910 982 980 828 869",
"output": "YES"
},
{
"input": "3\n408 410 409",
"output": "YES"
},
{
"input": "3\n903 902 904",
"output": "YES"
},
{
"input": "3\n399 400 398",
"output": "YES"
},
{
"input": "3\n450 448 449",
"output": "YES"
},
{
"input": "3\n390 389 388",
"output": "YES"
},
{
"input": "3\n438 439 440",
"output": "YES"
},
{
"input": "11\n488 688 490 94 564 615 641 170 489 517 669",
"output": "YES"
},
{
"input": "24\n102 672 983 82 720 501 81 721 982 312 207 897 159 964 611 956 118 984 37 271 596 403 772 954",
"output": "YES"
},
{
"input": "36\n175 551 70 479 875 480 979 32 465 402 640 116 76 687 874 678 359 785 753 401 978 629 162 963 886 641 39 845 132 930 2 372 478 947 407 318",
"output": "YES"
},
{
"input": "6\n10 79 306 334 304 305",
"output": "YES"
},
{
"input": "34\n787 62 26 683 486 364 684 891 846 801 969 837 359 800 836 359 471 637 732 91 841 836 7 799 959 405 416 841 737 803 615 483 323 365",
"output": "YES"
},
{
"input": "30\n860 238 14 543 669 100 428 789 576 484 754 274 849 850 586 377 711 386 510 408 520 693 23 477 266 851 728 711 964 73",
"output": "YES"
},
{
"input": "11\n325 325 324 324 324 325 325 324 324 324 324",
"output": "NO"
},
{
"input": "7\n517 517 518 517 518 518 518",
"output": "NO"
},
{
"input": "20\n710 710 711 711 711 711 710 710 710 710 711 710 710 710 710 710 710 711 711 710",
"output": "NO"
},
{
"input": "48\n29 30 29 29 29 30 29 30 30 30 30 29 30 30 30 29 29 30 30 29 30 29 29 30 29 30 29 30 30 29 30 29 29 30 30 29 29 30 30 29 29 30 30 30 29 29 30 29",
"output": "NO"
},
{
"input": "7\n880 880 514 536 881 881 879",
"output": "YES"
},
{
"input": "15\n377 432 262 376 261 375 377 262 263 263 261 376 262 262 375",
"output": "YES"
},
{
"input": "32\n305 426 404 961 426 425 614 304 404 425 615 403 303 304 615 303 305 405 427 614 403 303 425 615 404 304 427 403 206 616 405 404",
"output": "YES"
},
{
"input": "41\n115 686 988 744 762 519 745 519 518 83 85 115 520 44 687 686 685 596 988 687 989 988 114 745 84 519 519 746 988 84 745 744 115 114 85 115 520 746 745 116 987",
"output": "YES"
},
{
"input": "47\n1 2 483 28 7 109 270 651 464 162 353 521 224 989 721 499 56 69 197 716 313 446 580 645 828 197 100 138 789 499 147 677 384 711 783 937 300 543 540 93 669 604 739 122 632 822 116",
"output": "NO"
},
{
"input": "31\n1 2 1 373 355 692 750 920 578 666 615 232 141 129 663 929 414 704 422 559 568 731 354 811 532 618 39 879 292 602 995",
"output": "NO"
},
{
"input": "50\n5 38 41 4 15 40 27 39 20 3 44 47 30 6 36 29 35 12 19 26 10 2 21 50 11 46 48 49 17 16 33 13 32 28 31 18 23 34 7 14 24 45 9 37 1 8 42 25 43 22",
"output": "YES"
},
{
"input": "50\n967 999 972 990 969 978 963 987 954 955 973 970 959 981 995 983 986 994 979 957 965 982 992 977 953 975 956 961 993 997 998 958 980 962 960 951 996 991 1000 966 971 988 976 968 989 984 974 964 985 952",
"output": "YES"
},
{
"input": "50\n850 536 761 506 842 898 857 723 583 637 536 943 895 929 890 612 832 633 696 731 553 880 710 812 665 877 915 636 711 540 748 600 554 521 813 796 568 513 543 809 798 820 928 504 999 646 907 639 550 911",
"output": "NO"
},
{
"input": "3\n3 1 2",
"output": "YES"
},
{
"input": "3\n500 999 1000",
"output": "NO"
},
{
"input": "10\n101 102 104 105 107 109 110 112 113 115",
"output": "NO"
},
{
"input": "50\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1",
"output": "NO"
},
{
"input": "50\n1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000 1000",
"output": "NO"
},
{
"input": "3\n1000 999 998",
"output": "YES"
},
{
"input": "49\n343 322 248 477 53 156 245 493 209 141 370 66 229 184 434 137 276 472 216 456 147 180 140 114 493 323 393 262 380 314 222 124 98 441 129 346 48 401 347 460 122 125 114 106 189 260 374 165 456",
"output": "NO"
},
{
"input": "20\n1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 3 3 3 3 3",
"output": "YES"
},
{
"input": "3\n999 999 1000",
"output": "NO"
},
{
"input": "9\n2 4 5 13 25 100 200 300 400",
"output": "NO"
},
{
"input": "9\n1 1 1 2 2 2 3 3 3",
"output": "YES"
},
{
"input": "3\n1 1 2",
"output": "NO"
},
{
"input": "3\n998 999 1000",
"output": "YES"
},
{
"input": "12\n1 1 1 1 1 1 1 1 1 2 2 4",
"output": "NO"
},
{
"input": "4\n4 3 4 5",
"output": "YES"
},
{
"input": "6\n1 1 1 2 2 2",
"output": "NO"
},
{
"input": "3\n2 3 2",
"output": "NO"
},
{
"input": "5\n10 5 6 3 2",
"output": "NO"
},
{
"input": "3\n1 2 1",
"output": "NO"
},
{
"input": "3\n1 2 3",
"output": "YES"
},
{
"input": "4\n998 999 1000 1000",
"output": "YES"
},
{
"input": "5\n2 3 9 9 4",
"output": "YES"
},
{
"input": "4\n1 2 4 4",
"output": "NO"
},
{
"input": "3\n1 1 1",
"output": "NO"
},
{
"input": "3\n2 2 3",
"output": "NO"
},
{
"input": "7\n1 2 2 2 4 5 6",
"output": "YES"
},
{
"input": "5\n1 3 10 3 10",
"output": "NO"
},
{
"input": "3\n1 2 2",
"output": "NO"
},
{
"input": "4\n1000 1000 999 998",
"output": "YES"
},
{
"input": "3\n5 3 7",
"output": "NO"
},
{
"input": "6\n1 1 2 2 3 3",
"output": "YES"
},
{
"input": "9\n6 6 6 5 5 5 4 4 4",
"output": "YES"
},
{
"input": "7\n5 6 6 6 7 7 7",
"output": "YES"
},
{
"input": "5\n2 3 3 3 4",
"output": "YES"
},
{
"input": "5\n2 1 2 1 3",
"output": "YES"
},
{
"input": "3\n1 2 7",
"output": "NO"
},
{
"input": "3\n1000 1000 1000",
"output": "NO"
},
{
"input": "5\n1 100 2 100 3",
"output": "YES"
},
{
"input": "5\n5 4 6 5 5",
"output": "YES"
},
{
"input": "12\n1 1 1 1 2 2 2 2 3 3 3 3",
"output": "YES"
},
{
"input": "5\n9 9 1 2 3",
"output": "YES"
},
{
"input": "6\n1 2 3 1 2 3",
"output": "YES"
},
{
"input": "7\n1 1 1 1 2 3 3",
"output": "YES"
},
{
"input": "3\n13 13 13",
"output": "NO"
},
{
"input": "3\n42 42 42",
"output": "NO"
},
{
"input": "8\n1 1 1 1 2 2 2 2",
"output": "NO"
},
{
"input": "6\n1 1 1 1 2 3",
"output": "YES"
},
{
"input": "6\n1 1 2 2 6 6",
"output": "NO"
},
{
"input": "6\n1 2 5 5 5 5",
"output": "NO"
},
{
"input": "9\n1 2 3 1 2 3 1 2 3",
"output": "YES"
},
{
"input": "4\n1 2 1 100",
"output": "NO"
},
{
"input": "5\n1 1 2 2 3",
"output": "YES"
}
] | 1,695,353,594
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 6
| 30
| 0
|
n = int(input())
*balls_sizes, = set(map(int,input().split()))
sorted_sizes = sorted(balls_sizes)
#print(sorted_sizes)
def checker(size):
if (sorted_sizes[size] + sorted_sizes[size+1] + sorted_sizes[size+2]) % 3 ==0:
return "YES"
for i in range(0,len(sorted_sizes)-2):
checked = checker(i)
if checked != "YES":
print("NO")
else:
print(checked)
|
Title: Bear and Three Balls
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Limak is a little polar bear. He has *n* balls, the *i*-th ball has size *t**i*.
Limak wants to give one ball to each of his three friends. Giving gifts isn't easy — there are two rules Limak must obey to make friends happy:
- No two friends can get balls of the same size. - No two friends can get balls of sizes that differ by more than 2.
For example, Limak can choose balls with sizes 4, 5 and 3, or balls with sizes 90, 91 and 92. But he can't choose balls with sizes 5, 5 and 6 (two friends would get balls of the same size), and he can't choose balls with sizes 30, 31 and 33 (because sizes 30 and 33 differ by more than 2).
Your task is to check whether Limak can choose three balls that satisfy conditions above.
Input Specification:
The first line of the input contains one integer *n* (3<=≤<=*n*<=≤<=50) — the number of balls Limak has.
The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=1000) where *t**i* denotes the size of the *i*-th ball.
Output Specification:
Print "YES" (without quotes) if Limak can choose three balls of distinct sizes, such that any two of them differ by no more than 2. Otherwise, print "NO" (without quotes).
Demo Input:
['4\n18 55 16 17\n', '6\n40 41 43 44 44 44\n', '8\n5 972 3 4 1 4 970 971\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n']
Note:
In the first sample, there are 4 balls and Limak is able to choose three of them to satisfy the rules. He must must choose balls with sizes 18, 16 and 17.
In the second sample, there is no way to give gifts to three friends without breaking the rules.
In the third sample, there is even more than one way to choose balls:
1. Choose balls with sizes 3, 4 and 5. 1. Choose balls with sizes 972, 970, 971.
|
```python
n = int(input())
*balls_sizes, = set(map(int,input().split()))
sorted_sizes = sorted(balls_sizes)
#print(sorted_sizes)
def checker(size):
if (sorted_sizes[size] + sorted_sizes[size+1] + sorted_sizes[size+2]) % 3 ==0:
return "YES"
for i in range(0,len(sorted_sizes)-2):
checked = checker(i)
if checked != "YES":
print("NO")
else:
print(checked)
```
| 0
|
|
813
|
B
|
The Golden Age
|
PROGRAMMING
| 1,800
|
[
"brute force",
"math"
] | null | null |
Unlucky year in Berland is such a year that its number *n* can be represented as *n*<==<=*x**a*<=+<=*y**b*, where *a* and *b* are non-negative integer numbers.
For example, if *x*<==<=2 and *y*<==<=3 then the years 4 and 17 are unlucky (4<==<=20<=+<=31, 17<==<=23<=+<=32<==<=24<=+<=30) and year 18 isn't unlucky as there is no such representation for it.
Such interval of years that there are no unlucky years in it is called The Golden Age.
You should write a program which will find maximum length of The Golden Age which starts no earlier than the year *l* and ends no later than the year *r*. If all years in the interval [*l*,<=*r*] are unlucky then the answer is 0.
|
The first line contains four integer numbers *x*, *y*, *l* and *r* (2<=≤<=*x*,<=*y*<=≤<=1018, 1<=≤<=*l*<=≤<=*r*<=≤<=1018).
|
Print the maximum length of The Golden Age within the interval [*l*,<=*r*].
If all years in the interval [*l*,<=*r*] are unlucky then print 0.
|
[
"2 3 1 10\n",
"3 5 10 22\n",
"2 3 3 5\n"
] |
[
"1\n",
"8\n",
"0\n"
] |
In the first example the unlucky years are 2, 3, 4, 5, 7, 9 and 10. So maximum length of The Golden Age is achived in the intervals [1, 1], [6, 6] and [8, 8].
In the second example the longest Golden Age is the interval [15, 22].
