contestId int64 0 1.01k | index stringclasses 57 values | name stringlengths 2 58 | type stringclasses 2 values | rating int64 0 3.5k | tags listlengths 0 11 | title stringclasses 522 values | time-limit stringclasses 8 values | memory-limit stringclasses 8 values | problem-description stringlengths 0 7.15k | input-specification stringlengths 0 2.05k | output-specification stringlengths 0 1.5k | demo-input listlengths 0 7 | demo-output listlengths 0 7 | note stringlengths 0 5.24k | points float64 0 425k | test_cases listlengths 0 402 | creationTimeSeconds int64 1.37B 1.7B | relativeTimeSeconds int64 8 2.15B | programmingLanguage stringclasses 3 values | verdict stringclasses 14 values | testset stringclasses 12 values | passedTestCount int64 0 1k | timeConsumedMillis int64 0 15k | memoryConsumedBytes int64 0 805M | code stringlengths 3 65.5k | prompt stringlengths 262 8.2k | response stringlengths 17 65.5k | score float64 -1 3.99 |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
148 | A | Insomnia cure | PROGRAMMING | 800 | [
"constructive algorithms",
"implementation",
"math"
] | null | null | «One dragon. Two dragon. Three dragon», — the princess was counting. She had trouble falling asleep, and she got bored of counting lambs when she was nine.
However, just counting dragons was boring as well, so she entertained herself at best she could. Tonight she imagined that all dragons were here to steal her, and she was fighting them off. Every *k*-th dragon got punched in the face with a frying pan. Every *l*-th dragon got his tail shut into the balcony door. Every *m*-th dragon got his paws trampled with sharp heels. Finally, she threatened every *n*-th dragon to call her mom, and he withdrew in panic.
How many imaginary dragons suffered moral or physical damage tonight, if the princess counted a total of *d* dragons? | Input data contains integer numbers *k*,<=*l*,<=*m*,<=*n* and *d*, each number in a separate line (1<=≤<=*k*,<=*l*,<=*m*,<=*n*<=≤<=10, 1<=≤<=*d*<=≤<=105). | Output the number of damaged dragons. | [
"1\n2\n3\n4\n12\n",
"2\n3\n4\n5\n24\n"
] | [
"12\n",
"17\n"
] | In the first case every first dragon got punched with a frying pan. Some of the dragons suffered from other reasons as well, but the pan alone would be enough.
In the second case dragons 1, 7, 11, 13, 17, 19 and 23 escaped unharmed. | 1,000 | [
{
"input": "1\n2\n3\n4\n12",
"output": "12"
},
{
"input": "2\n3\n4\n5\n24",
"output": "17"
},
{
"input": "1\n1\n1\n1\n100000",
"output": "100000"
},
{
"input": "10\n9\n8\n7\n6",
"output": "0"
},
{
"input": "8\n4\n4\n3\n65437",
"output": "32718"
},
{
"input": "8\n4\n1\n10\n59392",
"output": "59392"
},
{
"input": "4\n1\n8\n7\n44835",
"output": "44835"
},
{
"input": "6\n1\n7\n2\n62982",
"output": "62982"
},
{
"input": "2\n7\n4\n9\n56937",
"output": "35246"
},
{
"input": "2\n9\n8\n1\n75083",
"output": "75083"
},
{
"input": "8\n7\n7\n6\n69038",
"output": "24656"
},
{
"input": "4\n4\n2\n3\n54481",
"output": "36320"
},
{
"input": "6\n4\n9\n8\n72628",
"output": "28244"
},
{
"input": "9\n7\n8\n10\n42357",
"output": "16540"
},
{
"input": "5\n6\n4\n3\n60504",
"output": "36302"
},
{
"input": "7\n2\n3\n8\n21754",
"output": "15539"
},
{
"input": "1\n2\n10\n4\n39901",
"output": "39901"
},
{
"input": "3\n4\n7\n1\n58048",
"output": "58048"
},
{
"input": "9\n10\n4\n6\n52003",
"output": "21956"
},
{
"input": "5\n10\n9\n3\n70149",
"output": "32736"
},
{
"input": "5\n5\n5\n10\n55592",
"output": "11118"
},
{
"input": "1\n5\n2\n6\n49547",
"output": "49547"
},
{
"input": "3\n7\n7\n7\n84046",
"output": "36019"
},
{
"input": "10\n2\n1\n8\n63537",
"output": "63537"
},
{
"input": "7\n2\n10\n5\n81684",
"output": "53678"
},
{
"input": "7\n1\n6\n8\n99831",
"output": "99831"
},
{
"input": "3\n9\n3\n3\n61082",
"output": "20360"
},
{
"input": "5\n5\n8\n9\n79228",
"output": "29931"
},
{
"input": "1\n5\n5\n6\n89535",
"output": "89535"
},
{
"input": "5\n5\n2\n1\n7682",
"output": "7682"
},
{
"input": "7\n4\n8\n8\n25829",
"output": "9224"
},
{
"input": "3\n4\n3\n3\n87079",
"output": "43539"
},
{
"input": "5\n8\n4\n9\n5226",
"output": "2438"
},
{
"input": "4\n9\n6\n6\n1070",
"output": "415"
},
{
"input": "10\n10\n10\n10\n100000",
"output": "10000"
},
{
"input": "1\n1\n1\n1\n1",
"output": "1"
},
{
"input": "10\n10\n10\n10\n1",
"output": "0"
},
{
"input": "10\n10\n1\n10\n10",
"output": "10"
},
{
"input": "10\n10\n1\n10\n100",
"output": "100"
},
{
"input": "2\n2\n2\n2\n1",
"output": "0"
}
] | 1,698,755,167 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 62 | 0 | def sol(n):
if len(n) == 1 : k = 1
else : k = len(n) - n.count('0')
ans=[]
for i in range(len(n)):
if n[i] !='0' : ans.append(n[i]+'0'*(len(n)-i-1))
print(k)
print(*ans)
for i in range(int(input())):
sol(str(input()))
| Title: Insomnia cure
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
«One dragon. Two dragon. Three dragon», — the princess was counting. She had trouble falling asleep, and she got bored of counting lambs when she was nine.
However, just counting dragons was boring as well, so she entertained herself at best she could. Tonight she imagined that all dragons were here to steal her, and she was fighting them off. Every *k*-th dragon got punched in the face with a frying pan. Every *l*-th dragon got his tail shut into the balcony door. Every *m*-th dragon got his paws trampled with sharp heels. Finally, she threatened every *n*-th dragon to call her mom, and he withdrew in panic.
How many imaginary dragons suffered moral or physical damage tonight, if the princess counted a total of *d* dragons?
Input Specification:
Input data contains integer numbers *k*,<=*l*,<=*m*,<=*n* and *d*, each number in a separate line (1<=≤<=*k*,<=*l*,<=*m*,<=*n*<=≤<=10, 1<=≤<=*d*<=≤<=105).
Output Specification:
Output the number of damaged dragons.
Demo Input:
['1\n2\n3\n4\n12\n', '2\n3\n4\n5\n24\n']
Demo Output:
['12\n', '17\n']
Note:
In the first case every first dragon got punched with a frying pan. Some of the dragons suffered from other reasons as well, but the pan alone would be enough.
In the second case dragons 1, 7, 11, 13, 17, 19 and 23 escaped unharmed. | ```python
def sol(n):
if len(n) == 1 : k = 1
else : k = len(n) - n.count('0')
ans=[]
for i in range(len(n)):
if n[i] !='0' : ans.append(n[i]+'0'*(len(n)-i-1))
print(k)
print(*ans)
for i in range(int(input())):
sol(str(input()))
``` | 0 | |
544 | A | Set of Strings | PROGRAMMING | 1,100 | [
"implementation",
"strings"
] | null | null | You are given a string *q*. A sequence of *k* strings *s*1,<=*s*2,<=...,<=*s**k* is called beautiful, if the concatenation of these strings is string *q* (formally, *s*1<=+<=*s*2<=+<=...<=+<=*s**k*<==<=*q*) and the first characters of these strings are distinct.
Find any beautiful sequence of strings or determine that the beautiful sequence doesn't exist. | The first line contains a positive integer *k* (1<=≤<=*k*<=≤<=26) — the number of strings that should be in a beautiful sequence.
The second line contains string *q*, consisting of lowercase Latin letters. The length of the string is within range from 1 to 100, inclusive. | If such sequence doesn't exist, then print in a single line "NO" (without the quotes). Otherwise, print in the first line "YES" (without the quotes) and in the next *k* lines print the beautiful sequence of strings *s*1,<=*s*2,<=...,<=*s**k*.
If there are multiple possible answers, print any of them. | [
"1\nabca\n",
"2\naaacas\n",
"4\nabc\n"
] | [
"YES\nabca\n",
"YES\naaa\ncas\n",
"NO\n"
] | In the second sample there are two possible answers: {"*aaaca*", "*s*"} and {"*aaa*", "*cas*"}. | 500 | [
{
"input": "1\nabca",
"output": "YES\nabca"
},
{
"input": "2\naaacas",
"output": "YES\naaa\ncas"
},
{
"input": "4\nabc",
"output": "NO"
},
{
"input": "3\nnddkhkhkdndknndkhrnhddkrdhrnrrnkkdnnndndrdhnknknhnrnnkrrdhrkhkrkhnkhkhhrhdnrndnknrrhdrdrkhdrkkhkrnkk",
"output": "YES\nn\ndd\nkhkhkdndknndkhrnhddkrdhrnrrnkkdnnndndrdhnknknhnrnnkrrdhrkhkrkhnkhkhhrhdnrndnknrrhdrdrkhdrkkhkrnkk"
},
{
"input": "26\nbiibfmmfifmffbmmfmbmbmiimbmiffmffibibfbiffibibiiimbffbbfbifmiibffbmbbbfmfibmibfffibfbffmfmimbmmmfmfm",
"output": "NO"
},
{
"input": "3\nkydoybxlfeugtrbvqnrjtzshorrsrwsxkvlwyolbaadtzpmyyfllxuciia",
"output": "YES\nk\ny\ndoybxlfeugtrbvqnrjtzshorrsrwsxkvlwyolbaadtzpmyyfllxuciia"
},
{
"input": "3\nssussususskkskkskuusksuuussksukkskuksukukusssususuususkkuukssuksskusukkssuksskskuskusussusskskksksus",
"output": "YES\nss\nussususs\nkkskkskuusksuuussksukkskuksukukusssususuususkkuukssuksskusukkssuksskskuskusussusskskksksus"
},
{
"input": "5\naaaaabcdef",
"output": "YES\naaaaa\nb\nc\nd\nef"
},
{
"input": "3\niiiiiiimiriiriwmimtmwrhhxmbmhwgghhgbqhywebrblyhlxjrthoooltehrmdhqhuodjmsjwcgrfnttiitpmqvbhlafwtzyikc",
"output": "YES\niiiiiii\nmi\nriiriwmimtmwrhhxmbmhwgghhgbqhywebrblyhlxjrthoooltehrmdhqhuodjmsjwcgrfnttiitpmqvbhlafwtzyikc"
},
{
"input": "20\ngggggllglgllltgtlglttstsgtttsslhhlssghgagtlsaghhoggtfgsaahtotdodthfltdxggxislnttlanxonhnkddtigppitdh",
"output": "NO"
},
{
"input": "16\nkkkkkkyykkynkknkkonyokdndkyonokdywkwykdkdotknnwzkoywiooinkcyzyntcdnitnppnpziomyzdspomoqmomcyrrospppn",
"output": "NO"
},
{
"input": "15\nwwwgggowgwwhoohwgwghwyohhggywhyyodgwydwgggkhgyydqyggkgkpokgthqghidhworprodtcogqkwgtfiodwdurcctkmrfmh",
"output": "YES\nwww\nggg\nowgww\nhoohwgwghw\nyohhggywhyyo\ndgwydwggg\nkhgyyd\nqyggkgk\npokg\nthqgh\nidhwo\nrprodt\ncogqkwgt\nfiodwd\nurcctkmrfmh"
},
{
"input": "15\nnnnnnntnttttttqqnqqynnqqwwnnnwneenhwtyhhoqeyeqyeuthwtnhtpnphhwetjhouhwnpojvvovoswwjryrwerbwwpbvrwvjj",
"output": "YES\nnnnnnn\ntntttttt\nqqnqq\nynnqq\nwwnnnwn\neen\nhwtyhh\noqeyeqye\nuthwtnht\npnphhwet\njhouhwnpoj\nvvovo\nswwj\nryrwer\nbwwpbvrwvjj"
},
{
"input": "15\nvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvv",
"output": "NO"
},
{
"input": "1\niiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiaaaaaiiiiaiaiiiiaaiaiiiaiiaiaaiaiiaiiiiiaiiiaiiiaiaiaai",
"output": "YES\niiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiaaaaaiiiiaiaiiiiaaiaiiiaiiaiaaiaiiaiiiiiaiiiaiiiaiaiaai"
},
{
"input": "26\nvvvnnsnnnpsnnswwspncvshtncwphaphmwnwkhvvhuvctvnehemowkmtzissswjaxuuvphzrmfzihamdqmmyhhijbitlipgltyy",
"output": "YES\nvvv\nnn\nsnnn\npsnns\nwwspn\ncvs\nh\ntncwph\naph\nmwnw\nkhvvh\nuvctvn\nehem\nowkmt\nz\nisssw\nja\nxuuvphz\nrm\nfziham\nd\nqmm\nyhhij\nbit\nlip\ngltyy"
},
{
"input": "26\njexzsbwaih",
"output": "NO"
},
{
"input": "1\nk",
"output": "YES\nk"
},
{
"input": "1\nzz",
"output": "YES\nzz"
},
{
"input": "3\nziw",
"output": "YES\nz\ni\nw"
},
{
"input": "26\ntjmbyqwuahlixegopkzrfndcsv",
"output": "YES\nt\nj\nm\nb\ny\nq\nw\nu\na\nh\nl\ni\nx\ne\ng\no\np\nk\nz\nr\nf\nn\nd\nc\ns\nv"
},
{
"input": "25\nvobekscyadzqwnjxruplifmthg",
"output": "YES\nv\no\nb\ne\nk\ns\nc\ny\na\nd\nz\nq\nw\nn\nj\nx\nr\nu\np\nl\ni\nf\nm\nt\nhg"
},
{
"input": "26\nlllplzkkzflzflffzznnnnfgflqlttlmtnkzlztskngyymitqagattkdllyutzimsrskpapcmuupjdopxqlnhqcscwvdtxbflefy",
"output": "YES\nlll\npl\nz\nkkz\nflzflffzz\nnnnnf\ngfl\nql\nttl\nmtnkzlzt\nskng\nyym\nitq\nagattk\ndlly\nutzims\nrskpap\ncmuup\njd\nop\nxqln\nhqcsc\nw\nvdtx\nbfl\nefy"
},
{
"input": "25\nkkrrkrkrkrsrskpskbrppdsdbgbkrbllkbswdwcchgskmkhwiidicczlscsodtjglxbmeotzxnmbjmoqgkquglaoxgcykxvbhdi",
"output": "YES\nkk\nrrkrkrkr\nsrsk\npsk\nbrpp\ndsdb\ngbkrb\nllkbs\nwdw\ncc\nhgsk\nmkhw\niidicc\nzlscs\nod\nt\njgl\nxbm\neotzx\nnmbjmo\nqgkq\nugl\naoxgc\nykx\nvbhdi"
},
{
"input": "25\nuuuuuccpucubccbupxubcbpujiliwbpqbpyiweuywaxwqasbsllwehceruytjvphytraawgbjmerfeymoayujqranlvkpkiypadr",
"output": "YES\nuuuuu\ncc\npucu\nbccbup\nxubcbpu\nj\ni\nli\nwbp\nqbp\nyiw\neuyw\naxwqa\nsbsllwe\nhce\nruy\ntj\nvphytraaw\ngbj\nmer\nfeym\noayujqra\nnlv\nkpkiypa\ndr"
},
{
"input": "26\nxxjxodrogovufvohrodliretxxyjqnrbzmicorptkjafiwmsbwml",
"output": "YES\nxx\njx\no\nd\nro\ngo\nv\nu\nfvo\nhrod\nl\nir\ne\ntxx\nyj\nq\nnr\nb\nz\nmi\ncor\npt\nkj\nafi\nwm\nsbwml"
},
{
"input": "26\npjhsxjbvkqntwmsdnrguecaofylzti",
"output": "YES\np\nj\nh\ns\nxj\nb\nv\nk\nq\nn\nt\nw\nms\ndn\nr\ng\nu\ne\nc\na\no\nf\ny\nl\nzt\ni"
},
{
"input": "25\nrrrrqqwrlqrwglrlylwhrrwyvrhvzgvqahrhgsvavtggyduayivxzgeicinlnrkapoepbsfyjjrt",
"output": "YES\nrrrr\nqq\nwr\nlqrw\nglrl\nylw\nhrrwy\nvrhv\nzgvq\nahrhg\nsvav\ntggy\nd\nuay\niv\nxzg\nei\nci\nnlnr\nka\np\noep\nbs\nfy\njjrt"
},
{
"input": "26\ncccccccaacwwaxxaacczacnnnqqwnaggzqrwagcnabxnrcvgjqjamqzgdntzanaxvjfwqlvdttuzjoxiwtkqvrydospmpeirhg",
"output": "YES\nccccccc\naac\nwwa\nxxaacc\nzac\nnnn\nqqwna\nggzq\nrwagcna\nbxnrc\nvg\njqja\nmqzg\ndn\ntzanaxvj\nfwq\nlvdtt\nuzj\nox\niwt\nkqvr\nydo\ns\npmp\neir\nhg"
},
{
"input": "4\nsssssssssssssssssssssssssslsslslsllsslssslslssllaaslsaalsasaassllasasalrlrslarlaarlsrsaslasarlr",
"output": "YES\nssssssssssssssssssssssssss\nlsslslsllsslssslslssll\naaslsaalsasaassllasasal\nrlrslarlaarlsrsaslasarlr"
},
{
"input": "26\na",
"output": "NO"
},
{
"input": "26\nab",
"output": "NO"
},
{
"input": "2\nab",
"output": "YES\na\nb"
}
] | 1,434,624,882 | 2,147,483,647 | Python 3 | OK | TESTS | 33 | 62 | 0 | k = int(input())
q = input()
s = set()
a = []
for i in range(len(q)):
if not q[i] in s:
s.add(q[i])
a += [i]
if len(a) == k:
print("YES")
for j in range(k - 1):
print(q[a[j]:a[j + 1]])
print(q[a[-1]:])
exit()
print("NO") | Title: Set of Strings
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given a string *q*. A sequence of *k* strings *s*1,<=*s*2,<=...,<=*s**k* is called beautiful, if the concatenation of these strings is string *q* (formally, *s*1<=+<=*s*2<=+<=...<=+<=*s**k*<==<=*q*) and the first characters of these strings are distinct.