| 0
|
[
{
"input": "2 3 1 10",
"output": "1"
},
{
"input": "3 5 10 22",
"output": "8"
},
{
"input": "2 3 3 5",
"output": "0"
},
{
"input": "2 2 1 10",
"output": "1"
},
{
"input": "2 2 1 1000000",
"output": "213568"
},
{
"input": "2 2 1 1000000000000000000",
"output": "144115188075855871"
},
{
"input": "2 3 1 1000000",
"output": "206415"
},
{
"input": "2 3 1 1000000000000000000",
"output": "261485717957290893"
},
{
"input": "12345 54321 1 1000000",
"output": "933334"
},
{
"input": "54321 12345 1 1000000000000000000",
"output": "976614248345331214"
},
{
"input": "2 3 100000000 1000000000000",
"output": "188286357653"
},
{
"input": "2 14 732028847861235712 732028847861235712",
"output": "0"
},
{
"input": "14 2 732028847861235713 732028847861235713",
"output": "1"
},
{
"input": "3 2 6 7",
"output": "1"
},
{
"input": "16 5 821690667 821691481",
"output": "815"
},
{
"input": "1000000000000000000 2 1 1000000000000000000",
"output": "423539247696576511"
},
{
"input": "2 1000000000000000000 1000000000000000 1000000000000000000",
"output": "423539247696576511"
},
{
"input": "2 2 1000000000000000000 1000000000000000000",
"output": "1"
},
{
"input": "3 3 1 1",
"output": "1"
},
{
"input": "2 3 626492297402423196 726555387600422608",
"output": "100063090197999413"
},
{
"input": "4 4 1 1",
"output": "1"
},
{
"input": "304279187938024110 126610724244348052 78460471576735729 451077737144268785",
"output": "177668463693676057"
},
{
"input": "510000000000 510000000000 1 1000000000000000000",
"output": "999998980000000000"
},
{
"input": "2 10000000000000000 1 1000000000000000000",
"output": "413539247696576512"
},
{
"input": "84826654960259 220116531311479700 375314289098080160 890689132792406667",
"output": "515374843694326508"
},
{
"input": "1001 9999 1 1000000000000000000",
"output": "988998989390034998"
},
{
"input": "106561009498593483 3066011339919949 752858505287719337 958026822891358781",
"output": "205168317603639445"
},
{
"input": "650233444262690661 556292951587380938 715689923804218376 898772439356652923",
"output": "183082515552434548"
},
{
"input": "4294967297 4294967297 1 1000000000000000000",
"output": "999999991410065406"
},
{
"input": "1000000000000000000 1000000000000000000 1000000000000000000 1000000000000000000",
"output": "1"
},
{
"input": "2 2 1 1",
"output": "1"
},
{
"input": "73429332516742239 589598864615747534 555287238606698050 981268715519611449",
"output": "318240518387121676"
},
{
"input": "282060925969693883 446418005951342865 709861829378794811 826972744183396568",
"output": "98493812262359820"
},
{
"input": "97958277744315833 443452631396066615 33878596673318768 306383421710156519",
"output": "208425143965840685"
},
{
"input": "40975442958818854 7397733549114401 299774870238987084 658001214206968260",
"output": "358226343967981177"
},
{
"input": "699 700 1 1000",
"output": "697"
},
{
"input": "483076744475822225 425097332543006422 404961220953110704 826152774360856248",
"output": "343076029885034022"
},
{
"input": "4294967297 4294967297 1 999999999999999999",
"output": "999999991410065405"
},
{
"input": "702012794 124925148 2623100012 1000000000000000000",
"output": "491571744457491660"
},
{
"input": "433333986179614514 1000000000000000000 433333986179614515 726628630292055493",
"output": "293294644112440978"
},
{
"input": "999999999999999999 364973116927770629 4 4",
"output": "1"
},
{
"input": "4 2 40 812",
"output": "191"
},
{
"input": "2 3 1 1",
"output": "1"
},
{
"input": "1556368728 1110129598 120230736 1258235681",
"output": "989898863"
},
{
"input": "7 9 164249007852879073 459223650245359577",
"output": "229336748650748455"
},
{
"input": "324693328712373699 541961409169732375 513851377473048715 873677521504257312",
"output": "324693328712373697"
},
{
"input": "370083000139673112 230227213530985315 476750241623737312 746365058930029530",
"output": "146054845259371103"
},
{
"input": "4 3 584 899",
"output": "146"
},
{
"input": "4 3 286 581",
"output": "161"
},
{
"input": "304045744870965151 464630021384225732 142628934177558000 844155070300317027",
"output": "304045744870965149"
},
{
"input": "195627622825327857 666148746663834172 1 1000000000000000000",
"output": "470521123838506314"
},
{
"input": "459168731438725410 459955118458373596 410157890472128901 669197645706452507",
"output": "209242527248078910"
},
{
"input": "999999999999999999 999999999999999999 1 1000000000000000000",
"output": "999999999999999997"
},
{
"input": "752299248283963354 680566564599126819 73681814274367577 960486443362068685",
"output": "606884750324759243"
},
{
"input": "20373217421623606 233158243228114207 97091516440255589 395722640217125926",
"output": "142191179567388113"
},
{
"input": "203004070900 20036005000 1 1000000000000000000",
"output": "999999776959924100"
},
{
"input": "565269817339236857 318270460838647700 914534538271870694 956123707310168659",
"output": "41589169038297966"
},
{
"input": "2 5 330 669",
"output": "131"
},
{
"input": "9 9 91 547",
"output": "385"
},
{
"input": "9 4 866389615074294253 992899492208527253",
"output": "126509877134233001"
},
{
"input": "3037000500 3037000500 1 1000000000000000000",
"output": "999999993925999000"
},
{
"input": "4294967297 4294967297 12 1000000000000000000",
"output": "999999991410065406"
},
{
"input": "5 3 78510497842978003 917156799600023483",
"output": "238418579101562499"
},
{
"input": "749206377024033575 287723056504284448 387669391392789697 931234393488075794",
"output": "361536985631243879"
},
{
"input": "999999999999999999 454135 1000000000000000000 1000000000000000000",
"output": "0"
},
{
"input": "759826429841877401 105086867783910112 667080043736858072 797465019478234768",
"output": "92746386105019330"
},
{
"input": "1000000000000000000 1000000000000000000 5 7",
"output": "3"
},
{
"input": "440968000218771383 43378854522801881 169393324037146024 995429539593716237",
"output": "511082684852142973"
},
{
"input": "15049917793417622 113425474361704411 87565655389309185 803955352361026671",
"output": "675479960205904638"
},
{
"input": "4 6 264626841724745187 925995096479842591",
"output": "369878143059623936"
},
{
"input": "4294967297 4294967297 13 1000000000000000000",
"output": "999999991410065406"
},
{
"input": "315729630349763416 22614591055604717 66895291338255006 947444311481017774",
"output": "609100090075649641"
},
{
"input": "3 10 173 739",
"output": "386"
},
{
"input": "161309010783040325 128259041753158864 5843045875031294 854024306926137845",
"output": "564456254389938656"
},
{
"input": "239838434825939759 805278168279318096 202337849919104640 672893754916863788",
"output": "433055320090924028"
},
{
"input": "9 9 435779695685310822 697902619874412541",
"output": "262122924189101720"
},
{
"input": "967302429573451368 723751675006196376 143219686319239751 266477897142546404",
"output": "123258210823306654"
},
{
"input": "10 8 139979660652061677 941135332855173888",
"output": "697020144779318016"
},
{
"input": "4294967297 1000000000000000000 4294967296 17179869184",
"output": "12884901886"
},
{
"input": "100914030314340517 512922595840756536 812829791042966971 966156272123068006",
"output": "153326481080101036"
},
{
"input": "288230376151711744 288230376151711744 1 1000000000000000000",
"output": "423539247696576512"
},
{
"input": "6 9 681 750",
"output": "49"
},
{
"input": "880356874212472951 178538501711453307 162918237570625233 224969951233811739",
"output": "46431449522358431"
},
{
"input": "2 7 405373082004080437 771991379629433514",
"output": "153172782079203571"
},
{
"input": "10 11 10 11",
"output": "1"
}
] | 1,551,889,580
| 3,380
|
Python 3
|
RUNTIME_ERROR
|
TESTS
| 12
| 109
| 307,200
|
import math
import sys
a = list(map(int,input().split()))
x = a[0]
y = a[1]
l = a[2]
r = a[3]
v = []
for i in range(0, 61):
for j in range(0, 61):
if (x ** i + y ** j >= l) and (x ** i + y ** j <= r):
v.append(x ** i + y ** j)
maxi = 0
v.sort()
for i in range(1, len(v)):
maxi = max(maxi, v[i] - v[i - 1] - 1)
if not v.count(l):
maxi = max(maxi, v[0] - l)
if not v.count(r):
maxi = max(maxi, r - v[len(v) - 1])
print(maxi)
|
Title: The Golden Age
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Unlucky year in Berland is such a year that its number *n* can be represented as *n*<==<=*x**a*<=+<=*y**b*, where *a* and *b* are non-negative integer numbers.
For example, if *x*<==<=2 and *y*<==<=3 then the years 4 and 17 are unlucky (4<==<=20<=+<=31, 17<==<=23<=+<=32<==<=24<=+<=30) and year 18 isn't unlucky as there is no such representation for it.
Such interval of years that there are no unlucky years in it is called The Golden Age.
You should write a program which will find maximum length of The Golden Age which starts no earlier than the year *l* and ends no later than the year *r*. If all years in the interval [*l*,<=*r*] are unlucky then the answer is 0.
Input Specification:
The first line contains four integer numbers *x*, *y*, *l* and *r* (2<=≤<=*x*,<=*y*<=≤<=1018, 1<=≤<=*l*<=≤<=*r*<=≤<=1018).
Output Specification:
Print the maximum length of The Golden Age within the interval [*l*,<=*r*].
If all years in the interval [*l*,<=*r*] are unlucky then print 0.
Demo Input:
['2 3 1 10\n', '3 5 10 22\n', '2 3 3 5\n']
Demo Output:
['1\n', '8\n', '0\n']
Note:
In the first example the unlucky years are 2, 3, 4, 5, 7, 9 and 10. So maximum length of The Golden Age is achived in the intervals [1, 1], [6, 6] and [8, 8].
In the second example the longest Golden Age is the interval [15, 22].
|
```python
import math
import sys
a = list(map(int,input().split()))
x = a[0]
y = a[1]
l = a[2]
r = a[3]
v = []
for i in range(0, 61):
for j in range(0, 61):
if (x ** i + y ** j >= l) and (x ** i + y ** j <= r):
v.append(x ** i + y ** j)
maxi = 0
v.sort()
for i in range(1, len(v)):
maxi = max(maxi, v[i] - v[i - 1] - 1)
if not v.count(l):
maxi = max(maxi, v[0] - l)
if not v.count(r):
maxi = max(maxi, r - v[len(v) - 1])
print(maxi)
```
| -1
|
|
798
|
A
|
Mike and palindrome
|
PROGRAMMING
| 1,000
|
[
"brute force",
"constructive algorithms",
"strings"
] | null | null |
Mike has a string *s* consisting of only lowercase English letters. He wants to change exactly one character from the string so that the resulting one is a palindrome.
A palindrome is a string that reads the same backward as forward, for example strings "z", "aaa", "aba", "abccba" are palindromes, but strings "codeforces", "reality", "ab" are not.
|
The first and single line contains string *s* (1<=≤<=|*s*|<=≤<=15).
|
Print "YES" (without quotes) if Mike can change exactly one character so that the resulting string is palindrome or "NO" (without quotes) otherwise.
|
[
"abccaa\n",
"abbcca\n",
"abcda\n"
] |
[
"YES\n",
"NO\n",
"YES\n"
] |
none
| 500
|
[
{
"input": "abccaa",
"output": "YES"
},
{
"input": "abbcca",
"output": "NO"
},
{
"input": "abcda",
"output": "YES"
},
{
"input": "kyw",
"output": "YES"
},
{
"input": "fccf",
"output": "NO"
},
{
"input": "mnlm",
"output": "YES"
},
{
"input": "gqrk",
"output": "NO"
},
{
"input": "glxlg",
"output": "YES"
},
{
"input": "czhfc",
"output": "YES"
},
{
"input": "broon",
"output": "NO"
},
{
"input": "rmggmr",
"output": "NO"
},
{
"input": "wvxxzw",
"output": "YES"
},
{
"input": "ukvciu",
"output": "NO"
},
{
"input": "vrnwnrv",
"output": "YES"
},
{
"input": "vlkjkav",
"output": "YES"
},
{
"input": "guayhmg",
"output": "NO"
},
{
"input": "lkvhhvkl",
"output": "NO"
},
{
"input": "ffdsslff",
"output": "YES"
},
{
"input": "galjjtyw",
"output": "NO"
},
{
"input": "uosgwgsou",
"output": "YES"
},
{
"input": "qjwmjmljq",
"output": "YES"
},
{
"input": "ustrvrodf",
"output": "NO"
},
{
"input": "a",
"output": "YES"
},
{
"input": "qjfyjjyfjq",
"output": "NO"
},
{
"input": "ysxibbixsq",
"output": "YES"
},
{
"input": "howfslfwmh",
"output": "NO"
},
{
"input": "ekhajrjahke",
"output": "YES"
},
{
"input": "ucnolsloncw",
"output": "YES"
},
{
"input": "jrzsfrrkrtj",
"output": "NO"
},
{
"input": "typayzzyapyt",
"output": "NO"
},
{
"input": "uwdhkzokhdwu",
"output": "YES"
},
{
"input": "xokxpyyuafij",
"output": "NO"
},
{
"input": "eusneioiensue",
"output": "YES"
},
{
"input": "fuxpuajabpxuf",
"output": "YES"
},
{
"input": "guvggtfhlgruy",
"output": "NO"
},
{
"input": "cojhkhxxhkhjoc",
"output": "NO"
},
{
"input": "mhifbmmmmbmihm",
"output": "YES"
},
{
"input": "kxfqqncnebpami",
"output": "NO"
},
{
"input": "scfwrjevejrwfcs",
"output": "YES"
},
{
"input": "thdaonpepdoadht",
"output": "YES"
},
{
"input": "jsfzcbnhsccuqsj",
"output": "NO"
},
{
"input": "nn",
"output": "NO"
},
{
"input": "nm",
"output": "YES"
},
{
"input": "jdj",
"output": "YES"
},
{
"input": "bbcaa",
"output": "NO"
},
{
"input": "abcde",
"output": "NO"
},
{
"input": "abcdf",
"output": "NO"
},
{
"input": "aa",
"output": "NO"
},
{
"input": "abecd",
"output": "NO"
},
{
"input": "abccacb",
"output": "NO"
},
{
"input": "aabc",
"output": "NO"
},
{
"input": "anpqb",
"output": "NO"
},
{
"input": "c",
"output": "YES"
},
{
"input": "abcdefg",
"output": "NO"
},
{
"input": "aanbb",
"output": "NO"
},
{
"input": "aabbb",
"output": "NO"
},
{
"input": "aaabbab",
"output": "NO"
},
{
"input": "ab",
"output": "YES"
},
{
"input": "aabbc",
"output": "NO"
},
{
"input": "ecabd",
"output": "NO"
},
{
"input": "abcdrty",
"output": "NO"
},
{
"input": "abcdmnp",
"output": "NO"
},
{
"input": "bbbbbb",
"output": "NO"
},
{
"input": "abcxuio",
"output": "NO"
},
{
"input": "abcdabcde",
"output": "NO"
},
{
"input": "abcxpoi",
"output": "NO"
},
{
"input": "aba",
"output": "YES"
},
{
"input": "aacbb",
"output": "NO"
},
{
"input": "abcedca",
"output": "NO"
},
{
"input": "abcdd",
"output": "NO"
},
{
"input": "abbcs",
"output": "NO"
},
{
"input": "aaabccc",
"output": "NO"
},
{
"input": "paxkxbq",
"output": "NO"
},
{
"input": "z",
"output": "YES"
},
{
"input": "b",
"output": "YES"
},
{
"input": "abcdefghi",
"output": "NO"
},
{
"input": "abcqr",
"output": "NO"
},
{
"input": "abcdc",
"output": "NO"
},
{
"input": "abcb",
"output": "NO"
},
{
"input": "aabcd",
"output": "NO"
},
{
"input": "abbba",
"output": "YES"
},
{
"input": "aaabbb",
"output": "NO"
},
{
"input": "bb",
"output": "NO"
},
{
"input": "aaacbbb",
"output": "NO"
},
{
"input": "abbzcca",
"output": "NO"
},
{
"input": "abxab",
"output": "NO"
},
{
"input": "bbb",
"output": "YES"
},
{
"input": "abcrtyu",
"output": "NO"
},
{
"input": "cbacb",
"output": "NO"
},
{
"input": "acbb",
"output": "NO"
},
{
"input": "ww",
"output": "NO"
},
{
"input": "aaaaaa",
"output": "NO"
},
{
"input": "jizzz",
"output": "NO"
},
{
"input": "aaakcba",
"output": "NO"
},
{
"input": "acbak",
"output": "NO"
},
{
"input": "bddeffd",
"output": "NO"
},
{
"input": "aaa",
"output": "YES"
},
{
"input": "afghqwe",
"output": "NO"
},
{
"input": "abcdfga",
"output": "NO"
}
] | 1,649,548,174
| 2,147,483,647
|
PyPy 3-64
|
WRONG_ANSWER
|
TESTS
| 4
| 62
| 0
|
text = input()
back = text[::-1]
wrong = 0
for i in range(0, len(text)):
if text[i] != back[i]:
if len(text) % 2 == 1 and (len(text)//2)+1 == i-1:
wrong += 1
else:
wrong += .5
if wrong > 1:
break
if wrong > 1:
print("NO")
else:
print("YES")
|
Title: Mike and palindrome
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Mike has a string *s* consisting of only lowercase English letters. He wants to change exactly one character from the string so that the resulting one is a palindrome.
A palindrome is a string that reads the same backward as forward, for example strings "z", "aaa", "aba", "abccba" are palindromes, but strings "codeforces", "reality", "ab" are not.
Input Specification:
The first and single line contains string *s* (1<=≤<=|*s*|<=≤<=15).
Output Specification:
Print "YES" (without quotes) if Mike can change exactly one character so that the resulting string is palindrome or "NO" (without quotes) otherwise.
Demo Input:
['abccaa\n', 'abbcca\n', 'abcda\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n']
Note:
none
|
```python
text = input()
back = text[::-1]
wrong = 0
for i in range(0, len(text)):
if text[i] != back[i]:
if len(text) % 2 == 1 and (len(text)//2)+1 == i-1:
wrong += 1
else:
wrong += .5
if wrong > 1:
break
if wrong > 1:
print("NO")
else:
print("YES")
```
| 0
|
|
219
|
D
|
Choosing Capital for Treeland
|
PROGRAMMING
| 1,700
|
[
"dfs and similar",
"dp",
"graphs",
"trees"
] | null | null |
The country Treeland consists of *n* cities, some pairs of them are connected with unidirectional roads. Overall there are *n*<=-<=1 roads in the country. We know that if we don't take the direction of the roads into consideration, we can get from any city to any other one.
The council of the elders has recently decided to choose the capital of Treeland. Of course it should be a city of this country. The council is supposed to meet in the capital and regularly move from the capital to other cities (at this stage nobody is thinking about getting back to the capital from these cities). For that reason if city *a* is chosen a capital, then all roads must be oriented so that if we move along them, we can get from city *a* to any other city. For that some roads may have to be inversed.
Help the elders to choose the capital so that they have to inverse the minimum number of roads in the country.
|
The first input line contains integer *n* (2<=≤<=*n*<=≤<=2·105) — the number of cities in Treeland. Next *n*<=-<=1 lines contain the descriptions of the roads, one road per line. A road is described by a pair of integers *s**i*,<=*t**i* (1<=≤<=*s**i*,<=*t**i*<=≤<=*n*; *s**i*<=≠<=*t**i*) — the numbers of cities, connected by that road. The *i*-th road is oriented from city *s**i* to city *t**i*. You can consider cities in Treeland indexed from 1 to *n*.
|
In the first line print the minimum number of roads to be inversed if the capital is chosen optimally. In the second line print all possible ways to choose the capital — a sequence of indexes of cities in the increasing order.
|
[
"3\n2 1\n2 3\n",
"4\n1 4\n2 4\n3 4\n"
] |
[
"0\n2 \n",
"2\n1 2 3 \n"
] |
none
| 2,000
|
[
{
"input": "3\n2 1\n2 3",
"output": "0\n2 "
},
{
"input": "4\n1 4\n2 4\n3 4",
"output": "2\n1 2 3 "
},
{
"input": "2\n1 2",
"output": "0\n1 "
},
{
"input": "8\n1 2\n3 2\n4 3\n4 5\n6 5\n6 7\n8 7",
"output": "3\n4 6 8 "
},
{
"input": "10\n2 3\n1 8\n9 5\n5 4\n6 10\n4 8\n5 6\n7 6\n5 3",
"output": "3\n9 "
},
{
"input": "10\n9 3\n3 8\n4 3\n3 5\n7 8\n10 3\n2 3\n6 2\n3 1",
"output": "4\n6 "
},
{
"input": "10\n5 4\n6 5\n10 1\n2 5\n9 8\n1 3\n7 10\n2 3\n5 9",
"output": "2\n7 "
},
{
"input": "10\n2 3\n1 8\n9 5\n5 4\n6 10\n4 8\n5 6\n7 6\n5 3",
"output": "3\n9 "
},
{
"input": "11\n3 10\n4 7\n11 7\n8 2\n6 9\n9 3\n5 9\n1 3\n3 8\n7 3",
"output": "5\n4 5 6 11 "
},
{
"input": "12\n10 7\n6 10\n8 10\n4 12\n10 4\n3 12\n1 2\n2 7\n4 5\n11 5\n11 9",
"output": "5\n1 6 8 "
},
{
"input": "13\n7 13\n5 4\n5 1\n11 12\n8 3\n13 4\n10 7\n11 5\n8 13\n2 8\n10 6\n4 9",
"output": "4\n2 10 "
},
{
"input": "14\n13 10\n5 14\n9 4\n8 12\n10 1\n5 2\n3 6\n11 2\n13 2\n13 7\n8 2\n4 5\n1 3",
"output": "3\n9 "
},
{
"input": "15\n15 6\n2 15\n14 15\n15 12\n1 2\n10 15\n7 4\n13 7\n11 2\n5 2\n7 2\n3 2\n7 8\n9 15",
"output": "7\n13 "
}
] | 1,699,501,539
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 34
| 2,058
| 70,860,800
|
num_nodes = int(input())
time_array = [0] * (num_nodes + 1)
forward_edges, backward_edges = [[] for _ in range(num_nodes + 1)], [[] for _ in range(num_nodes + 1)]
for _ in range(num_nodes - 1):
x, y = map(int, input().split())
time_array[y] = 1
forward_edges[x].append(y)
backward_edges[y].append(x)
traversal_queue, leaf_count = forward_edges[1] + backward_edges[1], len(backward_edges[1])
for i in forward_edges[1]:
time_array[i] = 1
backward_edges[i].remove(1)
for i in backward_edges[1]:
time_array[i] = -1
forward_edges[i].remove(1)
while traversal_queue:
current_node = traversal_queue.pop()
for i in forward_edges[current_node]:
time_array[i] = time_array[current_node] + 1
backward_edges[i].remove(current_node)
for i in backward_edges[current_node]:
time_array[i] = time_array[current_node] - 1
forward_edges[i].remove(current_node)
traversal_queue += forward_edges[current_node] + backward_edges[current_node]
leaf_count += len(backward_edges[current_node])
min_time = min(time_array)
print(leaf_count + min_time)
print(' '.join(map(str, [i for i in range(1, num_nodes + 1) if time_array[i] == min_time])))
|
Title: Choosing Capital for Treeland
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The country Treeland consists of *n* cities, some pairs of them are connected with unidirectional roads. Overall there are *n*<=-<=1 roads in the country. We know that if we don't take the direction of the roads into consideration, we can get from any city to any other one.
The council of the elders has recently decided to choose the capital of Treeland. Of course it should be a city of this country. The council is supposed to meet in the capital and regularly move from the capital to other cities (at this stage nobody is thinking about getting back to the capital from these cities). For that reason if city *a* is chosen a capital, then all roads must be oriented so that if we move along them, we can get from city *a* to any other city. For that some roads may have to be inversed.
Help the elders to choose the capital so that they have to inverse the minimum number of roads in the country.
Input Specification:
The first input line contains integer *n* (2<=≤<=*n*<=≤<=2·105) — the number of cities in Treeland. Next *n*<=-<=1 lines contain the descriptions of the roads, one road per line. A road is described by a pair of integers *s**i*,<=*t**i* (1<=≤<=*s**i*,<=*t**i*<=≤<=*n*; *s**i*<=≠<=*t**i*) — the numbers of cities, connected by that road. The *i*-th road is oriented from city *s**i* to city *t**i*. You can consider cities in Treeland indexed from 1 to *n*.
Output Specification:
In the first line print the minimum number of roads to be inversed if the capital is chosen optimally. In the second line print all possible ways to choose the capital — a sequence of indexes of cities in the increasing order.
Demo Input:
['3\n2 1\n2 3\n', '4\n1 4\n2 4\n3 4\n']
Demo Output:
['0\n2 \n', '2\n1 2 3 \n']
Note:
none
|
```python
num_nodes = int(input())
time_array = [0] * (num_nodes + 1)
forward_edges, backward_edges = [[] for _ in range(num_nodes + 1)], [[] for _ in range(num_nodes + 1)]
for _ in range(num_nodes - 1):
x, y = map(int, input().split())
time_array[y] = 1
forward_edges[x].append(y)
backward_edges[y].append(x)
traversal_queue, leaf_count = forward_edges[1] + backward_edges[1], len(backward_edges[1])
for i in forward_edges[1]:
time_array[i] = 1
backward_edges[i].remove(1)
for i in backward_edges[1]:
time_array[i] = -1
forward_edges[i].remove(1)
while traversal_queue:
current_node = traversal_queue.pop()
for i in forward_edges[current_node]:
time_array[i] = time_array[current_node] + 1
backward_edges[i].remove(current_node)
for i in backward_edges[current_node]:
time_array[i] = time_array[current_node] - 1
forward_edges[i].remove(current_node)
traversal_queue += forward_edges[current_node] + backward_edges[current_node]
leaf_count += len(backward_edges[current_node])
min_time = min(time_array)
print(leaf_count + min_time)
print(' '.join(map(str, [i for i in range(1, num_nodes + 1) if time_array[i] == min_time])))
```
| 3
|
|
122
|
A
|
Lucky Division
|
PROGRAMMING
| 1,000
|
[
"brute force",
"number theory"
] | null | null |
Petya loves lucky numbers. Everybody knows that lucky numbers are positive integers whose decimal representation contains only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Petya calls a number almost lucky if it could be evenly divided by some lucky number. Help him find out if the given number *n* is almost lucky.
|
The single line contains an integer *n* (1<=≤<=*n*<=≤<=1000) — the number that needs to be checked.
|
In the only line print "YES" (without the quotes), if number *n* is almost lucky. Otherwise, print "NO" (without the quotes).
|
[
"47\n",
"16\n",
"78\n"
] |
[
"YES\n",
"YES\n",
"NO\n"
] |
Note that all lucky numbers are almost lucky as any number is evenly divisible by itself.
In the first sample 47 is a lucky number. In the second sample 16 is divisible by 4.
| 500
|
[
{
"input": "47",
"output": "YES"
},
{
"input": "16",
"output": "YES"
},
{
"input": "78",
"output": "NO"
},
{
"input": "48",
"output": "YES"
},
{
"input": "100",
"output": "YES"
},
{
"input": "107",
"output": "NO"
},
{
"input": "77",
"output": "YES"
},
{
"input": "477",
"output": "YES"
},
{
"input": "480",
"output": "YES"
},
{
"input": "1",
"output": "NO"
},
{
"input": "3",
"output": "NO"
},
{
"input": "4",
"output": "YES"
},
{
"input": "49",
"output": "YES"
},
{
"input": "56",
"output": "YES"
},
{
"input": "124",
"output": "YES"
},
{
"input": "1000",
"output": "YES"
},
{
"input": "999",
"output": "NO"
},
{
"input": "298",
"output": "NO"
},
{
"input": "274",
"output": "NO"
},
{
"input": "998",
"output": "NO"
},
{
"input": "42",
"output": "YES"
},
{
"input": "788",
"output": "YES"
},
{
"input": "70",
"output": "YES"
},
{
"input": "444",
"output": "YES"
},
{
"input": "777",
"output": "YES"
},
{
"input": "799",
"output": "YES"
},
{
"input": "25",
"output": "NO"
},
{
"input": "882",
"output": "YES"
},
{
"input": "88",
"output": "YES"
},
{
"input": "11",
"output": "NO"
},
{
"input": "2",
"output": "NO"
},
{
"input": "7",
"output": "YES"
},
{
"input": "8",
"output": "YES"
},
{
"input": "94",
"output": "YES"
},
{
"input": "477",
"output": "YES"
},
{
"input": "141",
"output": "YES"
}
] | 1,697,903,886
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS
| 36
| 124
| 0
|
n=int(input())
n1=str(n)
count=0
for digit in n1:
if digit=='4' or digit=='7':
count+=1
if count==len(n1) and count!=0:
print("YES")
elif (n%4==0 or n%7==0 or n%47==0 or n%74==0 or n%447==0 or n%474==0 or n%477==0 or n%747==0 or n%774==0):
print("YES")
else:
print("NO")
|
Title: Lucky Division
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya loves lucky numbers. Everybody knows that lucky numbers are positive integers whose decimal representation contains only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Petya calls a number almost lucky if it could be evenly divided by some lucky number. Help him find out if the given number *n* is almost lucky.
Input Specification:
The single line contains an integer *n* (1<=≤<=*n*<=≤<=1000) — the number that needs to be checked.
Output Specification:
In the only line print "YES" (without the quotes), if number *n* is almost lucky. Otherwise, print "NO" (without the quotes).
Demo Input:
['47\n', '16\n', '78\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n']
Note:
Note that all lucky numbers are almost lucky as any number is evenly divisible by itself.
In the first sample 47 is a lucky number. In the second sample 16 is divisible by 4.
|
```python
n=int(input())
n1=str(n)
count=0
for digit in n1:
if digit=='4' or digit=='7':
count+=1
if count==len(n1) and count!=0:
print("YES")
elif (n%4==0 or n%7==0 or n%47==0 or n%74==0 or n%447==0 or n%474==0 or n%477==0 or n%747==0 or n%774==0):
print("YES")
else:
print("NO")
```
| 3
|
|
761
|
A
|
Dasha and Stairs
|
PROGRAMMING
| 1,000
|
[
"brute force",
"constructive algorithms",
"implementation",
"math"
] | null | null |
On her way to programming school tiger Dasha faced her first test — a huge staircase!
The steps were numbered from one to infinity. As we know, tigers are very fond of all striped things, it is possible that it has something to do with their color. So on some interval of her way she calculated two values — the number of steps with even and odd numbers.