Find any beautiful sequence of strings or determine that the beautiful sequence doesn't exist.
Input Specification:
The first line contains a positive integer *k* (1<=≤<=*k*<=≤<=26) — the number of strings that should be in a beautiful sequence.
The second line contains string *q*, consisting of lowercase Latin letters. The length of the string is within range from 1 to 100, inclusive.
Output Specification:
If such sequence doesn't exist, then print in a single line "NO" (without the quotes). Otherwise, print in the first line "YES" (without the quotes) and in the next *k* lines print the beautiful sequence of strings *s*1,<=*s*2,<=...,<=*s**k*.
If there are multiple possible answers, print any of them.
Demo Input:
['1\nabca\n', '2\naaacas\n', '4\nabc\n']
Demo Output:
['YES\nabca\n', 'YES\naaa\ncas\n', 'NO\n']
Note:
In the second sample there are two possible answers: {"*aaaca*", "*s*"} and {"*aaa*", "*cas*"}. | ```python
k = int(input())
q = input()
s = set()
a = []
for i in range(len(q)):
if not q[i] in s:
s.add(q[i])
a += [i]
if len(a) == k:
print("YES")
for j in range(k - 1):
print(q[a[j]:a[j + 1]])
print(q[a[-1]:])
exit()
print("NO")
``` | 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"
}
] | 1,691,672,179 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 30 | 0 | a=int(input())
g=str(a)
z=g.count("4")
t=g.count("7")
lista=("7","4","44","77","47","74","777","444","447","474","744","747","774","477")
for i in lista:
if a % int(i)==0:
print("YES")
if (z+t)==len(g):
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
a=int(input())
g=str(a)
z=g.count("4")
t=g.count("7")
lista=("7","4","44","77","47","74","777","444","447","474","744","747","774","477")
for i in lista:
if a % int(i)==0:
print("YES")
if (z+t)==len(g):
print("YES")
else:
print("NO")
``` | 0 | |
159 | E | Zebra Tower | PROGRAMMING | 1,700 | [
"*special",
"data structures",
"greedy",
"sortings"
] | null | null | Little Janet likes playing with cubes. Actually, she likes to play with anything whatsoever, cubes or tesseracts, as long as they are multicolored. Each cube is described by two parameters — color *c**i* and size *s**i*. A Zebra Tower is a tower that consists of cubes of exactly two colors. Besides, the colors of the cubes in the tower must alternate (colors of adjacent cubes must differ). The Zebra Tower should have at least two cubes. There are no other limitations. The figure below shows an example of a Zebra Tower.
A Zebra Tower's height is the sum of sizes of all cubes that form the tower. Help little Janet build the Zebra Tower of the maximum possible height, using the available cubes. | The first line contains an integer *n* (2<=≤<=*n*<=≤<=105) — the number of cubes. Next *n* lines contain the descriptions of the cubes, one description per line. A cube description consists of two space-separated integers *c**i* and *s**i* (1<=≤<=*c**i*,<=*s**i*<=≤<=109) — the *i*-th cube's color and size, correspondingly. It is guaranteed that there are at least two cubes of different colors. | Print the description of the Zebra Tower of the maximum height in the following form. In the first line print the tower's height, in the second line print the number of cubes that form the tower, and in the third line print the space-separated indices of cubes in the order in which they follow in the tower from the bottom to the top. Assume that the cubes are numbered from 1 to *n* in the order in which they were given in the input.
If there are several existing Zebra Towers with maximum heights, it is allowed to print any of them.
Please do not use the %lld specificator to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams or the %I64d specificator. | [
"4\n1 2\n1 3\n2 4\n3 3\n",
"2\n1 1\n2 1\n"
] | [
"9\n3\n2 3 1 \n",
"2\n2\n2 1 \n"
] | none | 2,500 | [
{
"input": "4\n1 2\n1 3\n2 4\n3 3",
"output": "9\n3\n2 3 1 "
},
{
"input": "2\n1 1\n2 1",
"output": "2\n2\n2 1 "
},
{
"input": "3\n1 2\n2 2\n2 1",
"output": "5\n3\n2 1 3 "
},
{
"input": "4\n2 1\n2 1\n1 1\n1 2",
"output": "5\n4\n4 2 3 1 "
},
{
"input": "6\n1 1\n1 1\n2 2\n1 2\n1 2\n2 2",
"output": "9\n5\n5 6 4 3 2 "
},
{
"input": "20\n1 2\n3 2\n4 2\n2 2\n5 2\n2 5\n3 2\n3 4\n4 4\n5 3\n2 1\n5 2\n5 3\n2 1\n5 5\n2 3\n1 5\n5 2\n3 4\n3 3",
"output": "32\n11\n15 19 13 8 10 20 18 7 12 2 5 "
},
{
"input": "100\n2 5\n1 4\n1 2\n5 4\n1 3\n5 2\n4 4\n5 2\n3 5\n2 2\n5 5\n4 5\n5 3\n5 3\n1 1\n1 3\n5 3\n2 2\n3 1\n4 5\n5 1\n3 5\n3 5\n1 1\n3 3\n3 3\n2 3\n2 1\n5 3\n3 3\n1 2\n3 2\n1 3\n4 1\n4 1\n5 4\n2 4\n3 4\n1 4\n4 3\n4 4\n1 3\n5 3\n3 1\n5 4\n1 5\n4 5\n2 3\n5 5\n2 5\n4 5\n3 4\n1 5\n1 1\n5 1\n5 3\n5 1\n2 4\n3 1\n3 2\n2 3\n2 4\n4 5\n4 2\n1 1\n3 3\n1 4\n2 2\n1 2\n4 4\n4 1\n4 1\n2 5\n4 3\n5 5\n4 1\n1 5\n5 4\n2 5\n5 5\n1 2\n1 4\n5 1\n5 3\n5 2\n4 3\n1 3\n5 4\n1 5\n3 4\n5 3\n3 1\n3 3\n5 4\n4 2\n2 5\n2 4\n1 3\n1 4\n3 1",
"output": "147\n47\n80 89 75 77 49 53 11 46 94 99 88 82 78 67 45 39 36 2 4 98 91 87 84 42 56 33 43 16 29 5 17 81 14 69 13 31 85 3 8 65 6 54 83 24 57 15 55 "
},
{
"input": "12\n1 3\n2 4\n2 1\n2 1\n3 1\n3 1\n3 1\n3 1\n3 1\n3 1\n3 1\n3 1",
"output": "10\n7\n12 2 11 4 10 3 9 "
},
{
"input": "4\n2 1000000000\n2 1000000000\n2 1000000000\n1 1",
"output": "2000000001\n3\n3 4 2 "
}
] | 1,451,724,977 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 46 | 307,200 | def main():
mode="filee"
if mode=="file":f=open("test.txt","r")
get = lambda :[int(x) for x in (f.readline() if mode=="file" else input()).split()]
[n]=get()
p = {}
for i in range(n):
[a,b] = get()
if a not in p:
p[a]=[]
p[a].append([b,i+1])
h=[]
for i in p:
s=0
for j in p[i]:
s+=j[0]
h.append([s,i])
h.sort()
print(h[-1][0] + h[-2][0])
print(len(p[h[-1][1]]) + len(p[h[-2][1]]))
for i in p[h[-1][1]]:
print(i[1],end=' ')
for i in p[h[-2][1]]:
print(i[1],end=' ')
if mode=="file":f.close()
if __name__=="__main__":
main()
| Title: Zebra Tower
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Little Janet likes playing with cubes. Actually, she likes to play with anything whatsoever, cubes or tesseracts, as long as they are multicolored. Each cube is described by two parameters — color *c**i* and size *s**i*. A Zebra Tower is a tower that consists of cubes of exactly two colors. Besides, the colors of the cubes in the tower must alternate (colors of adjacent cubes must differ). The Zebra Tower should have at least two cubes. There are no other limitations. The figure below shows an example of a Zebra Tower.
A Zebra Tower's height is the sum of sizes of all cubes that form the tower. Help little Janet build the Zebra Tower of the maximum possible height, using the available cubes.
Input Specification:
The first line contains an integer *n* (2<=≤<=*n*<=≤<=105) — the number of cubes. Next *n* lines contain the descriptions of the cubes, one description per line. A cube description consists of two space-separated integers *c**i* and *s**i* (1<=≤<=*c**i*,<=*s**i*<=≤<=109) — the *i*-th cube's color and size, correspondingly. It is guaranteed that there are at least two cubes of different colors.
Output Specification:
Print the description of the Zebra Tower of the maximum height in the following form. In the first line print the tower's height, in the second line print the number of cubes that form the tower, and in the third line print the space-separated indices of cubes in the order in which they follow in the tower from the bottom to the top. Assume that the cubes are numbered from 1 to *n* in the order in which they were given in the input.
If there are several existing Zebra Towers with maximum heights, it is allowed to print any of them.
Please do not use the %lld specificator to read or write 64-bit integers in С++. It is preferred to use the cin, cout streams or the %I64d specificator.
Demo Input:
['4\n1 2\n1 3\n2 4\n3 3\n', '2\n1 1\n2 1\n']
Demo Output:
['9\n3\n2 3 1 \n', '2\n2\n2 1 \n']
Note:
none | ```python
def main():
mode="filee"
if mode=="file":f=open("test.txt","r")
get = lambda :[int(x) for x in (f.readline() if mode=="file" else input()).split()]
[n]=get()
p = {}
for i in range(n):
[a,b] = get()
if a not in p:
p[a]=[]
p[a].append([b,i+1])
h=[]
for i in p:
s=0
for j in p[i]:
s+=j[0]
h.append([s,i])
h.sort()
print(h[-1][0] + h[-2][0])
print(len(p[h[-1][1]]) + len(p[h[-2][1]]))
for i in p[h[-1][1]]:
print(i[1],end=' ')
for i in p[h[-2][1]]:
print(i[1],end=' ')
if mode=="file":f.close()
if __name__=="__main__":
main()
``` | 0 | |
3 | C | Tic-tac-toe | PROGRAMMING | 1,800 | [
"brute force",
"games",
"implementation"
] | C. Tic-tac-toe | 1 | 64 | Certainly, everyone is familiar with tic-tac-toe game. The rules are very simple indeed. Two players take turns marking the cells in a 3<=×<=3 grid (one player always draws crosses, the other — noughts). The player who succeeds first in placing three of his marks in a horizontal, vertical or diagonal line wins, and the game is finished. The player who draws crosses goes first. If the grid is filled, but neither Xs, nor 0s form the required line, a draw is announced.
You are given a 3<=×<=3 grid, each grid cell is empty, or occupied by a cross or a nought. You have to find the player (first or second), whose turn is next, or print one of the verdicts below:
- illegal — if the given board layout can't appear during a valid game; - the first player won — if in the given board layout the first player has just won; - the second player won — if in the given board layout the second player has just won; - draw — if the given board layout has just let to a draw. | The input consists of three lines, each of the lines contains characters ".", "X" or "0" (a period, a capital letter X, or a digit zero). | Print one of the six verdicts: first, second, illegal, the first player won, the second player won or draw. | [
"X0X\n.0.\n.X.\n"
] | [
"second\n"
] | none | 0 | [
{
"input": "X0X\n.0.\n.X.",
"output": "second"
},
{
"input": "0.X\nXX.\n000",
"output": "illegal"
},
{
"input": "XXX\n.0.\n000",
"output": "illegal"
},
{
"input": "XXX\n...\n000",
"output": "illegal"
},
{
"input": "X.X\nX..\n00.",
"output": "second"
},
{
"input": "X.X\nX.0\n0.0",
"output": "first"
},
{
"input": "XXX\nX00\nX00",
"output": "the first player won"
},
{
"input": "000\nX.X\nX.X",
"output": "illegal"
},
{
"input": "XXX\n0.0\n0..",
"output": "illegal"
},
{
"input": "X0X\n0X0\nX0X",
"output": "the first player won"
},
{
"input": "XX.\nX0X\nX..",
"output": "illegal"
},
{
"input": "X0X\n0X0\nX..",
"output": "the first player won"
},
{
"input": "XX0\n0..\n000",
"output": "illegal"
},
{
"input": "XXX\n0..\n.0.",
"output": "the first player won"
},
{
"input": "XXX\nX..\n.00",
"output": "illegal"
},
{
"input": "X00\n0.0\nXX0",
"output": "illegal"
},
{
"input": "0.0\n0XX\n..0",
"output": "illegal"
},
{
"input": ".00\nX.X\n0..",
"output": "illegal"
},
{
"input": "..0\n.00\n.0X",
"output": "illegal"
},
{
"input": "..0\n0..\n00X",
"output": "illegal"
},
{
"input": "..0\n.XX\nX..",
"output": "illegal"
},
{
"input": "0.X\n0X0\n.00",
"output": "illegal"
},
{
"input": "..X\n0X0\n0X.",
"output": "first"
},
{
"input": "0X0\nX..\nX.0",
"output": "first"
},
{
"input": ".0.\nX.X\n0..",
"output": "first"
},
{
"input": "0X0\n00X\n.00",
"output": "illegal"
},
{
"input": ".0.\n.X0\nX..",
"output": "first"
},
{
"input": "00X\n0.X\n00X",
"output": "illegal"
},
{
"input": "00X\n0XX\n0X.",
"output": "the second player won"
},
{
"input": "X00\n..0\nX.X",
"output": "first"
},
{
"input": "X00\nX00\n.X0",
"output": "illegal"
},
{
"input": "X0X\n.X0\n0..",
"output": "first"
},
{
"input": "..0\nXXX\n000",
"output": "illegal"
},
{
"input": "XXX\n...\n.0.",
"output": "illegal"
},
{
"input": "0..\n000\nX0X",
"output": "illegal"
},
{
"input": ".00\n0X.\n0.0",
"output": "illegal"
},
{
"input": "X..\nX00\n0.0",
"output": "illegal"
},
{
"input": ".X0\nXX0\nX.X",
"output": "illegal"
},
{
"input": "X.X\n0.0\nX..",
"output": "second"
},
{
"input": "00X\n.00\n..0",
"output": "illegal"
},
{
"input": "..0\n0.X\n00.",
"output": "illegal"
},
{
"input": "0.X\nX0X\n.X0",
"output": "illegal"
},
{
"input": "0X.\n.X.\n0X0",
"output": "illegal"
},
{
"input": "00.\nX0.\n..X",
"output": "illegal"
},
{
"input": "..X\n.00\nXX.",
"output": "second"
},
{
"input": ".00\n.0.\n.X.",
"output": "illegal"
},
{
"input": "XX0\nX.0\nXX0",
"output": "illegal"
},
{
"input": "00.\n00.\nX.X",
"output": "illegal"
},
{
"input": "X00\nX.0\nX.0",
"output": "illegal"
},
{
"input": "0X.\n0XX\n000",
"output": "illegal"
},
{
"input": "00.\n00.\n.X.",
"output": "illegal"
},
{
"input": "X0X\n00.\n0.X",
"output": "illegal"
},
{
"input": "XX0\nXXX\n0X0",
"output": "illegal"
},
{
"input": "XX0\n..X\nXX0",
"output": "illegal"
},
{
"input": "0X.\n..X\nX..",
"output": "illegal"
},
{
"input": "...\nX0.\nXX0",
"output": "second"
},
{
"input": "..X\n.0.\n0..",
"output": "illegal"
},
{
"input": "00X\nXX.\n00X",
"output": "first"
},
{
"input": "..0\nXX0\n..X",
"output": "second"
},
{
"input": ".0.\n.00\nX00",
"output": "illegal"
},
{
"input": "X00\n.XX\n00.",
"output": "illegal"
},
{
"input": ".00\n0.X\n000",
"output": "illegal"
},
{
"input": "X0.\n..0\nX.0",
"output": "illegal"
},
{
"input": "X0X\n.XX\n00.",
"output": "second"
},
{
"input": "0X.\n00.\n.X.",
"output": "illegal"
},
{
"input": ".0.\n...\n0.0",
"output": "illegal"
},
{
"input": "..X\nX00\n0.0",
"output": "illegal"
},
{
"input": "0XX\n...\nX0.",
"output": "second"
},
{
"input": "X.X\n0X.\n.0X",
"output": "illegal"
},
{
"input": "XX0\nX.X\n00.",
"output": "second"
},
{
"input": ".0X\n.00\n00.",
"output": "illegal"
},
{
"input": ".XX\nXXX\n0..",
"output": "illegal"
},
{
"input": "XX0\n.X0\n.0.",
"output": "first"
},
{
"input": "X00\n0.X\nX..",
"output": "first"
},
{
"input": "X..\n.X0\nX0.",
"output": "second"
},
{
"input": ".0X\nX..\nXXX",
"output": "illegal"
},
{
"input": "X0X\nXXX\nX.X",
"output": "illegal"
},
{
"input": ".00\nX0.\n00X",
"output": "illegal"
},
{
"input": "0XX\n.X0\n0.0",
"output": "illegal"
},
{
"input": "00X\nXXX\n..0",
"output": "the first player won"
},
{
"input": "X0X\n...\n.X.",
"output": "illegal"
},
{
"input": ".X0\n...\n0X.",
"output": "first"
},
{
"input": "X..\n0X0\nX.0",
"output": "first"
},
{
"input": "..0\n.00\nX.0",
"output": "illegal"
},
{
"input": ".XX\n.0.\nX0X",
"output": "illegal"
},
{
"input": "00.\n0XX\n..0",
"output": "illegal"
},
{
"input": ".0.\n00.\n00.",
"output": "illegal"
},
{
"input": "00.\n000\nX.X",
"output": "illegal"
},
{
"input": "0X0\n.X0\n.X.",
"output": "illegal"
},
{
"input": "00X\n0..\n0..",
"output": "illegal"
},
{
"input": ".X.\n.X0\nX.0",
"output": "second"
},
{
"input": ".0.\n0X0\nX0X",
"output": "illegal"
},
{
"input": "...\nX.0\n0..",
"output": "illegal"
},
{
"input": "..0\nXX.\n00X",
"output": "first"
},
{
"input": "0.X\n.0X\nX00",
"output": "illegal"
},
{
"input": "..X\n0X.\n.0.",
"output": "first"
},
{
"input": "..X\nX.0\n.0X",
"output": "second"
},
{
"input": "X0.\n.0X\nX0X",
"output": "illegal"
},
{
"input": "...\n.0.\n.X0",
"output": "illegal"
},
{
"input": ".X0\nXX0\n0..",
"output": "first"
},
{
"input": "0X.\n...\nX..",
"output": "second"
},
{
"input": ".0.\n0.0\n0.X",
"output": "illegal"
},
{
"input": "XX.\n.X0\n.0X",
"output": "illegal"
},
{
"input": ".0.\nX0X\nX00",
"output": "illegal"
},
{
"input": "0X.\n.X0\nX..",
"output": "second"
},
{
"input": "..0\n0X.\n000",
"output": "illegal"
},
{
"input": "0.0\nX.X\nXX.",
"output": "illegal"
},
{
"input": ".X.\n.XX\nX0.",
"output": "illegal"
},
{
"input": "X.X\n.XX\n0X.",
"output": "illegal"
},
{
"input": "X.0\n0XX\n..0",
"output": "first"
},
{
"input": "X.0\n0XX\n.X0",
"output": "second"
},
{
"input": "X00\n0XX\n.X0",
"output": "first"
},
{
"input": "X00\n0XX\nXX0",
"output": "draw"
},
{
"input": "X00\n0XX\n0X0",
"output": "illegal"
},
{
"input": "XXX\nXXX\nXXX",
"output": "illegal"
},
{
"input": "000\n000\n000",
"output": "illegal"
},
{
"input": "XX0\n00X\nXX0",
"output": "draw"
},
{
"input": "X00\n00X\nXX0",
"output": "illegal"
},
{
"input": "X.0\n00.\nXXX",
"output": "the first player won"
},
{
"input": "X..\nX0.\nX0.",
"output": "the first player won"
},
{
"input": ".XX\n000\nXX0",
"output": "the second player won"
},
{
"input": "X0.\nX.X\nX00",
"output": "the first player won"
},
{
"input": "00X\nX00\nXXX",
"output": "the first player won"
},
{
"input": "XXX\n.00\nX0.",
"output": "the first player won"
},
{
"input": "XX0\n000\nXX.",
"output": "the second player won"
},
{
"input": ".X0\n0.0\nXXX",
"output": "the first player won"
},
{
"input": "0XX\nX00\n0XX",
"output": "draw"
},
{
"input": "0XX\nX0X\n00X",
"output": "the first player won"
},
{
"input": "XX0\n0XX\n0X0",
"output": "the first player won"
},
{
"input": "0X0\nX0X\nX0X",
"output": "draw"
},
{
"input": "X0X\n0XX\n00X",
"output": "the first player won"
},
{
"input": "0XX\nX0.\nX00",
"output": "the second player won"
},
{
"input": "X.0\n0X0\nXX0",
"output": "the second player won"
},
{
"input": "X0X\nX0X\n0X0",
"output": "draw"
},
{
"input": "X.0\n00X\n0XX",
"output": "the second player won"
},
{
"input": "00X\nX0X\n.X0",
"output": "the second player won"
},
{
"input": "X0X\n.00\nX0X",
"output": "the second player won"
},
{
"input": "0XX\nX00\nX0X",
"output": "draw"
},
{
"input": "000\nX0X\n.XX",
"output": "the second player won"
},
{
"input": "0.0\n0.X\nXXX",
"output": "the first player won"
},
{
"input": "X.0\nX0.\n0X.",
"output": "the second player won"
},
{
"input": "X0X\n0X0\n..X",
"output": "the first player won"
},
{
"input": "0X0\nXX0\n.X.",
"output": "the first player won"
},
{
"input": "X0.\n.X.\n0.X",
"output": "the first player won"
},
{
"input": "0XX\nX00\n.X0",
"output": "the second player won"
},
{
"input": "0.0\nXXX\n0.X",
"output": "the first player won"
},
{
"input": ".0X\n.X.\nX.0",
"output": "the first player won"
},
{
"input": "XXX\nX.0\n0.0",
"output": "the first player won"
},
{
"input": "XX0\nX..\nX00",
"output": "the first player won"
},
{
"input": "XXX\n00X\n00X",
"output": "the first player won"
},
{
"input": "X00\n00X\nXXX",
"output": "the first player won"
},
{
"input": "0X0\nX0X\n0X.",
"output": "the second player won"
},
{
"input": "XX0\nX00\n0X.",
"output": "the second player won"
},
{
"input": "..X\n0X0\nX..",
"output": "the first player won"
},
{
"input": "X0.\n00.\nXXX",
"output": "the first player won"
},
{
"input": "0.X\nX00\nXX0",
"output": "the second player won"
},
{
"input": "X0.\n0X.\n..X",
"output": "the first player won"
},
{
"input": "00X\nX0.\nXX0",
"output": "the second player won"
},
{
"input": "XX.\n000\n0XX",
"output": "the second player won"
},
{
"input": "..X\n0.X\n.0X",
"output": "the first player won"
},
{
"input": "X00\n.0X\n0XX",
"output": "the second player won"
},
{
"input": "00X\n0X.\nXX.",
"output": "the first player won"
},
{
"input": "X00\nXX.\n0.X",
"output": "the first player won"
},
{
"input": "XXX\n00X\n0X0",
"output": "the first player won"
},
{
"input": "X00\nXX0\n0XX",
"output": "the first player won"
},
{
"input": "0X0\nX00\nXXX",
"output": "the first player won"
},
{
"input": "XX0\nX00\n.X0",
"output": "the second player won"
}
] | 1,680,988,513 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 1 | 60 | 0 | def check_win(board, player):
for i in range(3):
# Check rows
if all(board[i][j] == player for j in range(3)):
return True
# Check columns
if all(board[j][i] == player for j in range(3)):
return True
# Check diagonals
if all(board[i][i] == player for i in range(3)):
return True
if all(board[i][2-i] == player for i in range(3)):
return True
return False
def check_board(board):
num_x = sum(row.count('X') for row in board)
num_o = sum(row.count('0') for row in board)
if abs(num_x - num_o) > 1:
return "illegal"
if check_win(board, 'X'):
if check_win(board, '0'):
return "illegal"
return "the first player won"
if check_win(board, '0'):
if check_win(board, 'X'):
return "illegal"
return "the second player won"
if any('-' in row for row in board):
return "first" if num_x == num_o else "second"
return "draw"
# Example usage
board = [
["X", "0", "-"],
["-", "X", "-"],
["-", "0", "0"]
]
print(check_board(board))
| Title: Tic-tac-toe
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
Certainly, everyone is familiar with tic-tac-toe game. The rules are very simple indeed. Two players take turns marking the cells in a 3<=×<=3 grid (one player always draws crosses, the other — noughts). The player who succeeds first in placing three of his marks in a horizontal, vertical or diagonal line wins, and the game is finished. The player who draws crosses goes first. If the grid is filled, but neither Xs, nor 0s form the required line, a draw is announced.
You are given a 3<=×<=3 grid, each grid cell is empty, or occupied by a cross or a nought. You have to find the player (first or second), whose turn is next, or print one of the verdicts below:
- illegal — if the given board layout can't appear during a valid game; - the first player won — if in the given board layout the first player has just won; - the second player won — if in the given board layout the second player has just won; - draw — if the given board layout has just let to a draw.
Input Specification:
The input consists of three lines, each of the lines contains characters ".", "X" or "0" (a period, a capital letter X, or a digit zero).
Output Specification:
Print one of the six verdicts: first, second, illegal, the first player won, the second player won or draw.
Demo Input:
['X0X\n.0.\n.X.\n']
Demo Output:
['second\n']
Note:
none | ```python
def check_win(board, player):
for i in range(3):
# Check rows
if all(board[i][j] == player for j in range(3)):
return True
# Check columns
if all(board[j][i] == player for j in range(3)):
return True
# Check diagonals
if all(board[i][i] == player for i in range(3)):
return True
if all(board[i][2-i] == player for i in range(3)):
return True
return False
def check_board(board):
num_x = sum(row.count('X') for row in board)
num_o = sum(row.count('0') for row in board)
if abs(num_x - num_o) > 1:
return "illegal"
if check_win(board, 'X'):
if check_win(board, '0'):
return "illegal"
return "the first player won"
if check_win(board, '0'):
if check_win(board, 'X'):
return "illegal"
return "the second player won"
if any('-' in row for row in board):
return "first" if num_x == num_o else "second"
return "draw"
# Example usage
board = [
["X", "0", "-"],
["-", "X", "-"],
["-", "0", "0"]
]
print(check_board(board))
``` | 0 |
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"
}
] | 1,494,510,133 | 2,147,483,647 | Python 3 | OK | TESTS | 34 | 62 | 0 |
n =int( input())
a = list(map(int, input().split()))
if a[0] > 15:
print(15)
exit()
s = a[0] + 15
for i in range(n - 1):
if ((a[i+1] - a[i]) > 15):
s = a[i] + 15
break
elif i == n - 2:
s = a[i + 1] + 15
if s > 90:
print(90)
else:
print(s)
| 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
n =int( input())
a = list(map(int, input().split()))
if a[0] > 15:
print(15)
exit()
s = a[0] + 15
for i in range(n - 1):
if ((a[i+1] - a[i]) > 15):
s = a[i] + 15
break
elif i == n - 2:
s = a[i + 1] + 15
if s > 90:
print(90)
else:
print(s)
``` | 3 | |
894 | A | QAQ | PROGRAMMING | 800 | [
"brute force",
"dp"
] | null | null | "QAQ" is a word to denote an expression of crying. Imagine "Q" as eyes with tears and "A" as a mouth.
Now Diamond has given Bort a string consisting of only uppercase English letters of length *n*. There is a great number of "QAQ" in the string (Diamond is so cute!).
Bort wants to know how many subsequences "QAQ" are in the string Diamond has given. Note that the letters "QAQ" don't have to be consecutive, but the order of letters should be exact. | The only line contains a string of length *n* (1<=≤<=*n*<=≤<=100). It's guaranteed that the string only contains uppercase English letters. | Print a single integer — the number of subsequences "QAQ" in the string. | [
"QAQAQYSYIOIWIN\n",
"QAQQQZZYNOIWIN\n"
] | [
"4\n",
"3\n"
] | In the first example there are 4 subsequences "QAQ": "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN". | 500 | [
{
"input": "QAQAQYSYIOIWIN",
"output": "4"
},
{
"input": "QAQQQZZYNOIWIN",
"output": "3"
},
{
"input": "QA",
"output": "0"
},
{
"input": "IAQVAQZLQBQVQFTQQQADAQJA",
"output": "24"
},
{
"input": "QQAAQASGAYAAAAKAKAQIQEAQAIAAIAQQQQQ",
"output": "378"
},
{
"input": "AMVFNFJIAVNQJWIVONQOAOOQSNQSONOASONAONQINAONAOIQONANOIQOANOQINAONOQINAONOXJCOIAQOAOQAQAQAQAQWWWAQQAQ",
"output": "1077"
},
{
"input": "AAQQAXBQQBQQXBNQRJAQKQNAQNQVDQASAGGANQQQQTJFFQQQTQQA",
"output": "568"
},
{
"input": "KAZXAVLPJQBQVQQQQQAPAQQGQTQVZQAAAOYA",
"output": "70"
},
{
"input": "W",
"output": "0"
},
{
"input": "DBA",
"output": "0"
},
{
"input": "RQAWNACASAAKAGAAAAQ",
"output": "10"
},
{
"input": "QJAWZAAOAAGIAAAAAOQATASQAEAAAAQFQQHPA",
"output": "111"
},
{
"input": "QQKWQAQAAAAAAAAGAAVAQUEQQUMQMAQQQNQLAMAAAUAEAAEMAAA",
"output": "411"
},
{
"input": "QQUMQAYAUAAGWAAAQSDAVAAQAAAASKQJJQQQQMAWAYYAAAAAAEAJAXWQQ",
"output": "625"
},
{
"input": "QORZOYAQ",
"output": "1"
},
{
"input": "QCQAQAGAWAQQQAQAVQAQQQQAQAQQQAQAAATQAAVAAAQQQQAAAUUQAQQNQQWQQWAQAAQQKQYAQAAQQQAAQRAQQQWBQQQQAPBAQGQA",
"output": "13174"
},
{
"input": "QQAQQAKQFAQLQAAWAMQAZQAJQAAQQOACQQAAAYANAQAQQAQAAQQAOBQQJQAQAQAQQQAAAAABQQQAVNZAQQQQAMQQAFAAEAQAQHQT",
"output": "10420"
},
{
"input": "AQEGQHQQKQAQQPQKAQQQAAAAQQQAQEQAAQAAQAQFSLAAQQAQOQQAVQAAAPQQAWAQAQAFQAXAQQQQTRLOQAQQJQNQXQQQQSQVDQQQ",
"output": "12488"
},
{
"input": "QNQKQQQLASQBAVQQQQAAQQOQRJQQAQQQEQZUOANAADAAQQJAQAQARAAAQQQEQBHTQAAQAAAAQQMKQQQIAOJJQQAQAAADADQUQQQA",
"output": "9114"
},
{
"input": "QQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQ",
"output": "35937"
},
{
"input": "AMQQAAQAAQAAAAAAQQQBOAAANAAKQJCYQAE",
"output": "254"
},
{
"input": "AYQBAEQGAQEOAKGIXLQJAIAKQAAAQPUAJAKAATFWQQAOQQQUFQYAQQMQHOKAAJXGFCARAQSATHAUQQAATQJJQDQRAANQQAE",
"output": "2174"
},
{
"input": "AAQXAAQAYQAAAAGAQHVQYAGIVACADFAAQAAAAQZAAQMAKZAADQAQDAAQDAAAMQQOXYAQQQAKQBAAQQKAXQBJZDDLAAHQQ",
"output": "2962"
},
{
"input": "AYQQYAVAMNIAUAAKBBQVACWKTQSAQZAAQAAASZJAWBCAALAARHACQAKQQAQAARPAQAAQAQAAZQUSHQAMFVFZQQQQSAQQXAA",
"output": "2482"
},
{
"input": "LQMAQQARQAQBJQQQAGAAZQQXALQQAARQAQQQQAAQQAQQQAQQCAQQAQQAYQQQRAAZATQALYQQAAHHAAQHAAAAAAAAQQMAAQNAKQ",
"output": "7768"
},
{
"input": "MAQQWAQOYQMAAAQAQPQZAOAAQAUAQNAAQAAAITQSAQAKAQKAQQWSQAAQQAGUCDQMQWKQUXKWQQAAQQAAQQZQDQQQAABXQUUXQOA",
"output": "5422"
},
{
"input": "QTAAQDAQXAQQJQQQGAAAQQQQSBQZKAQQAQQQQEAQNUQBZCQLYQZQEQQAAQHQVAORKQVAQYQNASZQAARZAAGAAAAOQDCQ",
"output": "3024"
},
{
"input": "QQWAQQGQQUZQQQLZAAQYQXQVAQFQUAQZUQZZQUKBHSHTQYLQAOQXAQQGAQQTQOAQARQADAJRAAQPQAQQUQAUAMAUVQAAAQQAWQ",
"output": "4527"
},
{
"input": "QQAAQQAQVAQZQQQQAOEAQZPQIBQZACQQAFQQLAAQDATZQANHKYQQAQTAAFQRQAIQAJPWQAQTEIRXAEQQAYWAAAUKQQAQAQQQSQQH",
"output": "6416"
},
{
"input": "AQQQQAQAAQQAQAQAAAAAAAAAQAQAAAAAQAQAQQQAQQQAAAQQQAAAAAAAQAAAAQQQQQQQAQQQQAQAAAQAAAAAQAQAAAAAQAQAAAA",
"output": "14270"
},
{
"input": "AQQQQAQAAQQAQAQAAAAAAAAAQAQAAAAAQAQAQQQAQQQAAAQQQAAAAAAAQAAAAQQQQQQQAQQQQAQAAAQAAAAAQAQAAAAAQ",
"output": "13136"
},
{
"input": "AQQQQAQAAQQAQAQAAAAAAAAAQAQAAAAAQAQAQQQAQQQAAAQQQAAAAAAAQAAAAQQQQQQQAQQQQAQAAAQAAAAAQAQAAAAAQAQAA",
"output": "14270"
},
{
"input": "AQQQQAQAAQQAQAQAAAAAAAAAQAQAAAAAQAQAQQQAQQQAAAQQQAAAAAAAQAAAAQQQQQQQAQQQQAQAAAQAAAAAQAQAAAAAQQAA",
"output": "14231"
},
{
"input": "QQQQQAQAAQQAQAQAAAAAAAAAQAQAAAAAQAQAQQQAQQQAAAQQQAAAAAAAQAAAAQQQQQQQAQQQQAQAAAQAAAAAQAQAAAAAQAQAA",
"output": "15296"
},
{
"input": "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQ",
"output": "0"
},
{
"input": "QQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA",
"output": "0"
},
{
"input": "QQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQ",
"output": "0"
},
{
"input": "QAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQA",
"output": "20825"
},
{
"input": "AQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQAQ",
"output": "20825"
},
{
"input": "Q",
"output": "0"
},
{
"input": "A",
"output": "0"
},
{
"input": "FFF",
"output": "0"
},
{
"input": "AAAAAA",
"output": "0"
}
] | 1,593,440,073 | 2,147,483,647 | PyPy 3 | OK | TESTS | 43 | 171 | 22,016,000 | s = input()
res = 0
for i in range(len(s)):
for j in range(i+1, len(s)):
for k in range(i+1, j+1):
if(s[i] == "Q" and s[k] == "A" and s[j] == "Q"):
res += 1
print(res) | Title: QAQ
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
"QAQ" is a word to denote an expression of crying. Imagine "Q" as eyes with tears and "A" as a mouth.
Now Diamond has given Bort a string consisting of only uppercase English letters of length *n*. There is a great number of "QAQ" in the string (Diamond is so cute!).
Bort wants to know how many subsequences "QAQ" are in the string Diamond has given. Note that the letters "QAQ" don't have to be consecutive, but the order of letters should be exact.
Input Specification:
The only line contains a string of length *n* (1<=≤<=*n*<=≤<=100). It's guaranteed that the string only contains uppercase English letters.
Output Specification:
Print a single integer — the number of subsequences "QAQ" in the string.