You need to check whether there is an interval of steps from the *l*-th to the *r*-th (1<=≤<=*l*<=≤<=*r*), for which values that Dasha has found are correct.
|
In the only line you are given two integers *a*, *b* (0<=≤<=*a*,<=*b*<=≤<=100) — the number of even and odd steps, accordingly.
|
In the only line print "YES", if the interval of steps described above exists, and "NO" otherwise.
|
[
"2 3\n",
"3 1\n"
] |
[
"YES\n",
"NO\n"
] |
In the first example one of suitable intervals is from 1 to 5. The interval contains two even steps — 2 and 4, and three odd: 1, 3 and 5.
| 500
|
[
{
"input": "2 3",
"output": "YES"
},
{
"input": "3 1",
"output": "NO"
},
{
"input": "5 4",
"output": "YES"
},
{
"input": "9 9",
"output": "YES"
},
{
"input": "85 95",
"output": "NO"
},
{
"input": "0 1",
"output": "YES"
},
{
"input": "89 25",
"output": "NO"
},
{
"input": "74 73",
"output": "YES"
},
{
"input": "62 39",
"output": "NO"
},
{
"input": "57 57",
"output": "YES"
},
{
"input": "100 99",
"output": "YES"
},
{
"input": "0 0",
"output": "NO"
},
{
"input": "98 100",
"output": "NO"
},
{
"input": "99 100",
"output": "YES"
},
{
"input": "1 0",
"output": "YES"
},
{
"input": "100 0",
"output": "NO"
},
{
"input": "0 100",
"output": "NO"
},
{
"input": "100 98",
"output": "NO"
},
{
"input": "100 100",
"output": "YES"
},
{
"input": "0 5",
"output": "NO"
},
{
"input": "2 2",
"output": "YES"
}
] | 1,533,036,312
| 2,147,483,647
|
Python 3
|
WRONG_ANSWER
|
TESTS
| 11
| 109
| 0
|
t = list(map(int,input().split()))
a = t[0]
b = t[1]
if abs(a - b) <= 1:
print("YES")
else:
print("NO")
|
Title: Dasha and Stairs
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
On her way to programming school tiger Dasha faced her first test — a huge staircase!
The steps were numbered from one to infinity. As we know, tigers are very fond of all striped things, it is possible that it has something to do with their color. So on some interval of her way she calculated two values — the number of steps with even and odd numbers.
You need to check whether there is an interval of steps from the *l*-th to the *r*-th (1<=≤<=*l*<=≤<=*r*), for which values that Dasha has found are correct.
Input Specification:
In the only line you are given two integers *a*, *b* (0<=≤<=*a*,<=*b*<=≤<=100) — the number of even and odd steps, accordingly.
Output Specification:
In the only line print "YES", if the interval of steps described above exists, and "NO" otherwise.
Demo Input:
['2 3\n', '3 1\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first example one of suitable intervals is from 1 to 5. The interval contains two even steps — 2 and 4, and three odd: 1, 3 and 5.
|
```python
t = list(map(int,input().split()))
a = t[0]
b = t[1]
if abs(a - b) <= 1:
print("YES")
else:
print("NO")
```
| 0
|
|
0
|
none
|
none
|
none
| 0
|
[
"none"
] | null | null |
Students went into a class to write a test and sat in some way. The teacher thought: "Probably they sat in this order to copy works of each other. I need to rearrange them in such a way that students that were neighbors are not neighbors in a new seating."
The class can be represented as a matrix with *n* rows and *m* columns with a student in each cell. Two students are neighbors if cells in which they sit have a common side.
Let's enumerate students from 1 to *n*·*m* in order of rows. So a student who initially sits in the cell in row *i* and column *j* has a number (*i*<=-<=1)·*m*<=+<=*j*. You have to find a matrix with *n* rows and *m* columns in which all numbers from 1 to *n*·*m* appear exactly once and adjacent numbers in the original matrix are not adjacent in it, or determine that there is no such matrix.
|
The only line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=105; *n*·*m*<=≤<=105) — the number of rows and the number of columns in the required matrix.
|
If there is no such matrix, output "NO" (without quotes).
Otherwise in the first line output "YES" (without quotes), and in the next *n* lines output *m* integers which form the required matrix.
|
[
"2 4\n",
"2 1\n"
] |
[
"YES\n5 4 7 2 \n3 6 1 8 \n",
"NO\n"
] |
In the first test case the matrix initially looks like this:
It's easy to see that there are no two students that are adjacent in both matrices.
In the second test case there are only two possible seatings and in both of them students with numbers 1 and 2 are neighbors.
| 0
|
[
{
"input": "2 4",
"output": "YES\n5 4 7 2 \n3 6 1 8 "
},
{
"input": "2 1",
"output": "NO"
},
{
"input": "1 1",
"output": "YES\n1"
},
{
"input": "1 2",
"output": "NO"
},
{
"input": "1 3",
"output": "NO"
},
{
"input": "2 2",
"output": "NO"
},
{
"input": "2 3",
"output": "NO"
},
{
"input": "3 1",
"output": "NO"
},
{
"input": "3 2",
"output": "NO"
},
{
"input": "3 3",
"output": "YES\n6 1 8\n7 5 3\n2 9 4"
},
{
"input": "1 4",
"output": "YES\n2 4 1 3"
},
{
"input": "4 1",
"output": "YES\n2\n4\n1\n3"
},
{
"input": "4 2",
"output": "YES\n2 5 \n7 4 \n6 1 \n3 8 "
},
{
"input": "1 100000",
"output": "YES\n1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 61 63 65 67 69 71 73 75 77 79 81 83 85 87 89 91 93 95 97 99 101 103 105 107 109 111 113 115 117 119 121 123 125 127 129 131 133 135 137 139 141 143 145 147 149 151 153 155 157 159 161 163 165 167 169 171 173 175 177 179 181 183 185 187 189 191 193 195 197 199 201 203 205 207 209 211 213 215 217 219 221 223 225 227 229 231 233 235 237 239 241 243 245 247 249 251 253 255 257 259 261 263 265 267 269 271 273 275 277 279 2..."
},
{
"input": "100000 1",
"output": "YES\n1\n3\n5\n7\n9\n11\n13\n15\n17\n19\n21\n23\n25\n27\n29\n31\n33\n35\n37\n39\n41\n43\n45\n47\n49\n51\n53\n55\n57\n59\n61\n63\n65\n67\n69\n71\n73\n75\n77\n79\n81\n83\n85\n87\n89\n91\n93\n95\n97\n99\n101\n103\n105\n107\n109\n111\n113\n115\n117\n119\n121\n123\n125\n127\n129\n131\n133\n135\n137\n139\n141\n143\n145\n147\n149\n151\n153\n155\n157\n159\n161\n163\n165\n167\n169\n171\n173\n175\n177\n179\n181\n183\n185\n187\n189\n191\n193\n195\n197\n199\n201\n203\n205\n207\n209\n211\n213\n215\n217\n219\n221\n223\n2..."
},
{
"input": "316 316",
"output": "YES\n317 4 319 6 321 8 323 10 325 12 327 14 329 16 331 18 333 20 335 22 337 24 339 26 341 28 343 30 345 32 347 34 349 36 351 38 353 40 355 42 357 44 359 46 361 48 363 50 365 52 367 54 369 56 371 58 373 60 375 62 377 64 379 66 381 68 383 70 385 72 387 74 389 76 391 78 393 80 395 82 397 84 399 86 401 88 403 90 405 92 407 94 409 96 411 98 413 100 415 102 417 104 419 106 421 108 423 110 425 112 427 114 429 116 431 118 433 120 435 122 437 124 439 126 441 128 443 130 445 132 447 134 449 136 451 138 453 140 455 1..."
},
{
"input": "315 316",
"output": "YES\n317 4 319 6 321 8 323 10 325 12 327 14 329 16 331 18 333 20 335 22 337 24 339 26 341 28 343 30 345 32 347 34 349 36 351 38 353 40 355 42 357 44 359 46 361 48 363 50 365 52 367 54 369 56 371 58 373 60 375 62 377 64 379 66 381 68 383 70 385 72 387 74 389 76 391 78 393 80 395 82 397 84 399 86 401 88 403 90 405 92 407 94 409 96 411 98 413 100 415 102 417 104 419 106 421 108 423 110 425 112 427 114 429 116 431 118 433 120 435 122 437 124 439 126 441 128 443 130 445 132 447 134 449 136 451 138 453 140 455 1..."
},
{
"input": "316 315",
"output": "YES\n2 633 4 635 6 637 8 639 10 641 12 643 14 645 16 647 18 649 20 651 22 653 24 655 26 657 28 659 30 661 32 663 34 665 36 667 38 669 40 671 42 673 44 675 46 677 48 679 50 681 52 683 54 685 56 687 58 689 60 691 62 693 64 695 66 697 68 699 70 701 72 703 74 705 76 707 78 709 80 711 82 713 84 715 86 717 88 719 90 721 92 723 94 725 96 727 98 729 100 731 102 733 104 735 106 737 108 739 110 741 112 743 114 745 116 747 118 749 120 751 122 753 124 755 126 757 128 759 130 761 132 763 134 765 136 767 138 769 140 771..."
},
{
"input": "315 315",
"output": "YES\n316 4 318 6 320 8 322 10 324 12 326 14 328 16 330 18 332 20 334 22 336 24 338 26 340 28 342 30 344 32 346 34 348 36 350 38 352 40 354 42 356 44 358 46 360 48 362 50 364 52 366 54 368 56 370 58 372 60 374 62 376 64 378 66 380 68 382 70 384 72 386 74 388 76 390 78 392 80 394 82 396 84 398 86 400 88 402 90 404 92 406 94 408 96 410 98 412 100 414 102 416 104 418 106 420 108 422 110 424 112 426 114 428 116 430 118 432 120 434 122 436 124 438 126 440 128 442 130 444 132 446 134 448 136 450 138 452 140 454 1..."
},
{
"input": "100 1000",
"output": "YES\n1001 4 1003 6 1005 8 1007 10 1009 12 1011 14 1013 16 1015 18 1017 20 1019 22 1021 24 1023 26 1025 28 1027 30 1029 32 1031 34 1033 36 1035 38 1037 40 1039 42 1041 44 1043 46 1045 48 1047 50 1049 52 1051 54 1053 56 1055 58 1057 60 1059 62 1061 64 1063 66 1065 68 1067 70 1069 72 1071 74 1073 76 1075 78 1077 80 1079 82 1081 84 1083 86 1085 88 1087 90 1089 92 1091 94 1093 96 1095 98 1097 100 1099 102 1101 104 1103 106 1105 108 1107 110 1109 112 1111 114 1113 116 1115 118 1117 120 1119 122 1121 124 1123 126..."
},
{
"input": "1000 100",
"output": "YES\n2 203 4 205 6 207 8 209 10 211 12 213 14 215 16 217 18 219 20 221 22 223 24 225 26 227 28 229 30 231 32 233 34 235 36 237 38 239 40 241 42 243 44 245 46 247 48 249 50 251 52 253 54 255 56 257 58 259 60 261 62 263 64 265 66 267 68 269 70 271 72 273 74 275 76 277 78 279 80 281 82 283 84 285 86 287 88 289 90 291 92 293 94 295 96 297 98 299 100 201 \n301 102 303 104 305 106 307 108 309 110 311 112 313 114 315 116 317 118 319 120 321 122 323 124 325 126 327 128 329 130 331 132 333 134 335 136 337 138 339 1..."
},
{
"input": "10 10000",
"output": "YES\n10001 4 10003 6 10005 8 10007 10 10009 12 10011 14 10013 16 10015 18 10017 20 10019 22 10021 24 10023 26 10025 28 10027 30 10029 32 10031 34 10033 36 10035 38 10037 40 10039 42 10041 44 10043 46 10045 48 10047 50 10049 52 10051 54 10053 56 10055 58 10057 60 10059 62 10061 64 10063 66 10065 68 10067 70 10069 72 10071 74 10073 76 10075 78 10077 80 10079 82 10081 84 10083 86 10085 88 10087 90 10089 92 10091 94 10093 96 10095 98 10097 100 10099 102 10101 104 10103 106 10105 108 10107 110 10109 112 10111 1..."
},
{
"input": "10000 10",
"output": "YES\n2 23 4 25 6 27 8 29 10 21 \n31 12 33 14 35 16 37 18 39 20 \n22 43 24 45 26 47 28 49 30 41 \n51 32 53 34 55 36 57 38 59 40 \n42 63 44 65 46 67 48 69 50 61 \n71 52 73 54 75 56 77 58 79 60 \n62 83 64 85 66 87 68 89 70 81 \n91 72 93 74 95 76 97 78 99 80 \n82 103 84 105 86 107 88 109 90 101 \n111 92 113 94 115 96 117 98 119 100 \n102 123 104 125 106 127 108 129 110 121 \n131 112 133 114 135 116 137 118 139 120 \n122 143 124 145 126 147 128 149 130 141 \n151 132 153 134 155 136 157 138 159 140 \n142 163 144..."
},
{
"input": "100 1",
"output": "YES\n1\n3\n5\n7\n9\n11\n13\n15\n17\n19\n21\n23\n25\n27\n29\n31\n33\n35\n37\n39\n41\n43\n45\n47\n49\n51\n53\n55\n57\n59\n61\n63\n65\n67\n69\n71\n73\n75\n77\n79\n81\n83\n85\n87\n89\n91\n93\n95\n97\n99\n2\n4\n6\n8\n10\n12\n14\n16\n18\n20\n22\n24\n26\n28\n30\n32\n34\n36\n38\n40\n42\n44\n46\n48\n50\n52\n54\n56\n58\n60\n62\n64\n66\n68\n70\n72\n74\n76\n78\n80\n82\n84\n86\n88\n90\n92\n94\n96\n98\n100"
},
{
"input": "1 100",
"output": "YES\n1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 61 63 65 67 69 71 73 75 77 79 81 83 85 87 89 91 93 95 97 99 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 66 68 70 72 74 76 78 80 82 84 86 88 90 92 94 96 98 100 "
},
{
"input": "100 2",
"output": "YES\n2 5 \n7 4 \n6 9 \n11 8 \n10 13 \n15 12 \n14 17 \n19 16 \n18 21 \n23 20 \n22 25 \n27 24 \n26 29 \n31 28 \n30 33 \n35 32 \n34 37 \n39 36 \n38 41 \n43 40 \n42 45 \n47 44 \n46 49 \n51 48 \n50 53 \n55 52 \n54 57 \n59 56 \n58 61 \n63 60 \n62 65 \n67 64 \n66 69 \n71 68 \n70 73 \n75 72 \n74 77 \n79 76 \n78 81 \n83 80 \n82 85 \n87 84 \n86 89 \n91 88 \n90 93 \n95 92 \n94 97 \n99 96 \n98 101 \n103 100 \n102 105 \n107 104 \n106 109 \n111 108 \n110 113 \n115 112 \n114 117 \n119 116 \n118 121 \n123 120 \n122 125 \n..."
},
{
"input": "2 100",
"output": "YES\n101 4 103 6 105 8 107 10 109 12 111 14 113 16 115 18 117 20 119 22 121 24 123 26 125 28 127 30 129 32 131 34 133 36 135 38 137 40 139 42 141 44 143 46 145 48 147 50 149 52 151 54 153 56 155 58 157 60 159 62 161 64 163 66 165 68 167 70 169 72 171 74 173 76 175 78 177 80 179 82 181 84 183 86 185 88 187 90 189 92 191 94 193 96 195 98 197 100 199 2 \n3 102 5 104 7 106 9 108 11 110 13 112 15 114 17 116 19 118 21 120 23 122 25 124 27 126 29 128 31 130 33 132 35 134 37 136 39 138 41 140 43 142 45 144 47 146 ..."
},
{
"input": "100 3",
"output": "YES\n2 9 7 \n10 5 12 \n8 15 13 \n16 11 18 \n14 21 19 \n22 17 24 \n20 27 25 \n28 23 30 \n26 33 31 \n34 29 36 \n32 39 37 \n40 35 42 \n38 45 43 \n46 41 48 \n44 51 49 \n52 47 54 \n50 57 55 \n58 53 60 \n56 63 61 \n64 59 66 \n62 69 67 \n70 65 72 \n68 75 73 \n76 71 78 \n74 81 79 \n82 77 84 \n80 87 85 \n88 83 90 \n86 93 91 \n94 89 96 \n92 99 97 \n100 95 102 \n98 105 103 \n106 101 108 \n104 111 109 \n112 107 114 \n110 117 115 \n118 113 120 \n116 123 121 \n124 119 126 \n122 129 127 \n130 125 132 \n128 135 133 \n136 ..."
},
{
"input": "3 100",
"output": "YES\n101 4 103 6 105 8 107 10 109 12 111 14 113 16 115 18 117 20 119 22 121 24 123 26 125 28 127 30 129 32 131 34 133 36 135 38 137 40 139 42 141 44 143 46 145 48 147 50 149 52 151 54 153 56 155 58 157 60 159 62 161 64 163 66 165 68 167 70 169 72 171 74 173 76 175 78 177 80 179 82 181 84 183 86 185 88 187 90 189 92 191 94 193 96 195 98 197 100 199 2 \n203 102 205 104 207 106 209 108 211 110 213 112 215 114 217 116 219 118 221 120 223 122 225 124 227 126 229 128 231 130 233 132 235 134 237 136 239 138 241 1..."
},
{
"input": "100 4",
"output": "YES\n2 11 4 9 \n13 6 15 8 \n10 19 12 17 \n21 14 23 16 \n18 27 20 25 \n29 22 31 24 \n26 35 28 33 \n37 30 39 32 \n34 43 36 41 \n45 38 47 40 \n42 51 44 49 \n53 46 55 48 \n50 59 52 57 \n61 54 63 56 \n58 67 60 65 \n69 62 71 64 \n66 75 68 73 \n77 70 79 72 \n74 83 76 81 \n85 78 87 80 \n82 91 84 89 \n93 86 95 88 \n90 99 92 97 \n101 94 103 96 \n98 107 100 105 \n109 102 111 104 \n106 115 108 113 \n117 110 119 112 \n114 123 116 121 \n125 118 127 120 \n122 131 124 129 \n133 126 135 128 \n130 139 132 137 \n141 134 143 ..."
},
{
"input": "4 100",
"output": "YES\n101 4 103 6 105 8 107 10 109 12 111 14 113 16 115 18 117 20 119 22 121 24 123 26 125 28 127 30 129 32 131 34 133 36 135 38 137 40 139 42 141 44 143 46 145 48 147 50 149 52 151 54 153 56 155 58 157 60 159 62 161 64 163 66 165 68 167 70 169 72 171 74 173 76 175 78 177 80 179 82 181 84 183 86 185 88 187 90 189 92 191 94 193 96 195 98 197 100 199 2 \n203 102 205 104 207 106 209 108 211 110 213 112 215 114 217 116 219 118 221 120 223 122 225 124 227 126 229 128 231 130 233 132 235 134 237 136 239 138 241 1..."
},
{
"input": "101 1",
"output": "YES\n1\n3\n5\n7\n9\n11\n13\n15\n17\n19\n21\n23\n25\n27\n29\n31\n33\n35\n37\n39\n41\n43\n45\n47\n49\n51\n53\n55\n57\n59\n61\n63\n65\n67\n69\n71\n73\n75\n77\n79\n81\n83\n85\n87\n89\n91\n93\n95\n97\n99\n101\n2\n4\n6\n8\n10\n12\n14\n16\n18\n20\n22\n24\n26\n28\n30\n32\n34\n36\n38\n40\n42\n44\n46\n48\n50\n52\n54\n56\n58\n60\n62\n64\n66\n68\n70\n72\n74\n76\n78\n80\n82\n84\n86\n88\n90\n92\n94\n96\n98\n100"
},
{
"input": "1 101",
"output": "YES\n1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 43 45 47 49 51 53 55 57 59 61 63 65 67 69 71 73 75 77 79 81 83 85 87 89 91 93 95 97 99 101 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48 50 52 54 56 58 60 62 64 66 68 70 72 74 76 78 80 82 84 86 88 90 92 94 96 98 100 "
},
{
"input": "101 2",
"output": "YES\n2 5 \n7 4 \n6 9 \n11 8 \n10 13 \n15 12 \n14 17 \n19 16 \n18 21 \n23 20 \n22 25 \n27 24 \n26 29 \n31 28 \n30 33 \n35 32 \n34 37 \n39 36 \n38 41 \n43 40 \n42 45 \n47 44 \n46 49 \n51 48 \n50 53 \n55 52 \n54 57 \n59 56 \n58 61 \n63 60 \n62 65 \n67 64 \n66 69 \n71 68 \n70 73 \n75 72 \n74 77 \n79 76 \n78 81 \n83 80 \n82 85 \n87 84 \n86 89 \n91 88 \n90 93 \n95 92 \n94 97 \n99 96 \n98 101 \n103 100 \n102 105 \n107 104 \n106 109 \n111 108 \n110 113 \n115 112 \n114 117 \n119 116 \n118 121 \n123 120 \n122 125 \n..."
},
{
"input": "2 101",
"output": "YES\n102 4 104 6 106 8 108 10 110 12 112 14 114 16 116 18 118 20 120 22 122 24 124 26 126 28 128 30 130 32 132 34 134 36 136 38 138 40 140 42 142 44 144 46 146 48 148 50 150 52 152 54 154 56 156 58 158 60 160 62 162 64 164 66 166 68 168 70 170 72 172 74 174 76 176 78 178 80 180 82 182 84 184 86 186 88 188 90 190 92 192 94 194 96 196 98 198 100 200 1 202 \n3 103 5 105 7 107 9 109 11 111 13 113 15 115 17 117 19 119 21 121 23 123 25 125 27 127 29 129 31 131 33 133 35 135 37 137 39 139 41 141 43 143 45 145 47 ..."
},
{
"input": "101 3",
"output": "YES\n2 9 7 \n10 5 12 \n8 15 13 \n16 11 18 \n14 21 19 \n22 17 24 \n20 27 25 \n28 23 30 \n26 33 31 \n34 29 36 \n32 39 37 \n40 35 42 \n38 45 43 \n46 41 48 \n44 51 49 \n52 47 54 \n50 57 55 \n58 53 60 \n56 63 61 \n64 59 66 \n62 69 67 \n70 65 72 \n68 75 73 \n76 71 78 \n74 81 79 \n82 77 84 \n80 87 85 \n88 83 90 \n86 93 91 \n94 89 96 \n92 99 97 \n100 95 102 \n98 105 103 \n106 101 108 \n104 111 109 \n112 107 114 \n110 117 115 \n118 113 120 \n116 123 121 \n124 119 126 \n122 129 127 \n130 125 132 \n128 135 133 \n136 ..."
},
{
"input": "3 101",
"output": "YES\n102 4 104 6 106 8 108 10 110 12 112 14 114 16 116 18 118 20 120 22 122 24 124 26 126 28 128 30 130 32 132 34 134 36 136 38 138 40 140 42 142 44 144 46 146 48 148 50 150 52 152 54 154 56 156 58 158 60 160 62 162 64 164 66 166 68 168 70 170 72 172 74 174 76 176 78 178 80 180 82 182 84 184 86 186 88 188 90 190 92 192 94 194 96 196 98 198 100 200 1 202 \n205 103 207 105 209 107 211 109 213 111 215 113 217 115 219 117 221 119 223 121 225 123 227 125 229 127 231 129 233 131 235 133 237 135 239 137 241 139 2..."
},
{
"input": "101 4",
"output": "YES\n2 11 4 9 \n13 6 15 8 \n10 19 12 17 \n21 14 23 16 \n18 27 20 25 \n29 22 31 24 \n26 35 28 33 \n37 30 39 32 \n34 43 36 41 \n45 38 47 40 \n42 51 44 49 \n53 46 55 48 \n50 59 52 57 \n61 54 63 56 \n58 67 60 65 \n69 62 71 64 \n66 75 68 73 \n77 70 79 72 \n74 83 76 81 \n85 78 87 80 \n82 91 84 89 \n93 86 95 88 \n90 99 92 97 \n101 94 103 96 \n98 107 100 105 \n109 102 111 104 \n106 115 108 113 \n117 110 119 112 \n114 123 116 121 \n125 118 127 120 \n122 131 124 129 \n133 126 135 128 \n130 139 132 137 \n141 134 143 ..."
},
{
"input": "4 101",
"output": "YES\n102 4 104 6 106 8 108 10 110 12 112 14 114 16 116 18 118 20 120 22 122 24 124 26 126 28 128 30 130 32 132 34 134 36 136 38 138 40 140 42 142 44 144 46 146 48 148 50 150 52 152 54 154 56 156 58 158 60 160 62 162 64 164 66 166 68 168 70 170 72 172 74 174 76 176 78 178 80 180 82 182 84 184 86 186 88 188 90 190 92 192 94 194 96 196 98 198 100 200 1 202 \n205 103 207 105 209 107 211 109 213 111 215 113 217 115 219 117 221 119 223 121 225 123 227 125 229 127 231 129 233 131 235 133 237 135 239 137 241 139 2..."
},
{
"input": "6 16666",
"output": "YES\n16667 4 16669 6 16671 8 16673 10 16675 12 16677 14 16679 16 16681 18 16683 20 16685 22 16687 24 16689 26 16691 28 16693 30 16695 32 16697 34 16699 36 16701 38 16703 40 16705 42 16707 44 16709 46 16711 48 16713 50 16715 52 16717 54 16719 56 16721 58 16723 60 16725 62 16727 64 16729 66 16731 68 16733 70 16735 72 16737 74 16739 76 16741 78 16743 80 16745 82 16747 84 16749 86 16751 88 16753 90 16755 92 16757 94 16759 96 16761 98 16763 100 16765 102 16767 104 16769 106 16771 108 16773 110 16775 112 16777 1..."
},
{
"input": "314 315",
"output": "YES\n316 4 318 6 320 8 322 10 324 12 326 14 328 16 330 18 332 20 334 22 336 24 338 26 340 28 342 30 344 32 346 34 348 36 350 38 352 40 354 42 356 44 358 46 360 48 362 50 364 52 366 54 368 56 370 58 372 60 374 62 376 64 378 66 380 68 382 70 384 72 386 74 388 76 390 78 392 80 394 82 396 84 398 86 400 88 402 90 404 92 406 94 408 96 410 98 412 100 414 102 416 104 418 106 420 108 422 110 424 112 426 114 428 116 430 118 432 120 434 122 436 124 438 126 440 128 442 130 444 132 446 134 448 136 450 138 452 140 454 1..."
},
{
"input": "2 20",
"output": "YES\n21 4 23 6 25 8 27 10 29 12 31 14 33 16 35 18 37 20 39 2 \n3 22 5 24 7 26 9 28 11 30 13 32 15 34 17 36 19 38 1 40 "
}
] | 1,514,048,564
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
#define _CRT_SECURE_NO_DEPRECATE
#pragma comment(linker, "/STACK:102400000,102400000")
#include<iostream>
#include<cstdio>
#include<fstream>
#include<iomanip>
#include<algorithm>
#include<cmath>
#include<deque>
#include<vector>
#include<bitset>
#include<queue>
#include<string>
#include<cstring>
#include<map>
#include<stack>
#include<set>
#include<functional>
#define pii pair<int, int>
#define mod 1000000007
#define mp make_pair
#define pi acos(-1)
#define eps 0.00000001
#define mst(a,i) memset(a,i,sizeof(a))
#define all(n) n.begin(),n.end()
#define lson(x) ((x<<1))
#define rson(x) ((x<<1)|1)
#define inf 0x3f3f3f3f
typedef long long ll;
typedef unsigned long long ull;
using namespace std;
const int maxn = 1e5 + 5;
vector<int>a[maxn];
vector<int>ans[maxn];
int n, m;
void change2(int t)
{
ans[t].resize(m+1);
ans[t + 1].resize(m+1);
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t][i] = a[t][i];
else ans[t + 1][i] = a[t][i];
}
ans[t][2] = a[t + 1][m];
ans[t + 1][1] = a[t + 1][m - 1];
for (int i = 3; i <= m; ++i)
{
if (i & 1)ans[t + 1][i] = a[t+1][i-2];
else ans[t][i] = a[t + 1][i-2];
}
}
void change3(int t)
{
ans[t].resize(m+1);
ans[t + 1].resize(m+1);
ans[t + 2].resize(m+1);
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t][i] = a[t][i];
else ans[t + 2][i] = a[t][i];
}
ans[t][2] = a[t + 1][m];
ans[t + 1][1] = a[t + 1][m - 1];
for (int i = 3; i <= m; ++i)
{
if (i & 1)ans[t + 1][i] = a[t + 1][i - 2];
else ans[t][i] = a[t + 1][i - 2];
}
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t+2][i] = a[t + 2][i];
else ans[t + 1][i] = a[t + 2][i];
}
}
int main()
{
ios::sync_with_stdio(false);
cin.tie(0); cout.tie(0);
int i, j, k;
cin >> n >> m;
if (n == 3 && m == 3)
{
cout << "YES" << endl;
cout << "1 7 3" << endl;
cout << "9 2 5" << endl;
cout << "4 8 6" << endl;
return 0;
}
if (n == 1 && m == 1)
{
cout << "YES" << endl;
cout << "1" << endl;
return 0;
}
if ((n <= 2 && m <= 2) || n == 1 || m == 1 || n + m == 5) { cout << "NO" << endl; return 0; }
if (n <= m)
{
for (int i = 1; i <= n; ++i)
{
a[i].push_back(123);
for (int j = 1; j <= m; ++j)
a[i].push_back((i - 1)*m + j);
}
if (n % 2 == 0)
{
for (int i = 1; i <= n; i += 2)
change2(i);
}
else
{
for (int i = 1; i <= n - 3; i += 2)
change2(i);
change3(n - 2);
}
cout << "YES" << endl;
for (int i = 1; i <= n; ++i)
{
for (int j = 1; j <= m; ++j)
cout << ans[i][j] << " ";
cout << endl;
}
}
else
{
int cnt = 1;
swap(m, n);
for (int i = 1; i <= n; ++i)a[i].push_back(23);
for (int i = 1; i <= m; ++i)
for (int j = 1; j <= n; ++j)
a[j].push_back(cnt++);
if (n % 2 == 0)
{
for (int i = 1; i <= n; i += 2)
change2(i);
}
else
{
for (int i = 1; i <= n - 3; i += 2)
change2(i);
change3(n - 2);
}
cout << "YES" << endl;
for (int i = 1; i <= m; ++i)
{
for (int j = 1; j <= n; ++j)
cout << ans[j][i] << " ";
cout << endl;
}
}
return 0;
}
|
Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Students went into a class to write a test and sat in some way. The teacher thought: "Probably they sat in this order to copy works of each other. I need to rearrange them in such a way that students that were neighbors are not neighbors in a new seating."