Demo Input:
['QAQAQYSYIOIWIN\n', 'QAQQQZZYNOIWIN\n']
Demo Output:
['4\n', '3\n']
Note:
In the first example there are 4 subsequences "QAQ": "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN", "QAQAQYSYIOIWIN". | ```python
s = input()
res = 0
for i in range(len(s)):
for j in range(i+1, len(s)):
for k in range(i+1, j+1):
if(s[i] == "Q" and s[k] == "A" and s[j] == "Q"):
res += 1
print(res)
``` | 3 | |
43 | A | Football | PROGRAMMING | 1,000 | [
"strings"
] | A. Football | 2 | 256 | One day Vasya decided to have a look at the results of Berland 1910 Football Championship’s finals. Unfortunately he didn't find the overall score of the match; however, he got hold of a profound description of the match's process. On the whole there are *n* lines in that description each of which described one goal. Every goal was marked with the name of the team that had scored it. Help Vasya, learn the name of the team that won the finals. It is guaranteed that the match did not end in a tie. | The first line contains an integer *n* (1<=≤<=*n*<=≤<=100) — the number of lines in the description. Then follow *n* lines — for each goal the names of the teams that scored it. The names are non-empty lines consisting of uppercase Latin letters whose lengths do not exceed 10 symbols. It is guaranteed that the match did not end in a tie and the description contains no more than two different teams. | Print the name of the winning team. We remind you that in football the team that scores more goals is considered the winner. | [
"1\nABC\n",
"5\nA\nABA\nABA\nA\nA\n"
] | [
"ABC\n",
"A\n"
] | none | 500 | [
{
"input": "1\nABC",
"output": "ABC"
},
{
"input": "5\nA\nABA\nABA\nA\nA",
"output": "A"
},
{
"input": "2\nXTSJEP\nXTSJEP",
"output": "XTSJEP"
},
{
"input": "3\nXZYDJAEDZ\nXZYDJAEDZ\nXZYDJAEDZ",
"output": "XZYDJAEDZ"
},
{
"input": "3\nQCCYXL\nQCCYXL\nAXGLFQDD",
"output": "QCCYXL"
},
{
"input": "3\nAZID\nEERWBC\nEERWBC",
"output": "EERWBC"
},
{
"input": "3\nHNCGYL\nHNCGYL\nHNCGYL",
"output": "HNCGYL"
},
{
"input": "4\nZZWZTG\nZZWZTG\nZZWZTG\nZZWZTG",
"output": "ZZWZTG"
},
{
"input": "4\nA\nA\nKUDLJMXCSE\nA",
"output": "A"
},
{
"input": "5\nPHBTW\nPHBTW\nPHBTW\nPHBTW\nPHBTW",
"output": "PHBTW"
},
{
"input": "5\nPKUZYTFYWN\nPKUZYTFYWN\nSTC\nPKUZYTFYWN\nPKUZYTFYWN",
"output": "PKUZYTFYWN"
},
{
"input": "5\nHH\nHH\nNTQWPA\nNTQWPA\nHH",
"output": "HH"
},
{
"input": "10\nW\nW\nW\nW\nW\nD\nW\nD\nD\nW",
"output": "W"
},
{
"input": "19\nXBCP\nTGACNIH\nXBCP\nXBCP\nXBCP\nXBCP\nXBCP\nTGACNIH\nXBCP\nXBCP\nXBCP\nXBCP\nXBCP\nTGACNIH\nXBCP\nXBCP\nTGACNIH\nTGACNIH\nXBCP",
"output": "XBCP"
},
{
"input": "33\nOWQWCKLLF\nOWQWCKLLF\nOWQWCKLLF\nPYPAS\nPYPAS\nPYPAS\nOWQWCKLLF\nPYPAS\nOWQWCKLLF\nPYPAS\nPYPAS\nOWQWCKLLF\nOWQWCKLLF\nOWQWCKLLF\nPYPAS\nOWQWCKLLF\nPYPAS\nPYPAS\nPYPAS\nPYPAS\nOWQWCKLLF\nPYPAS\nPYPAS\nOWQWCKLLF\nOWQWCKLLF\nPYPAS\nOWQWCKLLF\nOWQWCKLLF\nPYPAS\nPYPAS\nOWQWCKLLF\nPYPAS\nPYPAS",
"output": "PYPAS"
},
{
"input": "51\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC\nNC",
"output": "NC"
},
{
"input": "89\nH\nVOCI\nVOCI\nH\nVOCI\nH\nH\nVOCI\nVOCI\nVOCI\nH\nH\nH\nVOCI\nVOCI\nVOCI\nH\nVOCI\nVOCI\nH\nVOCI\nVOCI\nVOCI\nH\nVOCI\nH\nVOCI\nH\nVOCI\nH\nVOCI\nVOCI\nH\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nH\nVOCI\nVOCI\nVOCI\nVOCI\nH\nVOCI\nH\nH\nVOCI\nH\nVOCI\nH\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nH\nH\nVOCI\nH\nH\nVOCI\nH\nVOCI\nH\nVOCI\nVOCI\nH\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nVOCI\nH\nH\nH\nH\nH\nVOCI\nH\nVOCI\nH\nVOCI\nVOCI",
"output": "VOCI"
},
{
"input": "100\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nM\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA\nHA",
"output": "HA"
},
{
"input": "100\nG\nG\nS\nS\nG\nG\nS\nS\nG\nS\nS\nS\nG\nS\nG\nG\nS\nG\nS\nS\nG\nS\nS\nS\nS\nS\nG\nS\nG\nS\nS\nG\nG\nG\nS\nS\nS\nS\nG\nS\nS\nG\nG\nG\nG\nG\nS\nG\nG\nS\nS\nS\nS\nS\nG\nG\nS\nG\nG\nG\nG\nG\nS\nS\nG\nS\nS\nS\nS\nG\nS\nS\nG\nS\nG\nG\nG\nG\nG\nG\nG\nG\nG\nG\nG\nS\nS\nG\nS\nS\nS\nS\nG\nG\nG\nS\nG\nG\nG\nS",
"output": "G"
},
{
"input": "100\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nOBH\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL\nWL",
"output": "WL"
}
] | 1,659,463,426 | 2,147,483,647 | PyPy 3-64 | WRONG_ANSWER | TESTS | 29 | 124 | 0 | if "__main__" == __name__:
goals = int(input())
team1 = None
team2 = None
team1_wins = 0
for _ in range(goals):
line = input()
if team1 is None:
team1 = line
else:
team2 = line
if line == team1:
team1_wins += 1
if team1_wins > (goals / 2):
print(team1)
else:
print(team2)
| Title: Football
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
One day Vasya decided to have a look at the results of Berland 1910 Football Championship’s finals. Unfortunately he didn't find the overall score of the match; however, he got hold of a profound description of the match's process. On the whole there are *n* lines in that description each of which described one goal. Every goal was marked with the name of the team that had scored it. Help Vasya, learn the name of the team that won the finals. It is guaranteed that the match did not end in a tie.
Input Specification:
The first line contains an integer *n* (1<=≤<=*n*<=≤<=100) — the number of lines in the description. Then follow *n* lines — for each goal the names of the teams that scored it. The names are non-empty lines consisting of uppercase Latin letters whose lengths do not exceed 10 symbols. It is guaranteed that the match did not end in a tie and the description contains no more than two different teams.
Output Specification:
Print the name of the winning team. We remind you that in football the team that scores more goals is considered the winner.
Demo Input:
['1\nABC\n', '5\nA\nABA\nABA\nA\nA\n']
Demo Output:
['ABC\n', 'A\n']
Note:
none | ```python
if "__main__" == __name__:
goals = int(input())
team1 = None
team2 = None
team1_wins = 0
for _ in range(goals):
line = input()
if team1 is None:
team1 = line
else:
team2 = line
if line == team1:
team1_wins += 1
if team1_wins > (goals / 2):
print(team1)
else:
print(team2)
``` | 0 |
991 | C | Candies | PROGRAMMING | 1,500 | [
"binary search",
"implementation"
] | null | null | After passing a test, Vasya got himself a box of $n$ candies. He decided to eat an equal amount of candies each morning until there are no more candies. However, Petya also noticed the box and decided to get some candies for himself.
This means the process of eating candies is the following: in the beginning Vasya chooses a single integer $k$, same for all days. After that, in the morning he eats $k$ candies from the box (if there are less than $k$ candies in the box, he eats them all), then in the evening Petya eats $10\%$ of the candies remaining in the box. If there are still candies left in the box, the process repeats — next day Vasya eats $k$ candies again, and Petya — $10\%$ of the candies left in a box, and so on.
If the amount of candies in the box is not divisible by $10$, Petya rounds the amount he takes from the box down. For example, if there were $97$ candies in the box, Petya would eat only $9$ of them. In particular, if there are less than $10$ candies in a box, Petya won't eat any at all.
Your task is to find out the minimal amount of $k$ that can be chosen by Vasya so that he would eat at least half of the $n$ candies he initially got. Note that the number $k$ must be integer. | The first line contains a single integer $n$ ($1 \leq n \leq 10^{18}$) — the initial amount of candies in the box. | Output a single integer — the minimal amount of $k$ that would allow Vasya to eat at least half of candies he got. | [
"68\n"
] | [
"3\n"
] | In the sample, the amount of candies, with $k=3$, would change in the following way (Vasya eats first):
$68 \to 65 \to 59 \to 56 \to 51 \to 48 \to 44 \to 41 \\ \to 37 \to 34 \to 31 \to 28 \to 26 \to 23 \to 21 \to 18 \to 17 \to 14 \\ \to 13 \to 10 \to 9 \to 6 \to 6 \to 3 \to 3 \to 0$.
In total, Vasya would eat $39$ candies, while Petya — $29$. | 1,250 | [
{
"input": "68",
"output": "3"
},
{
"input": "1",
"output": "1"
},
{
"input": "2",
"output": "1"
},
{
"input": "42",
"output": "1"
},
{
"input": "43",
"output": "2"
},
{
"input": "756",
"output": "29"
},
{
"input": "999999972",
"output": "39259423"
},
{
"input": "999999973",
"output": "39259424"
},
{
"input": "1000000000000000000",
"output": "39259424579862572"
},
{
"input": "6",
"output": "1"
},
{
"input": "3",
"output": "1"
},
{
"input": "4",
"output": "1"
},
{
"input": "5",
"output": "1"
},
{
"input": "66",
"output": "2"
},
{
"input": "67",
"output": "3"
},
{
"input": "1000",
"output": "39"
},
{
"input": "10000",
"output": "392"
},
{
"input": "100500",
"output": "3945"
},
{
"input": "1000000",
"output": "39259"
},
{
"input": "10000000",
"output": "392594"
},
{
"input": "100000000",
"output": "3925942"
},
{
"input": "123456789",
"output": "4846842"
},
{
"input": "543212345",
"output": "21326204"
},
{
"input": "505050505",
"output": "19827992"
},
{
"input": "777777777",
"output": "30535108"
},
{
"input": "888888871",
"output": "34897266"
},
{
"input": "1000000000",
"output": "39259424"
},
{
"input": "999999999999999973",
"output": "39259424579862572"
},
{
"input": "999999999999999998",
"output": "39259424579862572"
},
{
"input": "999999999999999999",
"output": "39259424579862573"
},
{
"input": "100000000000000000",
"output": "3925942457986257"
},
{
"input": "540776028375043656",
"output": "21230555700587649"
},
{
"input": "210364830044445976",
"output": "8258802179385535"
},
{
"input": "297107279239074256",
"output": "11664260821414605"
},
{
"input": "773524766411950187",
"output": "30368137227605772"
},
{
"input": "228684941775227220",
"output": "8978039224174797"
},
{
"input": "878782039723446310",
"output": "34500477210660436"
},
{
"input": "615090701338187389",
"output": "24148106998961343"
},
{
"input": "325990422297859188",
"output": "12798196397960353"
},
{
"input": "255163492355051023",
"output": "10017571883647466"
},
{
"input": "276392003308849171",
"output": "10850991008380891"
},
{
"input": "601",
"output": "23"
},
{
"input": "983",
"output": "38"
},
{
"input": "729",
"output": "29"
},
{
"input": "70",
"output": "3"
},
{
"input": "703",
"output": "28"
},
{
"input": "257",
"output": "10"
},
{
"input": "526",
"output": "20"
},
{
"input": "466",
"output": "18"
},
{
"input": "738",
"output": "29"
},
{
"input": "116",
"output": "5"
},
{
"input": "888888888888888887",
"output": "34897266293211176"
},
{
"input": "888888888888888888",
"output": "34897266293211176"
},
{
"input": "888888888888888889",
"output": "34897266293211176"
},
{
"input": "999999999999999969",
"output": "39259424579862571"
},
{
"input": "999999999999999970",
"output": "39259424579862571"
},
{
"input": "999999999999999971",
"output": "39259424579862572"
},
{
"input": "999999999999999943",
"output": "39259424579862571"
},
{
"input": "999999999999999944",
"output": "39259424579862570"
},
{
"input": "999999999999999945",
"output": "39259424579862571"
},
{
"input": "999999999999999917",
"output": "39259424579862570"
},
{
"input": "999999999999999918",
"output": "39259424579862569"
},
{
"input": "999999999999999919",
"output": "39259424579862570"
},
{
"input": "99999999999999957",
"output": "3925942457986255"
},
{
"input": "99999999999999958",
"output": "3925942457986255"
},
{
"input": "99999999999999959",
"output": "3925942457986256"
},
{
"input": "888888888888888853",
"output": "34897266293211174"
},
{
"input": "888888888888888854",
"output": "34897266293211174"
},
{
"input": "888888888888888855",
"output": "34897266293211175"
}
] | 1,695,294,285 | 2,147,483,647 | PyPy 3-64 | WRONG_ANSWER | TESTS | 1 | 46 | 0 | n = int(input())
def cand(n,k):
countv = 0
while n>0:
countv+=1
n-=k
if n>=10:
n = n-int(n*0.1)
return countv*k
def binary(n):
l,r,mid = 0,n,n//2
while l<r-1:
if cand(n,mid)>=n//2:
r = mid
else:
l = mid
mid = (l+r)//2
return r+1
print(binary(n))
| Title: Candies
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
After passing a test, Vasya got himself a box of $n$ candies. He decided to eat an equal amount of candies each morning until there are no more candies. However, Petya also noticed the box and decided to get some candies for himself.
This means the process of eating candies is the following: in the beginning Vasya chooses a single integer $k$, same for all days. After that, in the morning he eats $k$ candies from the box (if there are less than $k$ candies in the box, he eats them all), then in the evening Petya eats $10\%$ of the candies remaining in the box. If there are still candies left in the box, the process repeats — next day Vasya eats $k$ candies again, and Petya — $10\%$ of the candies left in a box, and so on.
If the amount of candies in the box is not divisible by $10$, Petya rounds the amount he takes from the box down. For example, if there were $97$ candies in the box, Petya would eat only $9$ of them. In particular, if there are less than $10$ candies in a box, Petya won't eat any at all.
Your task is to find out the minimal amount of $k$ that can be chosen by Vasya so that he would eat at least half of the $n$ candies he initially got. Note that the number $k$ must be integer.
Input Specification:
The first line contains a single integer $n$ ($1 \leq n \leq 10^{18}$) — the initial amount of candies in the box.
Output Specification:
Output a single integer — the minimal amount of $k$ that would allow Vasya to eat at least half of candies he got.
Demo Input:
['68\n']
Demo Output:
['3\n']
Note:
In the sample, the amount of candies, with $k=3$, would change in the following way (Vasya eats first):
$68 \to 65 \to 59 \to 56 \to 51 \to 48 \to 44 \to 41 \\ \to 37 \to 34 \to 31 \to 28 \to 26 \to 23 \to 21 \to 18 \to 17 \to 14 \\ \to 13 \to 10 \to 9 \to 6 \to 6 \to 3 \to 3 \to 0$.
In total, Vasya would eat $39$ candies, while Petya — $29$. | ```python
n = int(input())
def cand(n,k):
countv = 0
while n>0:
countv+=1
n-=k
if n>=10:
n = n-int(n*0.1)
return countv*k
def binary(n):
l,r,mid = 0,n,n//2
while l<r-1:
if cand(n,mid)>=n//2:
r = mid
else:
l = mid
mid = (l+r)//2
return r+1
print(binary(n))
``` | 0 | |
801 | B | Valued Keys | PROGRAMMING | 900 | [
"constructive algorithms",
"greedy",
"strings"
] | null | null | You found a mysterious function *f*. The function takes two strings *s*1 and *s*2. These strings must consist only of lowercase English letters, and must be the same length.
The output of the function *f* is another string of the same length. The *i*-th character of the output is equal to the minimum of the *i*-th character of *s*1 and the *i*-th character of *s*2.
For example, *f*("ab", "ba") = "aa", and *f*("nzwzl", "zizez") = "niwel".
You found two strings *x* and *y* of the same length and consisting of only lowercase English letters. Find any string *z* such that *f*(*x*,<=*z*)<==<=*y*, or print -1 if no such string *z* exists. | The first line of input contains the string *x*.
The second line of input contains the string *y*.
Both *x* and *y* consist only of lowercase English letters, *x* and *y* have same length and this length is between 1 and 100. | If there is no string *z* such that *f*(*x*,<=*z*)<==<=*y*, print -1.
Otherwise, print a string *z* such that *f*(*x*,<=*z*)<==<=*y*. If there are multiple possible answers, print any of them. The string *z* should be the same length as *x* and *y* and consist only of lowercase English letters. | [
"ab\naa\n",
"nzwzl\nniwel\n",
"ab\nba\n"
] | [
"ba\n",
"xiyez\n",
"-1\n"
] | The first case is from the statement.