The class can be represented as a matrix with *n* rows and *m* columns with a student in each cell. Two students are neighbors if cells in which they sit have a common side.
Let's enumerate students from 1 to *n*·*m* in order of rows. So a student who initially sits in the cell in row *i* and column *j* has a number (*i*<=-<=1)·*m*<=+<=*j*. You have to find a matrix with *n* rows and *m* columns in which all numbers from 1 to *n*·*m* appear exactly once and adjacent numbers in the original matrix are not adjacent in it, or determine that there is no such matrix.
Input Specification:
The only line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=105; *n*·*m*<=≤<=105) — the number of rows and the number of columns in the required matrix.
Output Specification:
If there is no such matrix, output "NO" (without quotes).
Otherwise in the first line output "YES" (without quotes), and in the next *n* lines output *m* integers which form the required matrix.
Demo Input:
['2 4\n', '2 1\n']
Demo Output:
['YES\n5 4 7 2 \n3 6 1 8 \n', 'NO\n']
Note:
In the first test case the matrix initially looks like this:
It's easy to see that there are no two students that are adjacent in both matrices.
In the second test case there are only two possible seatings and in both of them students with numbers 1 and 2 are neighbors.
|
```python
#define _CRT_SECURE_NO_DEPRECATE
#pragma comment(linker, "/STACK:102400000,102400000")
#include<iostream>
#include<cstdio>
#include<fstream>
#include<iomanip>
#include<algorithm>
#include<cmath>
#include<deque>
#include<vector>
#include<bitset>
#include<queue>
#include<string>
#include<cstring>
#include<map>
#include<stack>
#include<set>
#include<functional>
#define pii pair<int, int>
#define mod 1000000007
#define mp make_pair
#define pi acos(-1)
#define eps 0.00000001
#define mst(a,i) memset(a,i,sizeof(a))
#define all(n) n.begin(),n.end()
#define lson(x) ((x<<1))
#define rson(x) ((x<<1)|1)
#define inf 0x3f3f3f3f
typedef long long ll;
typedef unsigned long long ull;
using namespace std;
const int maxn = 1e5 + 5;
vector<int>a[maxn];
vector<int>ans[maxn];
int n, m;
void change2(int t)
{
ans[t].resize(m+1);
ans[t + 1].resize(m+1);
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t][i] = a[t][i];
else ans[t + 1][i] = a[t][i];
}
ans[t][2] = a[t + 1][m];
ans[t + 1][1] = a[t + 1][m - 1];
for (int i = 3; i <= m; ++i)
{
if (i & 1)ans[t + 1][i] = a[t+1][i-2];
else ans[t][i] = a[t + 1][i-2];
}
}
void change3(int t)
{
ans[t].resize(m+1);
ans[t + 1].resize(m+1);
ans[t + 2].resize(m+1);
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t][i] = a[t][i];
else ans[t + 2][i] = a[t][i];
}
ans[t][2] = a[t + 1][m];
ans[t + 1][1] = a[t + 1][m - 1];
for (int i = 3; i <= m; ++i)
{
if (i & 1)ans[t + 1][i] = a[t + 1][i - 2];
else ans[t][i] = a[t + 1][i - 2];
}
for (int i = 1; i <= m; ++i)
{
if (i & 1)ans[t+2][i] = a[t + 2][i];
else ans[t + 1][i] = a[t + 2][i];
}
}
int main()
{
ios::sync_with_stdio(false);
cin.tie(0); cout.tie(0);
int i, j, k;
cin >> n >> m;
if (n == 3 && m == 3)
{
cout << "YES" << endl;
cout << "1 7 3" << endl;
cout << "9 2 5" << endl;
cout << "4 8 6" << endl;
return 0;
}
if (n == 1 && m == 1)
{
cout << "YES" << endl;
cout << "1" << endl;
return 0;
}
if ((n <= 2 && m <= 2) || n == 1 || m == 1 || n + m == 5) { cout << "NO" << endl; return 0; }
if (n <= m)
{
for (int i = 1; i <= n; ++i)
{
a[i].push_back(123);
for (int j = 1; j <= m; ++j)
a[i].push_back((i - 1)*m + j);
}
if (n % 2 == 0)
{
for (int i = 1; i <= n; i += 2)
change2(i);
}
else
{
for (int i = 1; i <= n - 3; i += 2)
change2(i);
change3(n - 2);
}
cout << "YES" << endl;
for (int i = 1; i <= n; ++i)
{
for (int j = 1; j <= m; ++j)
cout << ans[i][j] << " ";
cout << endl;
}
}
else
{
int cnt = 1;
swap(m, n);
for (int i = 1; i <= n; ++i)a[i].push_back(23);
for (int i = 1; i <= m; ++i)
for (int j = 1; j <= n; ++j)
a[j].push_back(cnt++);
if (n % 2 == 0)
{
for (int i = 1; i <= n; i += 2)
change2(i);
}
else
{
for (int i = 1; i <= n - 3; i += 2)
change2(i);
change3(n - 2);
}
cout << "YES" << endl;
for (int i = 1; i <= m; ++i)
{
for (int j = 1; j <= n; ++j)
cout << ans[j][i] << " ";
cout << endl;
}
}
return 0;
}
```
| -1
|
|
331
|
C1
|
The Great Julya Calendar
|
PROGRAMMING
| 1,100
|
[
"dp"
] | null | null |
Yet another Armageddon is coming! This time the culprit is the Julya tribe calendar.
The beavers in this tribe knew math very well. Smart Beaver, an archaeologist, got a sacred plate with a magic integer on it. The translation from Old Beaverish is as follows:
"May the Great Beaver bless you! May your chacres open and may your third eye never turn blind from beholding the Truth! Take the magic number, subtract a digit from it (the digit must occur in the number) and get a new magic number. Repeat this operation until a magic number equals zero. The Earth will stand on Three Beavers for the time, equal to the number of subtractions you perform!"
Distinct subtraction sequences can obviously get you different number of operations. But the Smart Beaver is ready to face the worst and is asking you to count the minimum number of operations he needs to reduce the magic number to zero.
|
The single line contains the magic integer *n*, 0<=≤<=*n*.
- to get 20 points, you need to solve the problem with constraints: *n*<=≤<=106 (subproblem C1); - to get 40 points, you need to solve the problem with constraints: *n*<=≤<=1012 (subproblems C1+C2); - to get 100 points, you need to solve the problem with constraints: *n*<=≤<=1018 (subproblems C1+C2+C3).
|
Print a single integer — the minimum number of subtractions that turns the magic number to a zero.
|
[
"24\n"
] |
[
"5"
] |
In the first test sample the minimum number of operations can be reached by the following sequence of subtractions:
| 20
|
[
{
"input": "24",
"output": "5"
},
{
"input": "0",
"output": "0"
},
{
"input": "3",
"output": "1"
},
{
"input": "8",
"output": "1"
},
{
"input": "9",
"output": "1"
},
{
"input": "10",
"output": "2"
},
{
"input": "31",
"output": "6"
},
{
"input": "701",
"output": "116"
},
{
"input": "222",
"output": "39"
},
{
"input": "156",
"output": "28"
},
{
"input": "12343",
"output": "1778"
},
{
"input": "7984",
"output": "1178"
},
{
"input": "1000000",
"output": "128207"
},
{
"input": "1",
"output": "1"
},
{
"input": "3",
"output": "1"
},
{
"input": "5",
"output": "1"
},
{
"input": "11",
"output": "3"
},
{
"input": "77",
"output": "14"
},
{
"input": "216",
"output": "37"
},
{
"input": "1468",
"output": "233"
},
{
"input": "1995",
"output": "305"
},
{
"input": "11010",
"output": "1568"
},
{
"input": "47320",
"output": "6746"
},
{
"input": "258634",
"output": "35024"
}
] | 1,652,410,529
| 2,147,483,647
|
PyPy 3-64
|
OK
|
TESTS1
| 24
| 218
| 18,944,000
|
def converte(c):
return (ord(c) - 48)
def main():
n = int(input())
infinito = float("inf")
minima_operacao = [infinito for i in range(n + 1)]
minima_operacao[0] = 0
for i in range(1,n+1):
for c in str(i):
minima_operacao[i] = min(minima_operacao[i], minima_operacao[i - converte(c)] + 1)
print(minima_operacao[n])
if __name__ == '__main__':
main()
|
Title: The Great Julya Calendar
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Yet another Armageddon is coming! This time the culprit is the Julya tribe calendar.
The beavers in this tribe knew math very well. Smart Beaver, an archaeologist, got a sacred plate with a magic integer on it. The translation from Old Beaverish is as follows:
"May the Great Beaver bless you! May your chacres open and may your third eye never turn blind from beholding the Truth! Take the magic number, subtract a digit from it (the digit must occur in the number) and get a new magic number. Repeat this operation until a magic number equals zero. The Earth will stand on Three Beavers for the time, equal to the number of subtractions you perform!"
Distinct subtraction sequences can obviously get you different number of operations. But the Smart Beaver is ready to face the worst and is asking you to count the minimum number of operations he needs to reduce the magic number to zero.
Input Specification:
The single line contains the magic integer *n*, 0<=≤<=*n*.
- to get 20 points, you need to solve the problem with constraints: *n*<=≤<=106 (subproblem C1); - to get 40 points, you need to solve the problem with constraints: *n*<=≤<=1012 (subproblems C1+C2); - to get 100 points, you need to solve the problem with constraints: *n*<=≤<=1018 (subproblems C1+C2+C3).
Output Specification:
Print a single integer — the minimum number of subtractions that turns the magic number to a zero.
Demo Input:
['24\n']
Demo Output:
['5']
Note:
In the first test sample the minimum number of operations can be reached by the following sequence of subtractions:
|
```python
def converte(c):
return (ord(c) - 48)
def main():
n = int(input())
infinito = float("inf")
minima_operacao = [infinito for i in range(n + 1)]
minima_operacao[0] = 0
for i in range(1,n+1):
for c in str(i):
minima_operacao[i] = min(minima_operacao[i], minima_operacao[i - converte(c)] + 1)
print(minima_operacao[n])
if __name__ == '__main__':
main()
```
| 3
|
|
787
|
A
|
The Monster
|
PROGRAMMING
| 1,200
|
[
"brute force",
"math",
"number theory"
] | null | null |
A monster is chasing after Rick and Morty on another planet. They're so frightened that sometimes they scream. More accurately, Rick screams at times *b*,<=*b*<=+<=*a*,<=*b*<=+<=2*a*,<=*b*<=+<=3*a*,<=... and Morty screams at times *d*,<=*d*<=+<=*c*,<=*d*<=+<=2*c*,<=*d*<=+<=3*c*,<=....
The Monster will catch them if at any point they scream at the same time, so it wants to know when it will catch them (the first time they scream at the same time) or that they will never scream at the same time.
|
The first line of input contains two integers *a* and *b* (1<=≤<=*a*,<=*b*<=≤<=100).
The second line contains two integers *c* and *d* (1<=≤<=*c*,<=*d*<=≤<=100).
|
Print the first time Rick and Morty will scream at the same time, or <=-<=1 if they will never scream at the same time.
|
[
"20 2\n9 19\n",
"2 1\n16 12\n"
] |
[
"82\n",
"-1\n"
] |
In the first sample testcase, Rick's 5th scream and Morty's 8th time are at time 82.
In the second sample testcase, all Rick's screams will be at odd times and Morty's will be at even times, so they will never scream at the same time.
| 500
|
[
{
"input": "20 2\n9 19",
"output": "82"
},
{
"input": "2 1\n16 12",
"output": "-1"
},
{
"input": "39 52\n88 78",
"output": "1222"
},
{
"input": "59 96\n34 48",
"output": "1748"
},
{
"input": "87 37\n91 29",
"output": "211"
},
{
"input": "11 81\n49 7",
"output": "301"
},
{
"input": "39 21\n95 89",
"output": "3414"
},
{
"input": "59 70\n48 54",
"output": "1014"
},
{
"input": "87 22\n98 32",
"output": "718"
},
{
"input": "15 63\n51 13",
"output": "-1"
},
{
"input": "39 7\n97 91",
"output": "1255"
},
{
"input": "18 18\n71 71",
"output": "1278"
},
{
"input": "46 71\n16 49",
"output": "209"
},
{
"input": "70 11\n74 27",
"output": "2321"
},
{
"input": "94 55\n20 96",
"output": "-1"
},
{
"input": "18 4\n77 78",
"output": "1156"
},
{
"input": "46 44\n23 55",
"output": "-1"
},
{
"input": "74 88\n77 37",
"output": "1346"
},
{
"input": "94 37\n34 7",
"output": "789"
},
{
"input": "22 81\n80 88",
"output": "-1"
},
{
"input": "46 30\n34 62",
"output": "674"
},
{
"input": "40 4\n81 40",
"output": "364"
},
{
"input": "69 48\n39 9",
"output": "48"
},
{
"input": "89 93\n84 87",
"output": "5967"
},
{
"input": "17 45\n42 65",
"output": "317"
},
{
"input": "41 85\n95 46",
"output": "331"
},
{
"input": "69 30\n41 16",
"output": "1410"
},
{
"input": "93 74\n99 93",
"output": "-1"
},
{
"input": "17 19\n44 75",
"output": "427"
},
{
"input": "45 63\n98 53",
"output": "3483"
},
{
"input": "69 11\n48 34",
"output": "-1"
},
{
"input": "55 94\n3 96",
"output": "204"
},
{
"input": "100 100\n100 100",
"output": "100"
},
{
"input": "1 1\n1 1",
"output": "1"
},
{
"input": "1 1\n1 100",
"output": "100"
},
{
"input": "1 100\n100 1",
"output": "101"
},
{
"input": "98 1\n99 100",
"output": "9703"
},
{
"input": "98 1\n99 2",
"output": "9605"
},
{
"input": "97 2\n99 100",
"output": "4852"
},
{
"input": "3 3\n3 1",
"output": "-1"
},
{
"input": "3 2\n7 2",
"output": "2"
},
{
"input": "2 3\n2 5",
"output": "5"
},
{
"input": "2 3\n2 3",
"output": "3"
},
{
"input": "100 3\n100 5",
"output": "-1"
},
{
"input": "6 10\n12 14",
"output": "-1"
},
{
"input": "4 2\n4 4",
"output": "-1"
},
{
"input": "2 3\n2 2",
"output": "-1"
},
{
"input": "2 3\n4 99",
"output": "99"
},
{
"input": "1 5\n1 5",
"output": "5"
},
{
"input": "1 100\n3 1",
"output": "100"
},
{
"input": "2 2\n2 1",
"output": "-1"
},
{
"input": "2 10\n6 20",
"output": "20"
},
{
"input": "2 2\n2 10",
"output": "10"
},
{
"input": "3 7\n3 6",
"output": "-1"
},
{
"input": "1 100\n1 100",
"output": "100"
},
{
"input": "7 25\n39 85",
"output": "319"
},
{
"input": "84 82\n38 6",
"output": "82"
},
{
"input": "7 7\n7 14",
"output": "14"
}
] | 1,587,204,600
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 58
| 155
| 307,200
|
a,b = map(int,input().split())
c,d = map(int,input().split())
t = 10**5
i = 0
flag = 0
if d > b:
while i < t:
r = d - b + c*i
if r%a == 0:
flag = 1
break
i = i + 1
if flag == 0:
print(-1)
exit()
else:
print(d+c*i)
else:
while i < t:
r = b - d + a*i
if r%c == 0:
flag = 1
break
i = i + 1
if flag == 0:
print(-1)
else:
print(a*i+b)
|
Title: The Monster
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A monster is chasing after Rick and Morty on another planet. They're so frightened that sometimes they scream. More accurately, Rick screams at times *b*,<=*b*<=+<=*a*,<=*b*<=+<=2*a*,<=*b*<=+<=3*a*,<=... and Morty screams at times *d*,<=*d*<=+<=*c*,<=*d*<=+<=2*c*,<=*d*<=+<=3*c*,<=....
The Monster will catch them if at any point they scream at the same time, so it wants to know when it will catch them (the first time they scream at the same time) or that they will never scream at the same time.
Input Specification:
The first line of input contains two integers *a* and *b* (1<=≤<=*a*,<=*b*<=≤<=100).
The second line contains two integers *c* and *d* (1<=≤<=*c*,<=*d*<=≤<=100).
Output Specification:
Print the first time Rick and Morty will scream at the same time, or <=-<=1 if they will never scream at the same time.
Demo Input:
['20 2\n9 19\n', '2 1\n16 12\n']
Demo Output:
['82\n', '-1\n']
Note:
In the first sample testcase, Rick's 5th scream and Morty's 8th time are at time 82.
In the second sample testcase, all Rick's screams will be at odd times and Morty's will be at even times, so they will never scream at the same time.
|
```python
a,b = map(int,input().split())
c,d = map(int,input().split())
t = 10**5
i = 0
flag = 0
if d > b:
while i < t:
r = d - b + c*i
if r%a == 0:
flag = 1
break
i = i + 1
if flag == 0:
print(-1)
exit()
else:
print(d+c*i)
else:
while i < t:
r = b - d + a*i
if r%c == 0:
flag = 1
break
i = i + 1
if flag == 0:
print(-1)
else:
print(a*i+b)
```
| 3
|
|
142
|
C
|
Help Caretaker
|
PROGRAMMING
| 2,300
|
[
"brute force",
"dp"
] | null | null |
Autumn came late to the kingdom of Far Far Away. The harvest was exuberant and it is now time to get ready for the winter. As most people celebrate the Harvest festival, Simon the Caretaker tries to solve a very non-trivial task of how to find place for the agricultural equipment in the warehouse.
He's got problems with some particularly large piece of equipment, which is, of course, turboplows. The problem is that when a turboplow is stored, it takes up not some simply rectangular space. It takes up a T-shaped space like on one of the four pictures below (here character "#" stands for the space occupied by the turboplow and character "." stands for the free space):
Simon faced a quite natural challenge: placing in the given *n*<=×<=*m* cells warehouse the maximum number of turboplows. As one stores the turboplows, he can rotate them in any manner (so that they take up the space like on one of the four pictures above). However, two turboplows cannot "overlap", that is, they cannot share the same cell in the warehouse.
Simon feels that he alone cannot find the optimal way of positioning the plugs in the warehouse that would maximize their quantity. Can you help him?
|
The only line contains two space-separated integers *n* and *m* — the sizes of the warehouse (1<=≤<=*n*,<=*m*<=≤<=9).
|
In the first line print the maximum number of turboplows that can be positioned in the warehouse. In each of the next *n* lines print *m* characters. Use "." (dot) to mark empty space and use successive capital Latin letters ("A" for the first turboplow, "B" for the second one and so on until you reach the number of turboplows in your scheme) to mark place for the corresponding turboplows considering that they are positioned in the optimal manner in the warehouse. The order in which you number places for the turboplows does not matter. If there are several optimal solutions for a warehouse of the given size, print any of them.
|
[
"3 3\n",
"5 6\n",
"2 2\n"
] |
[
"1\nAAA\n.A.\n.A.\n",
"4\nA..C..\nAAAC..\nABCCCD\n.B.DDD\nBBB..D\n",
"0\n..\n..\n"
] |
none
| 1,500
|
[
{
"input": "3 3",
"output": "1\nAAA\n.A.\n.A."
},
{
"input": "5 6",
"output": "4\nA..C..\nAAAC..\nABCCCD\n.B.DDD\nBBB..D"
},
{
"input": "2 2",
"output": "0\n..\n.."
},
{
"input": "4 2",
"output": "0\n..\n..\n..\n.."
},
{
"input": "3 4",
"output": "1\nA...\nAAA.\nA..."
},
{
"input": "5 3",
"output": "2\nAAA\n.A.\n.AB\nBBB\n..B"
},
{
"input": "4 4",
"output": "2\nAAA.\n.AB.\n.AB.\n.BBB"
},
{
"input": "3 6",
"output": "2\nA..B..\nAAAB..\nA.BBB."
},
{
"input": "5 4",
"output": "2\nAAA.\n.AB.\n.AB.\n.BBB\n...."
},
{
"input": "5 5",
"output": "4\nAAA.B\n.ABBB\nCA.DB\nCCCD.\nC.DDD"
},
{
"input": "1 1",
"output": "0\n."
},
{
"input": "1 2",
"output": "0\n.."
},
{
"input": "2 1",
"output": "0\n.\n."
},
{
"input": "1 3",
"output": "0\n..."
},
{
"input": "3 1",
"output": "0\n.\n.\n."
},
{
"input": "1 4",
"output": "0\n...."
},
{
"input": "4 1",
"output": "0\n.\n.\n.\n."
},
{
"input": "1 5",
"output": "0\n....."
},
{
"input": "5 1",
"output": "0\n.\n.\n.\n.\n."
},
{
"input": "1 6",
"output": "0\n......"
},
{
"input": "2 3",
"output": "0\n...\n..."
},
{
"input": "3 2",
"output": "0\n..\n..\n.."
},
{
"input": "6 1",
"output": "0\n.\n.\n.\n.\n.\n."
},
{
"input": "1 7",
"output": "0\n......."
},
{
"input": "7 1",
"output": "0\n.\n.\n.\n.\n.\n.\n."
},
{
"input": "1 8",
"output": "0\n........"
},
{
"input": "2 4",
"output": "0\n....\n...."
},
{
"input": "8 1",
"output": "0\n.\n.\n.\n.\n.\n.\n.\n."
},
{
"input": "1 9",
"output": "0\n........."
},
{
"input": "9 1",
"output": "0\n.\n.\n.\n.\n.\n.\n.\n.\n."
},
{
"input": "2 5",
"output": "0\n.....\n....."
},
{
"input": "5 2",
"output": "0\n..\n..\n..\n..\n.."
},
{
"input": "2 6",
"output": "0\n......\n......"
},
{
"input": "4 3",
"output": "1\nAAA\n.A.\n.A.\n..."
},
{
"input": "6 2",
"output": "0\n..\n..\n..\n..\n..\n.."
},
{
"input": "2 7",
"output": "0\n.......\n......."
},
{
"input": "7 2",
"output": "0\n..\n..\n..\n..\n..\n..\n.."
},
{
"input": "3 5",
"output": "2\nA..B.\nAAAB.\nA.BBB"
},
{
"input": "2 8",
"output": "0\n........\n........"
},
{
"input": "8 2",
"output": "0\n..\n..\n..\n..\n..\n..\n..\n.."
},
{
"input": "2 9",
"output": "0\n.........\n........."
},
{
"input": "6 3",
"output": "2\nAAA\n.A.\n.AB\nBBB\n..B\n..."
},
{
"input": "9 2",
"output": "0\n..\n..\n..\n..\n..\n..\n..\n..\n.."
},
{
"input": "4 5",
"output": "2\nA....\nAAAB.\nABBB.\n...B."
},
{
"input": "3 7",
"output": "3\nA..B..C\nAAABCCC\nA.BBB.C"
},
{
"input": "7 3",
"output": "3\nAAA\n.A.\n.AB\nBBB\n.CB\n.C.\nCCC"
},
{
"input": "3 8",
"output": "3\nA..B..C.\nAAABCCC.\nA.BBB.C."
},
{
"input": "4 6",
"output": "3\nA..CCC\nAAABC.\nABBBC.\n...B.."
},
{
"input": "6 4",
"output": "3\nAAA.\n.AB.\n.AB.\nCBBB\nCCC.\nC..."
},
{
"input": "8 3",
"output": "3\nAAA\n.A.\n.AB\nBBB\n.CB\n.C.\nCCC\n..."
},
{
"input": "3 9",
"output": "4\nA..BCCCD.\nAAAB.C.D.\nA.BBBCDDD"
},
{
"input": "9 3",
"output": "4\nAAA\n.A.\n.AB\nBBB\nC.B\nCCC\nC.D\nDDD\n..D"
},
{
"input": "4 7",
"output": "4\nA..CCC.\nAAABCD.\nABBBCD.\n...BDDD"
},
{
"input": "7 4",
"output": "4\nAAA.\n.AB.\n.AB.\nCBBB\nCCCD\nCDDD\n...D"
},
{
"input": "6 5",
"output": "4\nAAA.B\n.ABBB\n.AC.B\nCCCD.\n..CD.\n..DDD"
},
{
"input": "4 8",
"output": "4\nA..CCC..\nAAABCD..\nABBBCD..\n...BDDD."
},
{
"input": "8 4",
"output": "4\nAAA.\n.AB.\n.AB.\nCBBB\nCCCD\nCDDD\n...D\n...."
},
{
"input": "5 7",
"output": "5\nA..C..E\nAAACEEE\nABCCCDE\n.B.DDD.\nBBB..D."
},
{
"input": "7 5",
"output": "5\nAAA.B\n.ABBB\n.AC.B\nCCCD.\n.ECD.\n.EDDD\nEEE.."
},
{
"input": "4 9",
"output": "5\nA..CCCE..\nAAABCDEEE\nABBBCDE..\n...BDDD.."
},
{
"input": "6 6",
"output": "5\nAAA.B.\n.ABBB.\n.A.CB.\nDCCCE.\nDDDCE.\nD..EEE"
},
{
"input": "9 4",
"output": "5\nAAA.\n.AB.\n.AB.\nCBBB\nCCCD\nCDDD\nEEED\n.E..\n.E.."
},
{
"input": "5 8",
"output": "6\nA.CCC.E.\nAAACEEE.\nAB.CDFE.\n.BDDDFFF\nBBB.DF.."
},
{
"input": "8 5",
"output": "6\nAAA.B\n.ABBB\nCA.DB\nCCCD.\nCEDDD\n.EFFF\nEEEF.\n...F."
},
{
"input": "6 7",
"output": "6\nA..C..E\nAAACEEE\nABCCCFE\n.B.D.F.\nBBBDFFF\n..DDD.."
},
{
"input": "7 6",
"output": "6\nAAA.B.\n.ABBB.\n.AC.BD\nCCCDDD\n.EC.FD\n.EFFF.\nEEE.F."
},
{
"input": "5 9",
"output": "7\nA.CCC.GGG\nAAACEEEG.\nAB.CDEFG.\n.BDDDEF..\nBBB.DFFF."
},
{
"input": "9 5",
"output": "7\nAAA.B\n.ABBB\nCA.DB\nCCCD.\nCEDDD\n.EEEF\nGEFFF\nGGG.F\nG...."
},
{
"input": "6 8",
"output": "7\nA..C.FFF\nAAAC.EF.\nABCCCEF.\n.B.DEEEG\nBBBD.GGG\n..DDD..G"
},
{
"input": "8 6",
"output": "7\nAAA.B.\n.ABBB.\n.AC.BD\nCCCDDD\n..CE.D\nFEEEG.\nFFFEG.\nF..GGG"
},
{
"input": "7 7",
"output": "8\nAAABCCC\n.A.B.C.\nDABBBCE\nDDDFEEE\nDG.F.HE\n.GFFFH.\nGGG.HHH"
},
{
"input": "6 9",
"output": "8\nA..CEEE.G\nAAAC.EGGG\nABCCCEF.G\n.B.DFFFH.\nBBBD..FH.\n..DDD.HHH"
},
{
"input": "9 6",
"output": "8\nAAA.B.\n.ABBB.\n.AC.BD\nCCCDDD\nE.CF.D\nEEEF..\nEGFFFH\n.G.HHH\nGGG..H"
},
{
"input": "7 8",
"output": "9\nA.DDD..H\nAAADFHHH\nA.BDFFFH\nBBBEFIII\n.CBE.GI.\n.CEEEGI.\nCCC.GGG."
},
{
"input": "8 7",
"output": "9\nAAAB..C\n.A.BCCC\nDABBBEC\nDDDEEE.\nDFFF.EG\n.HFIGGG\n.HFIIIG\nHHHI..."
},
{
"input": "7 9",
"output": "10\nA..DFFF.H\nAAAD.FHHH\nABDDDFI.H\n.B.EEEIII\nBBBCEGI.J\n.CCCEGJJJ\n...CGGG.J"
},
{
"input": "9 7",
"output": "10\nAAA.B..\n.ABBBC.\n.AD.BC.\nDDDECCC\nF.DEEEG\nFFFEGGG\nFHIIIJG\n.H.I.J.\nHHHIJJJ"
},
{
"input": "8 8",
"output": "10\nAAA.BCCC\n.ABBBDC.\nEA.FBDC.\nEEEFDDDG\nEHFFFGGG\n.HIII.JG\nHHHIJJJ.\n...I..J."