Another solution for the second case is "zizez"
There is no solution for the third case. That is, there is no *z* such that *f*("ab", *z*) = "ba". | 1,000 | [
{
"input": "ab\naa",
"output": "ba"
},
{
"input": "nzwzl\nniwel",
"output": "xiyez"
},
{
"input": "ab\nba",
"output": "-1"
},
{
"input": "r\nl",
"output": "l"
},
{
"input": "d\ny",
"output": "-1"
},
{
"input": "yvowz\ncajav",
"output": "cajav"
},
{
"input": "lwzjp\ninjit",
"output": "-1"
},
{
"input": "epqnlxmiicdidyscjaxqznwur\neodnlemiicdedmkcgavqbnqmm",
"output": "eodnlemiicdedmkcgavqbnqmm"
},
{
"input": "qqdabbsxiibnnjgsgxllfvdqj\nuxmypqtwfdezewdxfgplannrs",
"output": "-1"
},
{
"input": "aanerbaqslfmqmuciqbxyznkevukvznpkmxlcorpmrenwxhzfgbmlfpxtkqpxdrmcqcmbf\naanebbaqkgfiimcciqbaoznkeqqkrgapdillccrfeienwbcvfgbmlfbimkqchcrmclcmbf",
"output": "aanebbaqkgfiimcciqbaoznkeqqkrgapdillccrfeienwbcvfgbmlfbimkqchcrmclcmbf"
},
{
"input": "mbyrkhjctrcrayisflptgfudwgrtegidhqicsjqafvdloritbjhciyxuwavxknezwwudnk\nvvixsutlbdewqoabqhpuerfkzrddcqptfwmxdlxwbvsaqfjoxztlddvwgflcteqbwaiaen",
"output": "-1"
},
{
"input": "eufycwztywhbjrpqobvknwfqmnboqcfdiahkagykeibbsqpljcghhmsgfmswwsanzyiwtvuirwmppfivtekaywkzskyydfvkjgxb\necfwavookadbcilfobojnweqinbcpcfdiahkabwkeibbacpljcghhksgfajgmianfnivmhfifogpffiheegayfkxkkcmdfvihgdb",
"output": "ecfwavookadbcilfobojnweqinbcpcfdiahkabwkeibbacpljcghhksgfajgmianfnivmhfifogpffiheegayfkxkkcmdfvihgdb"
},
{
"input": "qvpltcffyeghtbdhjyhfteojezyzziardduzrbwuxmzzkkoehfnxecafizxglboauhynfbawlfxenmykquyhrxswhjuovvogntok\nchvkcvzxptbcepdjfezcpuvtehewbnvqeoezlcnzhpfwujbmhafoeqmjhtwisnobauinkzyigrvahpuetkgpdjfgbzficsmuqnym",
"output": "-1"
},
{
"input": "nmuwjdihouqrnsuahimssnrbxdpwvxiyqtenahtrlshjkmnfuttnpqhgcagoptinnaptxaccptparldzrhpgbyrzedghudtsswxi\nnilhbdghosqnbebafimconrbvdodjsipqmekahhrllhjkemeketapfhgcagopfidnahtlaccpfpafedqicpcbvfgedghudhddwib",
"output": "nilhbdghosqnbebafimconrbvdodjsipqmekahhrllhjkemeketapfhgcagopfidnahtlaccpfpafedqicpcbvfgedghudhddwib"
},
{
"input": "dyxgwupoauwqtcfoyfjdotzirwztdfrueqiypxoqvkmhiehdppwtdoxrbfvtairdbuvlqohjflznggjpifhwjrshcrfbjtklpykx\ngzqlnoizhxolnditjdhlhptjsbczehicudoybzilwnshmywozwnwuipcgirgzldtvtowdsokfeafggwserzdazkxyddjttiopeew",
"output": "-1"
},
{
"input": "hbgwuqzougqzlxemvyjpeizjfwhgugrfnhbrlxkmkdalikfyunppwgdzmalbwewybnjzqsohwhjkdcyhhzmysflambvhpsjilsyv\nfbdjdqjojdafarakvcjpeipjfehgfgrfehbolxkmkdagikflunnpvadocalbkedibhbflmohnhjkdcthhaigsfjaibqhbcjelirv",
"output": "fbdjdqjojdafarakvcjpeipjfehgfgrfehbolxkmkdagikflunnpvadocalbkedibhbflmohnhjkdcthhaigsfjaibqhbcjelirv"
},
{
"input": "xnjjhjfuhgyxqhpzmvgbaohqarugdoaczcfecofltwemieyxolswkcwhlfagfrgmoiqrgftokbqwtxgxzweozzlikrvafiabivlk\npjfosalbsitcnqiazhmepfifjxvmazvdgffcnozmnqubhonwjldmpdsjagmamniylzjdbklcyrzivjyzgnogahobpkwpwpvraqns",
"output": "-1"
},
{
"input": "zrvzedssbsrfldqvjpgmsefrmsatspzoitwvymahiptphiystjlsauzquzqqbmljobdhijcpdvatorwmyojqgnezvzlgjibxepcf\npesoedmqbmffldqsjggmhefkadaesijointrkmahapaahiysfjdiaupqujngbjhjobdhiecadeatgjvelojjgnepvajgeibfepaf",
"output": "pesoedmqbmffldqsjggmhefkadaesijointrkmahapaahiysfjdiaupqujngbjhjobdhiecadeatgjvelojjgnepvajgeibfepaf"
},
{
"input": "pdvkuwyzntzfqpblzmbynknyhlnqbxijuqaincviugxohcsrofozrrsategwkbwxcvkyzxhurokefpbdnmcfogfhsojayysqbrow\nbvxruombdrywlcjkrltyayaazwpauuhbtgwfzdrmfwwucgffucwelzvpsdgtapogchblzahsrfymjlaghkbmbssghrpxalkslcvp",
"output": "-1"
},
{
"input": "tgharsjyihroiiahwgbjezlxvlterxivdhtzjcqegzmtigqmrehvhiyjeywegxaseoyoacouijudbiruoghgxvxadwzgdxtnxlds\ntghaksjsdhkoiiahegbjexlfrctercipdhmvjbgegxdtggqdpbhvhiseehhegnaseoooacnsijubbirjnghgsvpadhaadrtimfdp",
"output": "tghaksjsdhkoiiahegbjexlfrctercipdhmvjbgegxdtggqdpbhvhiseehhegnaseoooacnsijubbirjnghgsvpadhaadrtimfdp"
},
{
"input": "jsinejpfwhzloulxndzvzftgogfdagrsscxmatldssqsgaknnbkcvhptebjjpkjhrjegrotzwcdosezkedzxeoyibmyzunkguoqj\nkfmvybobocdpipiripysioruqvloopvbggpjksgmwzyqwyxnesmvhsawnbbmntulspvsysfkjqwpvoelliopbaukyagedextzoej",
"output": "-1"
},
{
"input": "nttdcfceptruiomtmwzestrfchnqpgqeztpcvthzelfyggjgqadylzubpvbrlgndrcsursczpxlnoyoadxezncqalupfzmjeqihe\nkttdcfceohrjiaahmoldanpfchnfpgheqpdahqhxecfpbgigqadrkjubjfbrlgndbcgcgmcjpeleinaadretncqaiqpfkmjeqihe",
"output": "kttdcfceohrjiaahmoldanpfchnfpgheqpdahqhxecfpbgigqadrkjubjfbrlgndbcgcgmcjpeleinaadretncqaiqpfkmjeqihe"
},
{
"input": "diuopwglduasnaxgduwslbzoyayoypzznqspljcyqehweydhlwifcvnjmaowuvyqfwynjghecqvxdvuquuwpvwrjljozocaxnktv\ntrdydprdzmjhgbhzytelrfjpgsebijicsigmwhynmcyjtqrvojcndodchzxfcvyqjxqzwibccdvsjqhsnectdjyrrhzkeamukang",
"output": "-1"
},
{
"input": "ftfr\nftfr",
"output": "ftfr"
},
{
"input": "ftr\nftr",
"output": "ftr"
},
{
"input": "shftr\nshftr",
"output": "shftr"
},
{
"input": "vkvkkv\nvkvkkv",
"output": "vkvkkv"
},
{
"input": "ftrd\nftrd",
"output": "ftrd"
},
{
"input": "fztr\nfztr",
"output": "fztr"
},
{
"input": "frtr\nfrtr",
"output": "frtr"
},
{
"input": "shdftr\nshdftr",
"output": "shdftr"
},
{
"input": "zzz\nzzz",
"output": "zzz"
},
{
"input": "shtr\nshtr",
"output": "shtr"
},
{
"input": "aaaaa\nzzzzz",
"output": "-1"
},
{
"input": "efr\nefr",
"output": "efr"
}
] | 1,563,133,052 | 2,147,483,647 | PyPy 3 | OK | TESTS | 35 | 155 | 0 | s = input()
t = input()
res = ""
possible = True
for i in range(len(s)):
if t[i] <= s[i]:
res = res + t[i]
elif t[i] > s[i]:
possible = False
break
if possible:
print(res)
else:
print(-1)
| Title: Valued Keys
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You found a mysterious function *f*. The function takes two strings *s*1 and *s*2. These strings must consist only of lowercase English letters, and must be the same length.
The output of the function *f* is another string of the same length. The *i*-th character of the output is equal to the minimum of the *i*-th character of *s*1 and the *i*-th character of *s*2.
For example, *f*("ab", "ba") = "aa", and *f*("nzwzl", "zizez") = "niwel".
You found two strings *x* and *y* of the same length and consisting of only lowercase English letters. Find any string *z* such that *f*(*x*,<=*z*)<==<=*y*, or print -1 if no such string *z* exists.
Input Specification:
The first line of input contains the string *x*.
The second line of input contains the string *y*.
Both *x* and *y* consist only of lowercase English letters, *x* and *y* have same length and this length is between 1 and 100.
Output Specification:
If there is no string *z* such that *f*(*x*,<=*z*)<==<=*y*, print -1.
Otherwise, print a string *z* such that *f*(*x*,<=*z*)<==<=*y*. If there are multiple possible answers, print any of them. The string *z* should be the same length as *x* and *y* and consist only of lowercase English letters.
Demo Input:
['ab\naa\n', 'nzwzl\nniwel\n', 'ab\nba\n']
Demo Output:
['ba\n', 'xiyez\n', '-1\n']
Note:
The first case is from the statement.
Another solution for the second case is "zizez"
There is no solution for the third case. That is, there is no *z* such that *f*("ab", *z*) = "ba". | ```python
s = input()
t = input()
res = ""
possible = True
for i in range(len(s)):
if t[i] <= s[i]:
res = res + t[i]
elif t[i] > s[i]:
possible = False
break
if possible:
print(res)
else:
print(-1)
``` | 3 | |
825 | A | Binary Protocol | PROGRAMMING | 1,100 | [
"implementation"
] | null | null | Polycarp has just invented a new binary protocol for data transmission. He is encoding positive integer decimal number to binary string using following algorithm:
- Each digit is represented with number of '1' characters equal to the value of that digit (for 0 it is zero ones). - Digits are written one by one in order corresponding to number and separated by single '0' character.
Though Polycarp learnt how to encode the numbers, he has no idea how to decode them back. Help him calculate the decoded number. | The first line contains one integer number *n* (1<=≤<=*n*<=≤<=89) — length of the string *s*.
The second line contains string *s* — sequence of '0' and '1' characters, number in its encoded format. It is guaranteed that the number corresponding to the string is positive and doesn't exceed 109. The string always starts with '1'. | Print the decoded number. | [
"3\n111\n",
"9\n110011101\n"
] | [
"3\n",
"2031\n"
] | none | 0 | [
{
"input": "3\n111",
"output": "3"
},
{
"input": "9\n110011101",
"output": "2031"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "3\n100",
"output": "100"
},
{
"input": "5\n10001",
"output": "1001"
},
{
"input": "14\n11001100011000",
"output": "202002000"
},
{
"input": "31\n1000011111111100011110111111111",
"output": "100090049"
},
{
"input": "53\n10110111011110111110111111011111110111111110111111111",
"output": "123456789"
},
{
"input": "89\n11111111101111111110111111111011111111101111111110111111111011111111101111111110111111111",
"output": "999999999"
},
{
"input": "10\n1000000000",
"output": "1000000000"
},
{
"input": "2\n10",
"output": "10"
},
{
"input": "4\n1110",
"output": "30"
},
{
"input": "8\n10101010",
"output": "11110"
}
] | 1,500,217,698 | 198 | Python 3 | OK | TESTS | 13 | 62 | 4,608,000 | S = int(input())
s = input().split('0')
ans = ''
for c in s:
ans += str(len(c))
print(ans)
| Title: Binary Protocol
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Polycarp has just invented a new binary protocol for data transmission. He is encoding positive integer decimal number to binary string using following algorithm:
- Each digit is represented with number of '1' characters equal to the value of that digit (for 0 it is zero ones). - Digits are written one by one in order corresponding to number and separated by single '0' character.
Though Polycarp learnt how to encode the numbers, he has no idea how to decode them back. Help him calculate the decoded number.
Input Specification:
The first line contains one integer number *n* (1<=≤<=*n*<=≤<=89) — length of the string *s*.
The second line contains string *s* — sequence of '0' and '1' characters, number in its encoded format. It is guaranteed that the number corresponding to the string is positive and doesn't exceed 109. The string always starts with '1'.
Output Specification:
Print the decoded number.
Demo Input:
['3\n111\n', '9\n110011101\n']
Demo Output:
['3\n', '2031\n']
Note:
none | ```python
S = int(input())
s = input().split('0')
ans = ''
for c in s:
ans += str(len(c))
print(ans)
``` | 3 | |
446 | A | DZY Loves Sequences | PROGRAMMING | 1,600 | [
"dp",
"implementation",
"two pointers"
] | null | null | DZY has a sequence *a*, consisting of *n* integers.
We'll call a sequence *a**i*,<=*a**i*<=+<=1,<=...,<=*a**j* (1<=≤<=*i*<=≤<=*j*<=≤<=*n*) a subsegment of the sequence *a*. The value (*j*<=-<=*i*<=+<=1) denotes the length of the subsegment.
Your task is to find the longest subsegment of *a*, such that it is possible to change at most one number (change one number to any integer you want) from the subsegment to make the subsegment strictly increasing.
You only need to output the length of the subsegment you find. | The first line contains integer *n* (1<=≤<=*n*<=≤<=105). The next line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109). | In a single line print the answer to the problem — the maximum length of the required subsegment. | [
"6\n7 2 3 1 5 6\n"
] | [
"5\n"
] | You can choose subsegment *a*<sub class="lower-index">2</sub>, *a*<sub class="lower-index">3</sub>, *a*<sub class="lower-index">4</sub>, *a*<sub class="lower-index">5</sub>, *a*<sub class="lower-index">6</sub> and change its 3rd element (that is *a*<sub class="lower-index">4</sub>) to 4. | 500 | [
{
"input": "6\n7 2 3 1 5 6",
"output": "5"
},
{
"input": "10\n424238336 649760493 681692778 714636916 719885387 804289384 846930887 957747794 596516650 189641422",
"output": "9"
},
{
"input": "50\n804289384 846930887 681692778 714636916 957747794 424238336 719885387 649760493 596516650 189641422 25202363 350490028 783368691 102520060 44897764 967513927 365180541 540383427 304089173 303455737 35005212 521595369 294702568 726956430 336465783 861021531 59961394 89018457 101513930 125898168 131176230 145174068 233665124 278722863 315634023 369133070 468703136 628175012 635723059 653377374 656478043 801979803 859484422 914544920 608413785 756898538 734575199 973594325 149798316 38664371",
"output": "19"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "2\n1000000000 1000000000",
"output": "2"
},
{
"input": "5\n1 2 3 4 1",
"output": "5"
},
{
"input": "10\n1 2 3 4 5 5 6 7 8 9",
"output": "6"
},
{
"input": "5\n1 1 1 1 1",
"output": "2"
},
{
"input": "5\n1 1 2 3 4",
"output": "5"
},
{
"input": "5\n1 2 3 1 6",
"output": "5"
},
{
"input": "1\n42",
"output": "1"
},
{
"input": "5\n1 2 42 3 4",
"output": "4"
},
{
"input": "5\n1 5 9 6 10",
"output": "4"
},
{
"input": "5\n5 2 3 4 5",
"output": "5"
},
{
"input": "3\n2 1 3",
"output": "3"
},
{
"input": "5\n1 2 3 3 4",
"output": "4"
},
{
"input": "8\n1 2 3 4 1 5 6 7",
"output": "5"
},
{
"input": "1\n3",
"output": "1"
},
{
"input": "3\n5 1 2",
"output": "3"
},
{
"input": "4\n1 4 3 4",
"output": "4"
},
{
"input": "6\n7 2 12 4 5 6",
"output": "5"
},
{
"input": "6\n7 2 3 1 4 5",
"output": "4"
},
{
"input": "6\n2 3 5 5 6 7",
"output": "6"
},
{
"input": "5\n2 4 7 6 8",
"output": "5"
},
{
"input": "3\n3 1 2",
"output": "3"
},
{
"input": "3\n1 1 2",
"output": "3"
},
{
"input": "2\n1 2",
"output": "2"
},
{
"input": "5\n4 1 2 3 4",
"output": "5"
},
{
"input": "20\n1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 2 3 4 5 6",
"output": "7"
},
{
"input": "4\n1 2 1 3",
"output": "3"
},
{
"input": "4\n4 3 1 2",
"output": "3"
},
{
"input": "6\n1 2 2 3 4 5",
"output": "5"
},
{
"input": "4\n1 1 1 2",
"output": "3"
},
{
"input": "4\n5 1 2 3",
"output": "4"
},
{
"input": "5\n9 1 2 3 4",
"output": "5"
},
{
"input": "2\n1 1",
"output": "2"
},
{
"input": "5\n1 3 2 4 5",
"output": "4"
},
{
"input": "6\n1 2 1 2 4 5",
"output": "5"
},
{
"input": "10\n1 1 5 3 2 9 9 7 7 6",
"output": "3"
},
{
"input": "6\n1 2 3 100000 100 101",
"output": "6"
},
{
"input": "4\n3 3 3 4",
"output": "3"
},
{
"input": "3\n4 3 5",
"output": "3"
},
{
"input": "5\n1 3 2 3 4",
"output": "4"
},
{
"input": "10\n1 2 3 4 5 10 10 11 12 13",
"output": "10"
},
{
"input": "7\n11 2 1 2 13 4 14",
"output": "5"
},
{
"input": "3\n5 1 3",
"output": "3"
},
{
"input": "4\n1 5 3 4",
"output": "4"
},
{
"input": "10\n1 2 3 4 100 6 7 8 9 10",
"output": "10"
},
{
"input": "3\n5 3 5",
"output": "3"
},
{
"input": "5\n100 100 7 8 9",
"output": "4"
},
{
"input": "5\n1 2 3 4 5",
"output": "5"
},
{
"input": "5\n1 2 4 4 5",
"output": "5"
},
{
"input": "6\n7 4 5 6 7 8",
"output": "6"
},
{
"input": "9\n3 4 1 6 3 4 5 6 7",
"output": "7"
},
{
"input": "3\n1000 1 2",
"output": "3"
},
{
"input": "3\n20 1 9",
"output": "3"
},
{
"input": "6\n7 2 3 1 4 6",
"output": "4"
},
{
"input": "3\n100 5 10",
"output": "3"
},
{
"input": "4\n2 2 2 3",
"output": "3"
},
{
"input": "6\n4 2 8 1 2 5",
"output": "4"
},
{
"input": "3\n25 1 6",
"output": "3"
},
{
"input": "10\n17 99 23 72 78 36 5 43 95 9",
"output": "5"
},
{
"input": "7\n21 16 22 21 11 13 19",
"output": "4"
},
{
"input": "5\n1 2 5 3 4",
"output": "4"
},
{
"input": "6\n2 2 2 3 4 5",
"output": "5"
},
{
"input": "5\n1 3 1 2 3",
"output": "4"
},
{
"input": "3\n81 33 64",
"output": "3"
},
{
"input": "7\n14 3 3 19 13 19 15",
"output": "4"
},
{
"input": "9\n1 2 3 4 5 42 7 8 9",
"output": "9"
},
{
"input": "5\n2 3 7 5 6",
"output": "5"
},
{
"input": "5\n1 3 3 4 5",
"output": "5"
},
{
"input": "6\n1 5 4 3 4 5",
"output": "4"
}
] | 1,627,202,949 | 2,147,483,647 | PyPy 3 | OK | TESTS | 92 | 202 | 32,153,600 | n=int(input())
a=list(map(int,input().split()))
b=[1]
for i in range(1,n):
if a[i]>a[i-1]:
b.append(b[-1]+1)
else:
b.append(1)
ans=max(b)
if ans!=n:
ans+=1
c=[0]*n
i=n-1
val=b[-1]
while i>=0:
for j in range(val):
c[i]=val
i-=1
val=b[i]
for i in range(1,n-1):
if a[i+1]-a[i-1]>=2:
if b[i]==1:
ans=max(ans,c[i-1]+c[i])
elif b[i+1]==1:
ans=max(ans,c[i+1]+c[i])
print(ans) | Title: DZY Loves Sequences
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
DZY has a sequence *a*, consisting of *n* integers.