},
{
"input": "8 9",
"output": "12\nA.EEE.JJJ\nAAAEHHHJ.\nAB.EFHKJ.\n.BFFFHKKK\nBBBDFIK..\nCDDDGIIIL\nCCCDGILLL\nC..GGG..L"
},
{
"input": "9 8",
"output": "12\nAAA.BCCC\n.ABBBDC.\nEA.FBDC.\nEEEFDDDG\nEHFFFGGG\n.HHHIIIG\nJHKKKIL.\nJJJK.IL.\nJ..K.LLL"
},
{
"input": "9 9",
"output": "13\nAAA.BCCC.\n.ABBB.CD.\n.AE.BFCD.\nEEEFFFDDD\nG.E.HFIII\nGGGJHHHI.\nGK.JHL.IM\n.KJJJLMMM\nKKK.LLL.M"
}
] | 1,673,524,504
| 2,147,483,647
|
Python 3
|
COMPILATION_ERROR
|
TESTS
| 0
| 0
| 0
|
# LUOGU_RID: 99522112
n,a,d=map(int,input().split()) //
print(368131125*a%10**9*12*10**9+1,368131125*d%10**9*12*10**9)
|
Title: Help Caretaker
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Autumn came late to the kingdom of Far Far Away. The harvest was exuberant and it is now time to get ready for the winter. As most people celebrate the Harvest festival, Simon the Caretaker tries to solve a very non-trivial task of how to find place for the agricultural equipment in the warehouse.
He's got problems with some particularly large piece of equipment, which is, of course, turboplows. The problem is that when a turboplow is stored, it takes up not some simply rectangular space. It takes up a T-shaped space like on one of the four pictures below (here character "#" stands for the space occupied by the turboplow and character "." stands for the free space):
Simon faced a quite natural challenge: placing in the given *n*<=×<=*m* cells warehouse the maximum number of turboplows. As one stores the turboplows, he can rotate them in any manner (so that they take up the space like on one of the four pictures above). However, two turboplows cannot "overlap", that is, they cannot share the same cell in the warehouse.
Simon feels that he alone cannot find the optimal way of positioning the plugs in the warehouse that would maximize their quantity. Can you help him?
Input Specification:
The only line contains two space-separated integers *n* and *m* — the sizes of the warehouse (1<=≤<=*n*,<=*m*<=≤<=9).
Output Specification:
In the first line print the maximum number of turboplows that can be positioned in the warehouse. In each of the next *n* lines print *m* characters. Use "." (dot) to mark empty space and use successive capital Latin letters ("A" for the first turboplow, "B" for the second one and so on until you reach the number of turboplows in your scheme) to mark place for the corresponding turboplows considering that they are positioned in the optimal manner in the warehouse. The order in which you number places for the turboplows does not matter. If there are several optimal solutions for a warehouse of the given size, print any of them.
Demo Input:
['3 3\n', '5 6\n', '2 2\n']
Demo Output:
['1\nAAA\n.A.\n.A.\n', '4\nA..C..\nAAAC..\nABCCCD\n.B.DDD\nBBB..D\n', '0\n..\n..\n']
Note:
none
|
```python
# LUOGU_RID: 99522112
n,a,d=map(int,input().split()) //
print(368131125*a%10**9*12*10**9+1,368131125*d%10**9*12*10**9)
```
| -1
|
|
282
|
A
|
Bit++
|
PROGRAMMING
| 800
|
[
"implementation"
] | null | null |
The classic programming language of Bitland is Bit++. This language is so peculiar and complicated.
The language is that peculiar as it has exactly one variable, called *x*. Also, there are two operations:
- Operation ++ increases the value of variable *x* by 1. - Operation -- decreases the value of variable *x* by 1.
A statement in language Bit++ is a sequence, consisting of exactly one operation and one variable *x*. The statement is written without spaces, that is, it can only contain characters "+", "-", "X". Executing a statement means applying the operation it contains.
A programme in Bit++ is a sequence of statements, each of them needs to be executed. Executing a programme means executing all the statements it contains.
You're given a programme in language Bit++. The initial value of *x* is 0. Execute the programme and find its final value (the value of the variable when this programme is executed).
|
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=150) — the number of statements in the programme.
Next *n* lines contain a statement each. Each statement contains exactly one operation (++ or --) and exactly one variable *x* (denoted as letter «X»). Thus, there are no empty statements. The operation and the variable can be written in any order.
|
Print a single integer — the final value of *x*.
|
[
"1\n++X\n",
"2\nX++\n--X\n"
] |
[
"1\n",
"0\n"
] |
none
| 500
|
[
{
"input": "1\n++X",
"output": "1"
},
{
"input": "2\nX++\n--X",
"output": "0"
},
{
"input": "3\n++X\n++X\n++X",
"output": "3"
},
{
"input": "2\n--X\n--X",
"output": "-2"
},
{
"input": "5\n++X\n--X\n++X\n--X\n--X",
"output": "-1"
},
{
"input": "28\nX--\n++X\nX++\nX++\nX++\n--X\n--X\nX++\nX--\n++X\nX++\n--X\nX--\nX++\nX--\n++X\n++X\nX++\nX++\nX++\nX++\n--X\n++X\n--X\n--X\n--X\n--X\nX++",
"output": "4"
},
{
"input": "94\nX++\nX++\n++X\n++X\nX--\n--X\nX++\n--X\nX++\n++X\nX++\n++X\n--X\n--X\n++X\nX++\n--X\nX--\nX--\n--X\nX--\nX--\n--X\n++X\n--X\nX--\nX--\nX++\n++X\n--X\nX--\n++X\n--X\n--X\nX--\nX--\nX++\nX++\nX--\nX++\nX--\nX--\nX--\n--X\nX--\nX--\nX--\nX++\n++X\nX--\n++X\nX++\n--X\n--X\n--X\n--X\n++X\nX--\n--X\n--X\n++X\nX--\nX--\nX++\n++X\nX++\n++X\n--X\n--X\nX--\n++X\nX--\nX--\n++X\n++X\n++X\n++X\nX++\n++X\n--X\nX++\n--X\n--X\n++X\n--X\nX++\n++X\nX++\n--X\nX--\nX--\n--X\n++X\nX++",
"output": "-10"
},
{
"input": "56\n--X\nX--\n--X\n--X\nX--\nX--\n--X\nX++\n++X\n--X\nX++\nX--\n--X\n++X\n--X\nX--\nX--\n++X\nX--\nX--\n--X\n++X\n--X\n++X\n--X\nX++\n++X\nX++\n--X\n++X\nX++\nX++\n--X\nX++\nX--\n--X\nX--\n--X\nX++\n++X\n--X\n++X\nX++\nX--\n--X\n--X\n++X\nX--\nX--\n--X\nX--\n--X\nX++\n--X\n++X\n--X",
"output": "-14"
},
{
"input": "59\nX--\n--X\nX++\n++X\nX--\n--X\n--X\n++X\n++X\n++X\n++X\nX++\n++X\n++X\nX++\n--X\nX--\nX++\n++X\n--X\nX++\n--X\n++X\nX++\n--X\n--X\nX++\nX++\n--X\nX++\nX++\nX++\nX--\nX--\n--X\nX++\nX--\nX--\n++X\nX--\nX++\n--X\nX++\nX--\nX--\nX--\nX--\n++X\n--X\nX++\nX++\nX--\nX++\n++X\nX--\nX++\nX--\nX--\n++X",
"output": "3"
},
{
"input": "87\n--X\n++X\n--X\nX++\n--X\nX--\n--X\n++X\nX--\n++X\n--X\n--X\nX++\n--X\nX--\nX++\n++X\n--X\n++X\n++X\n--X\n++X\n--X\nX--\n++X\n++X\nX--\nX++\nX++\n--X\n--X\n++X\nX--\n--X\n++X\n--X\nX++\n--X\n--X\nX--\n++X\n++X\n--X\nX--\nX--\nX--\nX--\nX--\nX++\n--X\n++X\n--X\nX++\n++X\nX++\n++X\n--X\nX++\n++X\nX--\n--X\nX++\n++X\nX++\nX++\n--X\n--X\n++X\n--X\nX++\nX++\n++X\nX++\nX++\nX++\nX++\n--X\n--X\n--X\n--X\n--X\n--X\n--X\nX--\n--X\n++X\n++X",
"output": "-5"
},
{
"input": "101\nX++\nX++\nX++\n++X\n--X\nX--\nX++\nX--\nX--\n--X\n--X\n++X\nX++\n++X\n++X\nX--\n--X\n++X\nX++\nX--\n++X\n--X\n--X\n--X\n++X\n--X\n++X\nX++\nX++\n++X\n--X\nX++\nX--\nX++\n++X\n++X\nX--\nX--\nX--\nX++\nX++\nX--\nX--\nX++\n++X\n++X\n++X\n--X\n--X\n++X\nX--\nX--\n--X\n++X\nX--\n++X\nX++\n++X\nX--\nX--\n--X\n++X\n--X\n++X\n++X\n--X\nX++\n++X\nX--\n++X\nX--\n++X\nX++\nX--\n++X\nX++\n--X\nX++\nX++\n++X\n--X\n++X\n--X\nX++\n--X\nX--\n--X\n++X\n++X\n++X\n--X\nX--\nX--\nX--\nX--\n--X\n--X\n--X\n++X\n--X\n--X",
"output": "1"
},
{
"input": "63\n--X\nX--\n++X\n--X\n++X\nX++\n--X\n--X\nX++\n--X\n--X\nX++\nX--\nX--\n--X\n++X\nX--\nX--\nX++\n++X\nX++\nX++\n--X\n--X\n++X\nX--\nX--\nX--\n++X\nX++\nX--\n--X\nX--\n++X\n++X\nX++\n++X\nX++\nX++\n--X\nX--\n++X\nX--\n--X\nX--\nX--\nX--\n++X\n++X\n++X\n++X\nX++\nX++\n++X\n--X\n--X\n++X\n++X\n++X\nX--\n++X\n++X\nX--",
"output": "1"
},
{
"input": "45\n--X\n++X\nX--\n++X\n++X\nX++\n--X\n--X\n--X\n--X\n--X\n--X\n--X\nX++\n++X\nX--\n++X\n++X\nX--\nX++\nX--\n--X\nX--\n++X\n++X\n--X\n--X\nX--\nX--\n--X\n++X\nX--\n--X\n++X\n++X\n--X\n--X\nX--\n++X\n++X\nX++\nX++\n++X\n++X\nX++",
"output": "-3"
},
{
"input": "21\n++X\nX++\n--X\nX--\nX++\n++X\n--X\nX--\nX++\nX--\nX--\nX--\nX++\n++X\nX++\n++X\n--X\nX--\n--X\nX++\n++X",
"output": "1"
},
{
"input": "100\n--X\n++X\nX++\n++X\nX--\n++X\nX--\nX++\n--X\nX++\nX--\nX--\nX--\n++X\nX--\nX++\nX++\n++X\nX++\nX++\nX++\nX++\n++X\nX++\n++X\nX--\n--X\n++X\nX--\n--X\n++X\n++X\nX--\nX++\nX++\nX++\n++X\n--X\n++X\nX++\nX--\n++X\n++X\n--X\n++X\nX--\nX--\nX--\nX++\nX--\nX--\nX++\nX++\n--X\nX++\nX++\n--X\nX--\n--X\n++X\n--X\n++X\n++X\nX--\n--X\n++X\n++X\n--X\n--X\n++X\nX++\nX--\nX++\nX--\nX++\nX++\n--X\nX--\nX--\n++X\nX--\n--X\n--X\nX++\n--X\n--X\nX--\nX--\n++X\n++X\nX--\n++X\nX++\n--X\n++X\n++X\nX++\n--X\n--X\nX++",
"output": "8"
},
{
"input": "17\nX++\nX++\n++X\n--X\n--X\n++X\n++X\n--X\nX--\nX++\nX--\n--X\n--X\nX--\n++X\nX--\nX++",
"output": "-1"
},
{
"input": "77\n++X\nX++\n--X\nX--\n--X\n--X\nX--\nX++\nX--\nX++\nX--\n++X\n--X\n--X\n--X\n--X\n++X\nX--\nX++\nX--\n--X\nX--\n--X\nX--\n++X\n--X\n++X\n++X\nX++\nX++\nX--\n--X\nX--\nX--\nX++\n--X\n--X\n++X\nX--\nX--\n++X\nX++\nX--\n++X\n--X\nX++\nX--\n++X\n++X\n++X\nX--\nX--\nX--\n--X\n++X\n++X\n++X\nX++\n--X\n--X\n++X\n--X\nX--\nX++\n++X\nX++\n++X\nX--\nX++\nX++\n--X\nX++\nX++\nX++\n--X\nX++\nX--",
"output": "-5"
},
{
"input": "21\nX--\n++X\n--X\nX--\n++X\nX--\n++X\nX--\n--X\n++X\nX++\n++X\nX++\n++X\nX--\n--X\nX++\nX++\nX--\n++X\nX--",
"output": "1"
},
{
"input": "1\nX--",
"output": "-1"
}
] | 1,697,964,110
| 2,147,483,647
|
Python 3
|
OK
|
TESTS
| 36
| 46
| 0
|
n = int(input())
i = 0
x=0
while(i<n):
s = input()
if(s[1]=='+'):
x=x+1
else:
x=x-1
i=i+1
print(x)
|
Title: Bit++
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The classic programming language of Bitland is Bit++. This language is so peculiar and complicated.
The language is that peculiar as it has exactly one variable, called *x*. Also, there are two operations:
- Operation ++ increases the value of variable *x* by 1. - Operation -- decreases the value of variable *x* by 1.
A statement in language Bit++ is a sequence, consisting of exactly one operation and one variable *x*. The statement is written without spaces, that is, it can only contain characters "+", "-", "X". Executing a statement means applying the operation it contains.
A programme in Bit++ is a sequence of statements, each of them needs to be executed. Executing a programme means executing all the statements it contains.
You're given a programme in language Bit++. The initial value of *x* is 0. Execute the programme and find its final value (the value of the variable when this programme is executed).
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=150) — the number of statements in the programme.
Next *n* lines contain a statement each. Each statement contains exactly one operation (++ or --) and exactly one variable *x* (denoted as letter «X»). Thus, there are no empty statements. The operation and the variable can be written in any order.
Output Specification:
Print a single integer — the final value of *x*.
Demo Input:
['1\n++X\n', '2\nX++\n--X\n']
Demo Output:
['1\n', '0\n']
Note:
none
|
```python
n = int(input())
i = 0
x=0
while(i<n):
s = input()
if(s[1]=='+'):
x=x+1
else:
x=x-1
i=i+1
print(x)
```
| 3
|
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