We'll call a sequence *a**i*,<=*a**i*<=+<=1,<=...,<=*a**j* (1<=≤<=*i*<=≤<=*j*<=≤<=*n*) a subsegment of the sequence *a*. The value (*j*<=-<=*i*<=+<=1) denotes the length of the subsegment.
Your task is to find the longest subsegment of *a*, such that it is possible to change at most one number (change one number to any integer you want) from the subsegment to make the subsegment strictly increasing.
You only need to output the length of the subsegment you find.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=105). The next line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=109).
Output Specification:
In a single line print the answer to the problem — the maximum length of the required subsegment.
Demo Input:
['6\n7 2 3 1 5 6\n']
Demo Output:
['5\n']
Note:
You can choose subsegment *a*<sub class="lower-index">2</sub>, *a*<sub class="lower-index">3</sub>, *a*<sub class="lower-index">4</sub>, *a*<sub class="lower-index">5</sub>, *a*<sub class="lower-index">6</sub> and change its 3rd element (that is *a*<sub class="lower-index">4</sub>) to 4. | ```python
n=int(input())
a=list(map(int,input().split()))
b=[1]
for i in range(1,n):
if a[i]>a[i-1]:
b.append(b[-1]+1)
else:
b.append(1)
ans=max(b)
if ans!=n:
ans+=1
c=[0]*n
i=n-1
val=b[-1]
while i>=0:
for j in range(val):
c[i]=val
i-=1
val=b[i]
for i in range(1,n-1):
if a[i+1]-a[i-1]>=2:
if b[i]==1:
ans=max(ans,c[i-1]+c[i])
elif b[i+1]==1:
ans=max(ans,c[i+1]+c[i])
print(ans)
``` | 3 | |
450 | A | Jzzhu and Children | PROGRAMMING | 1,000 | [
"implementation"
] | null | null | There are *n* children in Jzzhu's school. Jzzhu is going to give some candies to them. Let's number all the children from 1 to *n*. The *i*-th child wants to get at least *a**i* candies.
Jzzhu asks children to line up. Initially, the *i*-th child stands at the *i*-th place of the line. Then Jzzhu start distribution of the candies. He follows the algorithm:
1. Give *m* candies to the first child of the line. 1. If this child still haven't got enough candies, then the child goes to the end of the line, else the child go home. 1. Repeat the first two steps while the line is not empty.
Consider all the children in the order they go home. Jzzhu wants to know, which child will be the last in this order? | The first line contains two integers *n*,<=*m* (1<=≤<=*n*<=≤<=100; 1<=≤<=*m*<=≤<=100). The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100). | Output a single integer, representing the number of the last child. | [
"5 2\n1 3 1 4 2\n",
"6 4\n1 1 2 2 3 3\n"
] | [
"4\n",
"6\n"
] | Let's consider the first sample.
Firstly child 1 gets 2 candies and go home. Then child 2 gets 2 candies and go to the end of the line. Currently the line looks like [3, 4, 5, 2] (indices of the children in order of the line). Then child 3 gets 2 candies and go home, and then child 4 gets 2 candies and goes to the end of the line. Currently the line looks like [5, 2, 4]. Then child 5 gets 2 candies and goes home. Then child 2 gets two candies and goes home, and finally child 4 gets 2 candies and goes home.
Child 4 is the last one who goes home. | 500 | [
{
"input": "5 2\n1 3 1 4 2",
"output": "4"
},
{
"input": "6 4\n1 1 2 2 3 3",
"output": "6"
},
{
"input": "7 3\n6 1 5 4 2 3 1",
"output": "4"
},
{
"input": "10 5\n2 7 3 6 2 5 1 3 4 5",
"output": "4"
},
{
"input": "100 1\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": "100"
},
{
"input": "9 3\n9 5 2 3 7 1 8 4 6",
"output": "7"
},
{
"input": "20 10\n58 4 32 10 73 7 30 39 47 6 59 21 24 66 79 79 46 13 29 58",
"output": "16"
},
{
"input": "50 5\n89 56 3 2 40 37 56 52 83 59 43 83 43 59 29 74 22 58 53 41 53 67 78 30 57 32 58 29 95 46 45 85 60 49 41 82 8 71 52 40 45 26 6 71 84 91 4 93 40 54",
"output": "48"
},
{
"input": "50 1\n4 3 9 7 6 8 3 7 10 9 8 8 10 2 9 3 2 4 4 10 4 6 8 10 9 9 4 2 8 9 4 4 9 5 1 5 2 4 4 9 10 2 5 10 7 2 8 6 8 1",
"output": "44"
},
{
"input": "50 5\n3 9 10 8 3 3 4 6 8 2 9 9 3 1 2 10 6 8 7 2 7 4 2 7 5 10 2 2 2 5 10 5 6 6 8 7 10 4 3 2 10 8 6 6 8 6 4 4 1 3",
"output": "46"
},
{
"input": "50 2\n56 69 72 15 95 92 51 1 74 87 100 29 46 54 18 81 84 72 84 83 20 63 71 27 45 74 50 89 48 8 21 15 47 3 39 73 80 84 6 99 17 25 56 3 74 64 71 39 89 78",
"output": "40"
},
{
"input": "50 3\n31 39 64 16 86 3 1 9 25 54 98 42 20 3 49 41 73 37 55 62 33 77 64 22 33 82 26 13 10 13 7 40 48 18 46 79 94 72 19 12 11 61 16 37 10 49 14 94 48 69",
"output": "11"
},
{
"input": "50 100\n67 67 61 68 42 29 70 77 12 61 71 27 4 73 87 52 59 38 93 90 31 27 87 47 26 57 76 6 28 72 81 68 50 84 69 79 39 93 52 6 88 12 46 13 90 68 71 38 90 95",
"output": "50"
},
{
"input": "100 3\n4 14 20 11 19 11 14 20 5 7 6 12 11 17 5 11 7 6 2 10 13 5 12 8 5 17 20 18 7 19 11 7 7 20 20 8 10 17 17 19 20 5 15 16 19 7 11 16 4 17 2 10 1 20 20 16 19 9 9 11 5 7 12 9 9 6 20 18 13 19 8 4 8 1 2 4 10 11 15 14 1 7 17 12 13 19 12 2 3 14 15 15 5 17 14 12 17 14 16 9",
"output": "86"
},
{
"input": "100 5\n16 8 14 16 12 11 17 19 19 2 8 9 5 6 19 9 11 18 6 9 14 16 14 18 17 17 17 5 15 20 19 7 7 10 10 5 14 20 5 19 11 16 16 19 17 9 7 12 14 10 2 11 14 5 20 8 10 11 19 2 14 14 19 17 5 10 8 8 4 2 1 10 20 12 14 11 7 6 6 15 1 5 9 15 3 17 16 17 5 14 11 9 16 15 1 11 10 6 15 7",
"output": "93"
},
{
"input": "100 1\n58 94 18 50 17 14 96 62 83 80 75 5 9 22 25 41 3 96 74 45 66 37 2 37 13 85 68 54 77 11 85 19 25 21 52 59 90 61 72 89 82 22 10 16 3 68 61 29 55 76 28 85 65 76 27 3 14 10 56 37 86 18 35 38 56 68 23 88 33 38 52 87 55 83 94 34 100 41 83 56 91 77 32 74 97 13 67 31 57 81 53 39 5 88 46 1 79 4 49 42",
"output": "77"
},
{
"input": "100 2\n1 51 76 62 34 93 90 43 57 59 52 78 3 48 11 60 57 48 5 54 28 81 87 23 44 77 67 61 14 73 29 53 21 89 67 41 47 9 63 37 1 71 40 85 4 14 77 40 78 75 89 74 4 70 32 65 81 95 49 90 72 41 76 55 69 83 73 84 85 93 46 6 74 90 62 37 97 7 7 37 83 30 37 88 34 16 11 59 85 19 57 63 85 20 63 97 97 65 61 48",
"output": "97"
},
{
"input": "100 3\n30 83 14 55 61 66 34 98 90 62 89 74 45 93 33 31 75 35 82 100 63 69 48 18 99 2 36 71 14 30 70 76 96 85 97 90 49 36 6 76 37 94 70 3 63 73 75 48 39 29 13 2 46 26 9 56 1 18 54 53 85 34 2 12 1 93 75 67 77 77 14 26 33 25 55 9 57 70 75 6 87 66 18 3 41 69 73 24 49 2 20 72 39 58 91 54 74 56 66 78",
"output": "20"
},
{
"input": "100 4\n69 92 76 3 32 50 15 38 21 22 14 3 67 41 95 12 10 62 83 52 78 1 18 58 94 35 62 71 58 75 13 73 60 34 50 97 50 70 19 96 53 10 100 26 20 39 62 59 88 26 24 83 70 68 66 8 6 38 16 93 2 91 81 89 78 74 21 8 31 56 28 53 77 5 81 5 94 42 77 75 92 15 59 36 61 18 55 45 69 68 81 51 12 42 85 74 98 31 17 41",
"output": "97"
},
{
"input": "100 5\n2 72 10 60 6 50 72 34 97 77 35 43 80 64 40 53 46 6 90 22 29 70 26 68 52 19 72 88 83 18 55 32 99 81 11 21 39 42 41 63 60 97 30 23 55 78 89 35 24 50 99 52 27 76 24 8 20 27 51 37 17 82 69 18 46 19 26 77 52 83 76 65 43 66 84 84 13 30 66 88 84 23 37 1 17 26 11 50 73 56 54 37 40 29 35 8 1 39 50 82",
"output": "51"
},
{
"input": "100 7\n6 73 7 54 92 33 66 65 80 47 2 53 28 59 61 16 54 89 37 48 77 40 49 59 27 52 17 22 78 80 81 80 8 93 50 7 87 57 29 16 89 55 20 7 51 54 30 98 44 96 27 70 1 1 32 61 22 92 84 98 31 89 91 90 28 56 49 25 86 49 55 16 19 1 18 8 88 47 16 18 73 86 2 96 16 91 74 49 38 98 94 25 34 85 29 27 99 31 31 58",
"output": "97"
},
{
"input": "100 9\n36 4 45 16 19 6 10 87 44 82 71 49 70 35 83 19 40 76 45 94 44 96 10 54 82 77 86 63 11 37 21 3 15 89 80 88 89 16 72 23 25 9 51 25 10 45 96 5 6 18 51 31 42 57 41 51 42 15 89 61 45 82 16 48 61 67 19 40 9 33 90 36 78 36 79 79 16 10 83 87 9 22 84 12 23 76 36 14 2 81 56 33 56 23 57 84 76 55 35 88",
"output": "47"
},
{
"input": "100 10\n75 81 39 64 90 58 92 28 75 9 96 78 92 83 77 68 76 71 14 46 58 60 80 25 78 11 13 63 22 82 65 68 47 6 33 63 90 50 85 43 73 94 80 48 67 11 83 17 22 15 94 80 66 99 66 4 46 35 52 1 62 39 96 57 37 47 97 49 64 12 36 63 90 16 4 75 85 82 85 56 13 4 92 45 44 93 17 35 22 46 18 44 29 7 52 4 100 98 87 51",
"output": "98"
},
{
"input": "100 20\n21 19 61 70 54 97 98 14 61 72 25 94 24 56 55 25 12 80 76 11 35 17 80 26 11 94 52 47 84 61 10 2 74 25 10 21 2 79 55 50 30 75 10 64 44 5 60 96 52 16 74 41 20 77 20 44 8 86 74 36 49 61 99 13 54 64 19 99 50 43 12 73 48 48 83 55 72 73 63 81 30 27 95 9 97 82 24 3 89 90 33 14 47 88 22 78 12 75 58 67",
"output": "94"
},
{
"input": "100 30\n56 79 59 23 11 23 67 82 81 80 99 79 8 58 93 36 98 81 46 39 34 67 3 50 4 68 70 71 2 21 52 30 75 23 33 21 16 100 56 43 8 27 40 8 56 24 17 40 94 10 67 49 61 36 95 87 17 41 7 94 33 19 17 50 26 11 94 54 38 46 77 9 53 35 98 42 50 20 43 6 78 6 38 24 100 45 43 16 1 50 16 46 14 91 95 88 10 1 50 19",
"output": "95"
},
{
"input": "100 40\n86 11 97 17 38 95 11 5 13 83 67 75 50 2 46 39 84 68 22 85 70 23 64 46 59 93 39 80 35 78 93 21 83 19 64 1 49 59 99 83 44 81 70 58 15 82 83 47 55 65 91 10 2 92 4 77 37 32 12 57 78 11 42 8 59 21 96 69 61 30 44 29 12 70 91 14 10 83 11 75 14 10 19 39 8 98 5 81 66 66 79 55 36 29 22 45 19 24 55 49",
"output": "88"
},
{
"input": "100 50\n22 39 95 69 94 53 80 73 33 90 40 60 2 4 84 50 70 38 92 12 36 74 87 70 51 36 57 5 54 6 35 81 52 17 55 100 95 81 32 76 21 1 100 1 95 1 40 91 98 59 84 19 11 51 79 19 47 86 45 15 62 2 59 77 31 68 71 92 17 33 10 33 85 57 5 2 88 97 91 99 63 20 63 54 79 93 24 62 46 27 30 87 3 64 95 88 16 50 79 1",
"output": "99"
},
{
"input": "100 70\n61 48 89 17 97 6 93 13 64 50 66 88 24 52 46 99 6 65 93 64 82 37 57 41 47 1 84 5 97 83 79 46 16 35 40 7 64 15 44 96 37 17 30 92 51 67 26 3 14 56 27 68 66 93 36 39 51 6 40 55 79 26 71 54 8 48 18 2 71 12 55 60 29 37 31 97 26 37 25 68 67 70 3 87 100 41 5 82 65 92 24 66 76 48 89 8 40 93 31 95",
"output": "100"
},
{
"input": "100 90\n87 32 30 15 10 52 93 63 84 1 82 41 27 51 75 32 42 94 39 53 70 13 4 22 99 35 44 38 5 23 18 100 61 80 9 12 42 93 9 77 3 7 60 95 66 78 95 42 69 8 1 88 93 66 96 20 76 63 15 36 92 52 2 72 36 57 48 63 29 20 74 88 49 47 81 61 94 74 70 93 47 3 19 52 59 41 5 40 22 3 76 97 91 37 95 88 91 99 76 15",
"output": "98"
},
{
"input": "100 100\n79 75 7 28 6 96 38 35 57 95 41 74 24 96 32 78 81 13 63 84 24 95 3 23 66 1 60 6 96 49 41 5 14 18 31 97 66 19 49 89 49 70 51 28 20 99 18 1 28 77 24 46 69 21 40 32 31 66 28 6 66 97 9 16 70 90 91 30 34 82 93 41 65 11 39 52 1 88 63 43 80 50 60 49 28 56 18 76 24 57 74 1 28 99 36 35 79 54 18 16",
"output": "100"
},
{
"input": "1 3\n5",
"output": "1"
},
{
"input": "1 1\n100",
"output": "1"
},
{
"input": "2 3\n4 2",
"output": "1"
},
{
"input": "2 5\n99 97",
"output": "2"
},
{
"input": "3 4\n7 5 2",
"output": "2"
},
{
"input": "3 50\n47 86 51",
"output": "3"
},
{
"input": "5 100\n82 100 85 1 37",
"output": "5"
},
{
"input": "5 20\n40 39 21 5 20",
"output": "3"
},
{
"input": "1 27\n81",
"output": "1"
},
{
"input": "20 13\n7 8 29 83 74 28 93 85 7 8 3 9 8 70 49 50 39 41 57 1",
"output": "7"
},
{
"input": "2 1\n100 2",
"output": "1"
},
{
"input": "2 2\n6 4",
"output": "1"
},
{
"input": "5 2\n6 4 4 1 1",
"output": "1"
},
{
"input": "1 4\n3",
"output": "1"
},
{
"input": "3 2\n1 5 3",
"output": "2"
},
{
"input": "3 1\n3 2 2",
"output": "1"
},
{
"input": "3 1\n2 3 2",
"output": "2"
},
{
"input": "5 1\n5 1 1 1 1",
"output": "1"
},
{
"input": "2 3\n7 4",
"output": "1"
}
] | 1,696,477,394 | 2,147,483,647 | Python 3 | OK | TESTS | 49 | 46 | 0 | a,b=map(int,input().split())
lst=list(map(int,input().split()))
maxi=0
import math
for i in range(len(lst)):
x=math.ceil(lst[i]/b)
if x>=maxi:
maxi=x
idx=i+1
print(idx) | Title: Jzzhu and Children
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are *n* children in Jzzhu's school. Jzzhu is going to give some candies to them. Let's number all the children from 1 to *n*. The *i*-th child wants to get at least *a**i* candies.
Jzzhu asks children to line up. Initially, the *i*-th child stands at the *i*-th place of the line. Then Jzzhu start distribution of the candies. He follows the algorithm:
1. Give *m* candies to the first child of the line. 1. If this child still haven't got enough candies, then the child goes to the end of the line, else the child go home. 1. Repeat the first two steps while the line is not empty.
Consider all the children in the order they go home. Jzzhu wants to know, which child will be the last in this order?
Input Specification:
The first line contains two integers *n*,<=*m* (1<=≤<=*n*<=≤<=100; 1<=≤<=*m*<=≤<=100). The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=100).
Output Specification:
Output a single integer, representing the number of the last child.
Demo Input:
['5 2\n1 3 1 4 2\n', '6 4\n1 1 2 2 3 3\n']
Demo Output:
['4\n', '6\n']
Note:
Let's consider the first sample.
Firstly child 1 gets 2 candies and go home. Then child 2 gets 2 candies and go to the end of the line. Currently the line looks like [3, 4, 5, 2] (indices of the children in order of the line). Then child 3 gets 2 candies and go home, and then child 4 gets 2 candies and goes to the end of the line. Currently the line looks like [5, 2, 4]. Then child 5 gets 2 candies and goes home. Then child 2 gets two candies and goes home, and finally child 4 gets 2 candies and goes home.
Child 4 is the last one who goes home. | ```python
a,b=map(int,input().split())
lst=list(map(int,input().split()))
maxi=0
import math
for i in range(len(lst)):
x=math.ceil(lst[i]/b)
if x>=maxi:
maxi=x
idx=i+1
print(idx)
``` | 3 | |
346 | B | Lucky Common Subsequence | PROGRAMMING | 2,000 | [
"dp",
"strings"
] | null | null | In mathematics, a subsequence is a sequence that can be derived from another sequence by deleting some elements without changing the order of the remaining elements. For example, the sequence BDF is a subsequence of ABCDEF. A substring of a string is a continuous subsequence of the string. For example, BCD is a substring of ABCDEF.
You are given two strings *s*1, *s*2 and another string called *virus*. Your task is to find the longest common subsequence of *s*1 and *s*2, such that it doesn't contain *virus* as a substring. | The input contains three strings in three separate lines: *s*1, *s*2 and *virus* (1<=≤<=|*s*1|,<=|*s*2|,<=|*virus*|<=≤<=100). Each string consists only of uppercase English letters. | Output the longest common subsequence of *s*1 and *s*2 without *virus* as a substring. If there are multiple answers, any of them will be accepted.
If there is no valid common subsequence, output 0. | [
"AJKEQSLOBSROFGZ\nOVGURWZLWVLUXTH\nOZ\n",
"AA\nA\nA\n"
] | [
"ORZ\n",
"0\n"
] | none | 1,000 | [
{
"input": "AJKEQSLOBSROFGZ\nOVGURWZLWVLUXTH\nOZ",
"output": "ORZ"
},
{
"input": "AA\nA\nA",
"output": "0"
},
{
"input": "PWBJTZPQHA\nZJMKLWSROQ\nUQ",
"output": "WQ"
},
{
"input": "QNHRPFYMAAPJDUHBAEXNEEZSTMYHVGQPYKNMVKMBVSVLIYGUVMJHEFLJEPIWFHSLISTGOKRXNMSCXYKMAXBPKCOCNTIRPCUEPHXM\nRRFCZUGFDRKKMQTOETNELXMEWGOCDHFKIXOPVHHEWTCDNXVFKFKTKNWKEIKTCMHMHDNCLLVQSGKHBCDDYVVVQIRPZEOPUGQUGRHH\nR",
"output": "QNHFPHEXNETMHMHLLSGKCYPOPUH"
},
{
"input": "CGPWTAPEVBTGANLCLVSHQIIKHDPVUHRSQPXHSNYAHPGBECICFQYDFRTRELLLEDZYWJSLOBSKDGRRDHNRRGIXAMEBGFJJTEIGUGRU\nHAWYVKRRBEIWNOGYMIYQXDCFXMMCSAYSOXQFHHIFRRCJRAWHLDDHHHAKHXVKCVPBFGGEXUKWTFWMOUUGMXTSBUTHXCJCWHCQQTYQ\nANKFDWLYSX",
"output": "WVBGCSSQHHIFRRWLDDHXBGFUGU"
},
{
"input": "AUNBEKNURNUPHXQYKUTAHCOLMPRQZZTVDUYCTNIRACQQTQAIDTAWJXBUTIZUASDIJZWLHAQVGCAHKTZMXSDVVWAIGQEALRFKFYTT\nQBVRFKPKLYZLYNRFTRJZZQEYAEKPFXVICUVFVQSDENBJYYNCFTOZHULSWJQTNELYLKCZTGHOARDCFXBXQGGSQIVUCJVNGFZEEZQE\nN",
"output": "BKPYTRZZVICQDJTZUSJZHAQGSVVGQE"
},
{
"input": "BGIIURZTEUJJULBWKHDQBRFGEUOMQSREOTILICRSBUHBGTSRDHKVDDEBVHGMHXUVFJURSMFDJOOOWCYPJDVRVKLDHICPNKTBFXDJ\nXOADNTKNILGNHHBNFYNDWUNXBGDFUKUVHLPDOGOYRMOTAQELLRMHFAQEOXFWGAQUROVUSWOAWFRVIRJQVXPCXLSCQLCUWKBZUFQP\nYVF",
"output": "ILBWKHDGOMQELRHEGUVUSOWVRVLCKBF"
},
{
"input": "AXBPBDEYIYKKCZBTLKBUNEQLCXXLKIUTOOATYDXYYQCLFAXAEIGTFMNTTQKCQRMEEFRYVYXAOLMUQNPJBMFBUGVXFZAJSBXWALSI\nVWFONLLKSHGHHQSFBBFWTXAITPUKNDANOCLMNFTAAMJVDLXYPILPCJCFWTNBQWEOMMXHRYHEGBJIVSXBBGQKXRIYNZFIWSZPPUUM\nPPKKLHXWWT",
"output": "BBITKNCLTADXYCFTNQMRYVXBBGXFWS"
},
{
"input": "XKTAOCPCVMIOGCQKPENDKIZRZBZVRTBTGCDRQUIMVHABDIHSCGWPUTQKLPBOXAYICPWJBFLFSEPERGJZHRINEHQMYTOTKLCQCSMZ\nAITFIOUTUVZLSSIYWXSYTQMFLICCXOFSACHTKGPXRHRCGXFZXPYWKWPUOIDNEEZOKMOUYGVUJRQTIRQFCSBCWXVFCIAOLZDGENNI\nDBHOIORVCPNXCDOJKSYYIENQRJGZFHOWBYQIITMTVWXRMAMYILTHBBAJRJELWMIZOZBGPDGSTIRTQIILJRYICMUQTUAFKDYGECPY",
"output": "TOVMIOCKPRRCGWPUOIEEGJRQTQCSZ"
},
{
"input": "UNGXODEEINVYVPHYVGSWPIPFMFLZJYRJIPCUSWVUDLLSLRPJJFWCUOYDUGXBRKWPARGLXFJCNNFUIGEZUCTPFYUIMQMJLQHTIVPO\nBWDEGORKXYCXIDWZKGFCUYIDYLTWLCDBUVHPAPFLIZPEUINQSTNRAOVYKZCKFWIJQVLSVCGLTCOEMAYRCDVVQWQENTWZALWUKKKA\nXDGPZXADAFCHKILONSXFGRHIQVMIYWUTJUPCCEKYQVYAENRHVWERJSNPVEMRYSZGYBNTQLIFKFISKZJQIQQGSKVGCNMPNIJDRTXI",
"output": "GODIYVHPPFLZPUSWVLSLCOYDWALU"
},
{
"input": "KOROXDDWEUVYWJIXSFPEJFYZJDDUXISOFJTIFJSBTWIJQHMTQWLAGGMXTFALRXYCMGZNKYQRCDVTPRQDBAALTWAXTNLDPYWNSFKE\nNHZGRZFMFQGSAYOJTFKMMUPOOQXWCPPAIVRJHINJPHXTTBWRIYNOHMJKBBGXVXYZDBVBBTQRXTOFLBBCXGNICBKAAGOKAYCCJYCW\nXCXLBESCRBNKWYGFDZFKWYNLFAKEWWGRUIAQGNCFDQXCHDBEQDSWSNGVKUFOGGSPFFZWTXGZQMMFJXDWOPUEZCMZEFDHXTRJTNLW",
"output": "KOOXWVJIPXTBWIHMTQXTFLCGNCBAAAYW"
},
{
"input": "ESQZPIRAWBTUZSOWLYKIYCHZJPYERRXPJANKPZVPEDCXCJIDTLCARMAOTZMHJVDJXRDNQRIIOFIUTALVSCKDUSAKANKKOFKWINLQ\nGKSTYEAXFJQQUTKPZDAKHZKXCJDONKBZOTYGLYQJOGKOYMYNNNQRRVAGARKBQYJRVYYPFXTIBJJYQUWJUGAUQZUVMUHXLIQWGRMP\nUFPHNRDXLNYRIIYVOFRKRUQCWAICQUUBPHHEGBCILXHHGLOBKADQVPSQCMXJRLIZQPSRLZJNZVQPIURDQUKNHVVYNVBYGXXXXJDI",
"output": "STYEXJKPZDXCJDTLOMVRQRFIUAVUIQ"
},
{
"input": "UAYQUMTSNGMYBORUYXJJQZVAGBRVDWUTGUYYYOTWAHVKGGOHADXULFUFQULSAGDWFJCSDKPWBROYZIFRGGRVZQMEHKHCKNHTQSMK\nSVKVTPUZOBRKGLEAAXMIUSRISOTDIFFUCODYGNYIPSWEEBHGNWRZETXSVVMQTRBVFZMYHOHUCMLBUXBMPMSNCSHFZTAFUVTMQFGL\nTNICVANBEBOQASUEJJAOJXWNMDGAAVYNHRPSMKGMXZDJHCZHFHRRMIDWUOQCZSBKDPLSGHNHFKFYDRGVKXOLPOOWBPOWSDFLEJVX",
"output": "SVVTUOKGAXUFFUCDPWBRZRVZMHHCNHTQ"
},
{
"input": "KEJHTOKHMKWTYSJEAJAXGADRHUKBCRHACSRDNSZIHTPQNLOSRKYBGYIIJDINTXRPMWSVMMBODAYPVVDDTIXGDIOMWUAKZVFKDAUM\nWTEVPIFAAJYIDTZSZKPPQKIOMHDZTKDMFVKSJRUFMNHZJPVSQYELWYAFACGGNRORSLGYVXAEYVLZBLDEHYDGOFDSWUYCXLXDKFSU\nTUZEQBWVBVTKETQ",
"output": "EJTOKMKSJRUHZPQLYGNRSVAYVDDGDWUKFU"
},
{
"input": "EGQYYSKTFTURZNRDVIWBYXMRDGFWMYKFXGIFOGYJSXKDCJUAGZPVTYCHIXVFTVTCXMKHZFTXSMMQVFXZGKHCIYODDRZEYECDLKNG\nPEXXCTRFJAAKPOTBAEFRLDRZKORNMXHHXTLKMKCGPVPUOBELPLFQFXOBZWIVIQCHEJQPXKGSCQAWIMETCJVTAGXJIINTADDXJTKQ\nQURSEKPMSSEVQZI",
"output": "EKTFRZNXMGFFXIJXKCATCVTXTDDK"
},
{
"input": "ZFFBNYVXOZCJPSRAEACVPAUKVTCVZYQPHVENTKOCMHNIYYMIKKLNKHLWHHWAQMWFTSYEOQQFEYAAYGMPNZCRYBVNAQTDSLXZGBCG\nPIQHLNEWAMFAKGHBGZAWRWAXCSKUDZBDOCTXAHSVFZACXGFMDSYBYYDDNQNBEZCYCULSMMPBTQOJQNRPZTRCSDLIYPLVUGJPKDTG\nZBFJPLNAKWQBTUVJKMHVBATAM",
"output": "FBZRACUZOCHAMSYYYNZCYBNTDLGG"
},
{
"input": "BTWZLIKDACZVLCKMVTIQHLFBNRCBDSWPFFKGPCQFPTOIJLPFCDMFGQKFHTDFFCCULUAYPXXIIIWBZIDMOPNHPZBEXLVARJFTBFOE\nMDXYKKWZVASJPPWRCYNMRAOBBLUNBSMQAPCPSFAGLXWJRBQTBRWXYNQGWECYNFIAJXDMUHIIMDFMSHLPIMYQXNRRUSSNXALGNWIK\nKNFVBVAOWXMZVUHAVUDKDBUVAKNHACZBGBHMUOPHWGQSDFXLHB",
"output": "WZACLMQLBRWGCFIJDMHDFLPIMNXL"
},
{
"input": "GOZVMIRQIGYGVAGOREQTXFXPEZYOJOXPNDGAESICXHMKQDXQPRLMRVWHXFEJVCWZDLYMQLDURUXZPTLEHPTSKXGSNEQDKLVFFLDX\nIMEVFCZXACKRRJVXDRKFWTLTRTLQQDHEBZLCOCNVPABQMIWJHRLKFUKWOVVWGGNWCJNRYOYOAJFQWCLHQIQRBZTVWKBFOXKEHHQP\nSZ",
"output": "MVARXFEZOPAIHRLVWFCLQRZTKXEQ"
},
{
"input": "BBYUVCIYLNUJPSEYCAAPQSDNSDDTNEHQZDPBEKQAWNAKEYFBNEEBGPDPRLCSVOWYDEDRPPEDOROCHRCNQUSPNVXGRXHNLKDETWQC\nBQCQXCAHADGJHBYIKEUWNXFUOOTVCCKJPJJCMWLAWWKSDGHFNZTCPSQNRTPCBLXDTSJLRHSCCZXQXCVLVGTROOUCUQASIQHZGNEI\nRYE",
"output": "BBYUVCJPCASDNTPQNBDRLVROOCQSGNE"
},
{
"input": "WZRKLETJRBBRZKGHEFBVEFVLIERBPSEGJVSNUZUICONWWBOOTHCOJLLZFNOCNOFJQZTZWBLKHGIWWWPBUYWBAHYJGEBJZJDTNBGN\nZINFGDCNKHYFZYYWHTIHZTKWXXXMSWOVOPQDTRWSQKBWWCPEMYFVGARELELBLGEVJCMOCFTTUVCYUQUSFONAMWKVDWMGXVNZJBWH\nAFPA",
"output": "WZKTRBEFVELEBEJCOTCFONWKWGZJB"
},
{
"input": "ABABABB\nABABABB\nABABB",
"output": "ABABAB"
},
{
"input": "ABBB\nABBB\nABB",
"output": "BBB"
},
{
"input": "A\nBABAABAAABABABABABABAABABABABBABABABABAABBABBABAABABAABAABBAAAAAABBABABABABAABABAABABABABAABAABABABA\nB",
"output": "A"
},
{
"input": "ABBAABAAABABAABAABABABABAABBBABABABAAABBABAAABABABABBABBABABAABABABABABABBABAABABAABABABAAABBABABABA\nA\nB",
"output": "A"
},
{
"input": "ABBBABABABABABBABAABAAABABAABABABABBABAAAABABABBABAABABAAABAABBAAABAABABBABBABABBABAABABABAAAAABABAB\nB\nBABBABAABABABABABABABABABBAABABBABABBAAABAAABABBAABAABBABABBABABAABBABAABABBAABAABAABABABABABBABABAB",
"output": "B"
},
{
"input": "AABABAABAAABABAAABAAAABBAAABABAAABABAABAABAAAABAABAAAABAAAABAAAABBAABAAAAABAAAAABABAAAAAABABAABAAAAA\nABAABABABAAABABAABABBAABAABAABABAABABAAABBAABAAAABABABAAAAABAAAAABABABABAABAABAABAABABAABABAABAABAAB\nBABAAABABBAABABAABAA",
"output": "ABAABABABAAABAAAABBAABAAAABABAABABAAABAABAAAABAAAAAAABAAAAAAABAAAAABAAAAAAABABAABAAAA"
},
{
"input": "AABABABABAAAABBAAAABABABABAAAAABABAAAA\nAABABAAABABABAAABAAAAABAAABAAABABABBBABBAAABAABAAAAABABBABAAABAABAABABAAAABABAAABAAABAABABBBABBABABA\nAAAAA",
"output": "AABABABABAAAABBAAAABABABABAAAABABAAAA"
},
{
"input": "ZZXXAAZZAXAAZZAZZXXAAZZAXAXZZXXAAZZZZXXAZZXXAAAZZXXAAAZZXXZZXXXAAAZZXZZXXAZZXXZXXAAXAAZZZXXAXAXAZZXZ\nAZZXXAAZZXXAAXZXXAZZXAZZXZZXXAAZZXXAAZAAZZAAZZXXAA\nAAZZXAAXXAAAZZXXAZZXXAAZZXXAAAZZXXZ",
"output": "ZZXXAAZZXXAAXZXXAZZXAZZXZZXXAAZZXXAAZAZZAAZZXXAA"
},
{
"input": "SDASSDADASDASDASDSDADASASDAAASDASDDASDDASDADASDASDSSDASDD\nSDASDASDDASDASDASDSDSDASDASDASDASDASDASDASDADASDASDASDSDASDASDDDASSD\nSDASDSDDAA",
"output": "SDASSDADASDASDSDSDADASASDAAASDASDDASDDASDDASDASDDASD"
},
{
"input": "DASSDASDASDDAASDASDADASDASASDAS\nSDADASDASSDAASDASDASDADASSDDA\nSD",
"output": "DADADADAADADADADASSA"
},
{
"input": "ASDASSDASDS\nDASDASDDDASDADASDASDASDASSDADASDDAASDA\nDSD",
"output": "ASDASSDASDS"
},
{
"input": "ASDASASDASDASDAASDASDASDASASDDAASDASSASDSDAD\nDASDASSSDASDASDASASDASSDAASDASSDDSASDASDAASDDAASDASDAASDASDDASDASDASDASDASS\nDASD",
"output": "ASDASASDASASDAASDASASDASASDDAASDASSASDSDAD"
},
{
"input": "DASDSDASDADASDDDSDASSDDAASDA\nDASDDASDSDADSDASDADSDSDADDASDASDDASDASDASDSDASD\nDAASD",
"output": "DASDSDASDADASDDDSDASSDDASDA"
},
{
"input": "ABAAAABABADABAABAABCCABADABACABACABCABADABADABACABBACAADABACABABACABADABACABABA\nBACAACABABABACABCABADABAACABADABACABAA\nABBAB",
"output": "BAAACABABABACABCABADABAACABADABACABAA"
},
{
"input": "ABAABACABADAACADABACAAB\nBAACABADABACABAAAADADAABACABACABADABABADABACABAADABBADABACAAACAABACABADABBBAA\nDABACA",
"output": "ABAABACABADAACADABAAAB"
},
{
"input": "BACABACABAACABADABABACAABACABBACAACAACABCABADAACABAABAABBADABACABADABCABAD\nBACAABADABABADABACABABACABADABACABCBADABACADABCABABADAABA\nBADABAA",
"output": "BACAABAAABADABACAABACABAAACABCBADAACADABCABADAABA"
},
{
"input": "ACABADABACABCABAAB\nBADAB\nACAACABA",
"output": "BADAB"
},
{
"input": "ABABAC\nABABAC\nABAC",
"output": "ABABA"
},
{
"input": "BCBCBC\nBCBCBC\nBC",
"output": "CCB"
},
{
"input": "AAACAAACAAADAAAAAAA\nAADAAAAAAAACDAAAAAAAAAAACAAAAABCACAAACAAAAABAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAADA\nAAACAADAAAAADD",
"output": "AAACAAACAAAAAAAAAA"
},
{
"input": "ABABBB\nABABBB\nABB",
"output": "ABAB"
},
{
"input": "ABABABAC\nABABABAC\nABABAC",
"output": "ABABABA"
},
{
"input": "BBAABAAAAABBBBBBBABABAABAABAABBABABABBBABBABBABBBABAABBBBBBAABAAAAAAAAABABAAABBABBAAAAAABAABABBAAABB\nBBAABAAAAABBBBBBBABABAABAABAABBABABABBBABBABBABBBABAABBBBBBAABAAAAAAAAABABAAABBABBAAAAAABAABABBAAABB\nBBBAA",
"output": "BBAABAAAAABBBBBBBABABAABAABAABBABABABBBABBABBABBBABAABBBBBBABAAAAAAAAABABAAABBABBAAAAAABAABABBAAABB"
},
{
"input": "ABABC\nABABC\nABC",
"output": "ABAB"
},
{
"input": "BABBB\nBABBB\nABB",
"output": "BBBB"
},
{
"input": "ABCCCCCCCC\nABCCCCCCCC\nABC",
"output": "BCCCCCCCC"
}
] | 1,692,669,384 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 29 | 186 | 1,638,400 | s1 = input()
s2 = input()
vir = input()
n, m = len(s1), len(s2)
dp = [[0]*(m+1) for _ in range(n+1)]
lcs = ""
for i in range(1,n+1):
for j in range(1,m+1):
if s1[i-1] == s2[j-1]:
dp[i][j] = 1 + dp[i-1][j-1]
else:
dp[i][j] = max(dp[i-1][j], dp[i][j-1])
i, j = n, m
while i and j:
if dp[i][j] == dp[i-1][j]:
i -= 1
elif dp[i][j] == dp[i][j-1]:
j -= 1
else:
lcs += s1[i-1]
i -= 1
j -= 1
lcs = lcs[::-1]
# print(dp[-1][-1], lcs)
cnt = 0
res = ""
for i in range(len(lcs)):
if lcs[i:].startswith(vir):
continue
else:
res += lcs[i]
print(res if res else 0) | Title: Lucky Common Subsequence
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
In mathematics, a subsequence is a sequence that can be derived from another sequence by deleting some elements without changing the order of the remaining elements. For example, the sequence BDF is a subsequence of ABCDEF. A substring of a string is a continuous subsequence of the string. For example, BCD is a substring of ABCDEF.
You are given two strings *s*1, *s*2 and another string called *virus*. Your task is to find the longest common subsequence of *s*1 and *s*2, such that it doesn't contain *virus* as a substring.
Input Specification:
The input contains three strings in three separate lines: *s*1, *s*2 and *virus* (1<=≤<=|*s*1|,<=|*s*2|,<=|*virus*|<=≤<=100). Each string consists only of uppercase English letters.
Output Specification:
Output the longest common subsequence of *s*1 and *s*2 without *virus* as a substring. If there are multiple answers, any of them will be accepted.
If there is no valid common subsequence, output 0.
Demo Input:
['AJKEQSLOBSROFGZ\nOVGURWZLWVLUXTH\nOZ\n', 'AA\nA\nA\n']
Demo Output:
['ORZ\n', '0\n']
Note:
none | ```python
s1 = input()
s2 = input()
vir = input()
n, m = len(s1), len(s2)
dp = [[0]*(m+1) for _ in range(n+1)]
lcs = ""
for i in range(1,n+1):
for j in range(1,m+1):
if s1[i-1] == s2[j-1]:
dp[i][j] = 1 + dp[i-1][j-1]
else:
dp[i][j] = max(dp[i-1][j], dp[i][j-1])
i, j = n, m
while i and j:
if dp[i][j] == dp[i-1][j]:
i -= 1
elif dp[i][j] == dp[i][j-1]:
j -= 1
else:
lcs += s1[i-1]
i -= 1
j -= 1
lcs = lcs[::-1]
# print(dp[-1][-1], lcs)
cnt = 0
res = ""
for i in range(len(lcs)):
if lcs[i:].startswith(vir):
continue
else:
res += lcs[i]
print(res if res else 0)
``` | 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"
}
] | 1,676,242,260 | 2,147,483,647 | PyPy 3-64 | OK | TESTS | 33 | 109 | 1,638,400 | n = 0
x = 0
y = 0
while n < 12 or n > (10**6):
n = int(input())
def determine(n,x,y):
y = n
x = 1
for x in range(1, n):
for y in range(1,n):
if x + y == n:
for i1 in range(1, y):
if (y/i1)%1==0 and i1 != y and i1!=1 :
for i2 in range(1, x):
if (x/i2)%1==0 and i2 != x and i2!=1:
return x, y
elif x+y !=n:
y-=2
x+=1
xx,yy = determine(n,x,y)
print(f'{xx} {yy}') | 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
n = 0
x = 0
y = 0
while n < 12 or n > (10**6):
n = int(input())
def determine(n,x,y):
y = n
x = 1
for x in range(1, n):
for y in range(1,n):
if x + y == n:
for i1 in range(1, y):
if (y/i1)%1==0 and i1 != y and i1!=1 :
for i2 in range(1, x):
if (x/i2)%1==0 and i2 != x and i2!=1:
return x, y
elif x+y !=n:
y-=2
x+=1
xx,yy = determine(n,x,y)
print(f'{xx} {yy}')
``` | 3 | |
928 | B | Chat | PROGRAMMING | 1,400 | [
"*special",
"dp"
] | null | null | There are times you recall a good old friend and everything you've come through together. Luckily there are social networks — they store all your message history making it easy to know what you argued over 10 years ago.
More formal, your message history is a sequence of messages ordered by time sent numbered from 1 to *n* where *n* is the total number of messages in the chat.
Each message might contain a link to an earlier message which it is a reply to. When opening a message *x* or getting a link to it, the dialogue is shown in such a way that *k* previous messages, message *x* and *k* next messages are visible (with respect to message *x*). In case there are less than *k* messages somewhere, they are yet all shown.
Digging deep into your message history, you always read all visible messages and then go by the link in the current message *x* (if there is one) and continue reading in the same manner.
Determine the number of messages you'll read if your start from message number *t* for all *t* from 1 to *n*. Calculate these numbers independently. If you start with message *x*, the initial configuration is *x* itself, *k* previous and *k* next messages. Messages read multiple times are considered as one. | The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=*n*) — the total amount of messages and the number of previous and next messages visible.
The second line features a sequence of integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=<<=*i*), where *a**i* denotes the *i*-th message link destination or zero, if there's no link from *i*. All messages are listed in chronological order. It's guaranteed that the link from message *x* goes to message with number strictly less than *x*. | Print *n* integers with *i*-th denoting the number of distinct messages you can read starting from message *i* and traversing the links while possible. | [
"6 0\n0 1 1 2 3 2\n",
"10 1\n0 1 0 3 4 5 2 3 7 0\n",
"2 2\n0 1\n"
] | [
"1 2 2 3 3 3 \n",
"2 3 3 4 5 6 6 6 8 2 \n",
"2 2 \n"
] | Consider *i* = 6 in sample case one. You will read message 6, then 2, then 1 and then there will be no link to go.
In the second sample case *i* = 6 gives you messages 5, 6, 7 since *k* = 1, then 4, 5, 6, then 2, 3, 4 and then the link sequence breaks. The number of distinct messages here is equal to 6. | 1,250 | [
{
"input": "6 0\n0 1 1 2 3 2",
"output": "1 2 2 3 3 3 "
},
{
"input": "10 1\n0 1 0 3 4 5 2 3 7 0",
"output": "2 3 3 4 5 6 6 6 8 2 "
},
{
"input": "2 2\n0 1",
"output": "2 2 "
},
{
"input": "1 1\n0",
"output": "1 "
},
{
"input": "5 2\n0 1 2 3 1",
"output": "3 4 5 5 5 "
},
{
"input": "30 1\n0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 0 0 2 0 0 0 0 0 2 1 0",
"output": "2 3 3 3 3 3 3 3 3 3 3 3 3 5 5 5 3 3 3 3 3 6 3 3 3 3 3 6 5 2 "
},
{
"input": "100 5\n0 1 1 1 0 5 6 6 8 8 9 11 12 11 8 0 0 14 6 16 7 21 15 23 15 24 0 0 0 28 0 29 26 27 19 0 0 21 37 32 40 30 37 34 39 38 34 38 0 0 41 24 45 47 0 33 46 26 31 0 21 57 57 31 63 63 25 59 65 56 68 0 30 55 55 0 70 43 59 49 59 79 66 74 0 11 65 0 80 63 0 84 73 49 73 81 0 86 76 98",
"output": "6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 11 11 23 22 15 23 24 28 29 30 31 11 11 11 13 11 14 38 18 33 11 11 34 13 22 23 24 17 28 19 42 29 44 11 11 33 40 27 36 11 49 53 42 22 11 34 58 59 22 61 62 41 31 65 60 34 11 24 22 22 11 67 28 33 22 33 36 73 32 11 27 72 11 31 70 11 40 35 22 35 43 9 35 18 35 "
},
{
"input": "2 2\n0 0",
"output": "2 2 "
},
{
"input": "2 1\n0 0",
"output": "2 2 "
},
{
"input": "2 1\n0 1",
"output": "2 2 "
},
{
"input": "2 0\n0 0",
"output": "1 1 "
},
{
"input": "2 0\n0 1",
"output": "1 2 "
},
{
"input": "3 0\n0 0 0",
"output": "1 1 1 "
},
{
"input": "3 0\n0 0 1",
"output": "1 1 2 "
},
{
"input": "3 0\n0 0 2",
"output": "1 1 2 "
},
{
"input": "3 0\n0 1 0",
"output": "1 2 1 "
},
{
"input": "3 0\n0 1 1",
"output": "1 2 2 "
},
{
"input": "3 0\n0 1 2",
"output": "1 2 3 "
},
{
"input": "3 1\n0 0 0",
"output": "2 3 2 "
},
{
"input": "3 1\n0 0 1",
"output": "2 3 3 "
},
{
"input": "3 1\n0 0 2",
"output": "2 3 3 "
},
{
"input": "3 1\n0 1 0",
"output": "2 3 2 "
},
{
"input": "3 1\n0 1 1",
"output": "2 3 3 "
},
{
"input": "3 1\n0 1 2",
"output": "2 3 3 "
},
{
"input": "3 2\n0 0 0",
"output": "3 3 3 "
},
{
"input": "3 2\n0 0 1",
"output": "3 3 3 "
},
{
"input": "3 2\n0 0 2",
"output": "3 3 3 "
},
{
"input": "3 2\n0 1 0",
"output": "3 3 3 "
},
{
"input": "3 2\n0 1 1",
"output": "3 3 3 "
},
{
"input": "3 2\n0 1 2",
"output": "3 3 3 "
},
{
"input": "3 3\n0 0 0",
"output": "3 3 3 "
},
{
"input": "3 3\n0 0 1",
"output": "3 3 3 "
},
{
"input": "3 3\n0 0 2",
"output": "3 3 3 "
},
{
"input": "3 3\n0 1 0",
"output": "3 3 3 "
},
{
"input": "3 3\n0 1 1",
"output": "3 3 3 "
},
{
"input": "3 3\n0 1 2",
"output": "3 3 3 "
},
{
"input": "10 3\n0 0 0 0 0 0 0 4 0 4",
"output": "4 5 6 7 7 7 7 10 5 10 "
},
{
"input": "20 2\n0 0 0 0 2 1 0 3 0 1 1 11 0 10 0 0 9 17 9 0",
"output": "3 4 5 5 7 8 5 10 5 8 8 9 5 12 5 5 10 11 9 3 "
},
{
"input": "40 0\n0 1 2 3 4 5 0 0 0 0 0 11 12 0 14 10 0 16 15 0 19 21 22 0 23 25 25 24 24 29 29 0 0 31 0 35 31 36 34 29",
"output": "1 2 3 4 5 6 1 1 1 1 1 2 3 1 2 2 1 3 3 1 4 5 6 1 7 8 8 2 2 3 3 1 1 4 1 2 4 3 5 3 "
}
] | 1,519,548,285 | 61,785 | Python 3 | TIME_LIMIT_EXCEEDED | PRETESTS | 7 | 1,000 | 5,939,200 | s = input().split()
n = int(s[0])
k = int(s[1])
r = input().split()
for i in range(n):
l = []
for h in range(n):
l.append([])
for y in range(n):
l[y] = [y, int(r[y]), False]
p = 0
nowi = i
while True:
now = l[nowi][1]
for j in range(nowi-k, nowi+k+1):
if j > -1 and j<n:
if l[j][2]==False:
p += 1
l[j][2] = True
if l[nowi][1] == 0:
break
else:
nowi = l[nowi][1]-1
print(p, end=" ")
| Title: Chat
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
There are times you recall a good old friend and everything you've come through together. Luckily there are social networks — they store all your message history making it easy to know what you argued over 10 years ago.
More formal, your message history is a sequence of messages ordered by time sent numbered from 1 to *n* where *n* is the total number of messages in the chat.
Each message might contain a link to an earlier message which it is a reply to. When opening a message *x* or getting a link to it, the dialogue is shown in such a way that *k* previous messages, message *x* and *k* next messages are visible (with respect to message *x*). In case there are less than *k* messages somewhere, they are yet all shown.
Digging deep into your message history, you always read all visible messages and then go by the link in the current message *x* (if there is one) and continue reading in the same manner.
Determine the number of messages you'll read if your start from message number *t* for all *t* from 1 to *n*. Calculate these numbers independently. If you start with message *x*, the initial configuration is *x* itself, *k* previous and *k* next messages. Messages read multiple times are considered as one.
Input Specification:
The first line contains two integers *n* and *k* (1<=≤<=*n*<=≤<=105, 0<=≤<=*k*<=≤<=*n*) — the total amount of messages and the number of previous and next messages visible.
The second line features a sequence of integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=<<=*i*), where *a**i* denotes the *i*-th message link destination or zero, if there's no link from *i*. All messages are listed in chronological order. It's guaranteed that the link from message *x* goes to message with number strictly less than *x*.
Output Specification:
Print *n* integers with *i*-th denoting the number of distinct messages you can read starting from message *i* and traversing the links while possible.
Demo Input:
['6 0\n0 1 1 2 3 2\n', '10 1\n0 1 0 3 4 5 2 3 7 0\n', '2 2\n0 1\n']
Demo Output:
['1 2 2 3 3 3 \n', '2 3 3 4 5 6 6 6 8 2 \n', '2 2 \n']
Note:
Consider *i* = 6 in sample case one. You will read message 6, then 2, then 1 and then there will be no link to go.
In the second sample case *i* = 6 gives you messages 5, 6, 7 since *k* = 1, then 4, 5, 6, then 2, 3, 4 and then the link sequence breaks. The number of distinct messages here is equal to 6. | ```python
s = input().split()
n = int(s[0])
k = int(s[1])
r = input().split()
for i in range(n):
l = []
for h in range(n):
l.append([])
for y in range(n):
l[y] = [y, int(r[y]), False]
p = 0
nowi = i
while True:
now = l[nowi][1]
for j in range(nowi-k, nowi+k+1):
if j > -1 and j<n:
if l[j][2]==False:
p += 1
l[j][2] = True
if l[nowi][1] == 0:
break
else:
nowi = l[nowi][1]-1
print(p, end=" ")
``` | 0 | |
518 | A | Vitaly and Strings | PROGRAMMING | 1,600 | [
"constructive algorithms",
"strings"
] | null | null | Vitaly is a diligent student who never missed a lesson in his five years of studying in the university. He always does his homework on time and passes his exams in time.
During the last lesson the teacher has provided two strings *s* and *t* to Vitaly. The strings have the same length, they consist of lowercase English letters, string *s* is lexicographically smaller than string *t*. Vitaly wondered if there is such string that is lexicographically larger than string *s* and at the same is lexicographically smaller than string *t*. This string should also consist of lowercase English letters and have the length equal to the lengths of strings *s* and *t*.
Let's help Vitaly solve this easy problem! | The first line contains string *s* (1<=≤<=|*s*|<=≤<=100), consisting of lowercase English letters. Here, |*s*| denotes the length of the string.
The second line contains string *t* (|*t*|<==<=|*s*|), consisting of lowercase English letters.
It is guaranteed that the lengths of strings *s* and *t* are the same and string *s* is lexicographically less than string *t*. | If the string that meets the given requirements doesn't exist, print a single string "No such string" (without the quotes).
If such string exists, print it. If there are multiple valid strings, you may print any of them. | [
"a\nc\n",
"aaa\nzzz\n",
"abcdefg\nabcdefh\n"
] | [
"b\n",
"kkk\n",
"No such string\n"
] | String *s* = *s*<sub class="lower-index">1</sub>*s*<sub class="lower-index">2</sub>... *s*<sub class="lower-index">*n*</sub> is said to be lexicographically smaller than *t* = *t*<sub class="lower-index">1</sub>*t*<sub class="lower-index">2</sub>... *t*<sub class="lower-index">*n*</sub>, if there exists such *i*, that *s*<sub class="lower-index">1</sub> = *t*<sub class="lower-index">1</sub>, *s*<sub class="lower-index">2</sub> = *t*<sub class="lower-index">2</sub>, ... *s*<sub class="lower-index">*i* - 1</sub> = *t*<sub class="lower-index">*i* - 1</sub>, *s*<sub class="lower-index">*i*</sub> < *t*<sub class="lower-index">*i*</sub>. | 500 | [
{
"input": "a\nc",
"output": "b"
},
{
"input": "aaa\nzzz",
"output": "kkk"
},
{
"input": "abcdefg\nabcdefh",
"output": "No such string"
},
{
"input": "abcdefg\nabcfefg",
"output": "abcdefh"
},
{
"input": "frt\nfru",
"output": "No such string"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz",
"output": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaab"
},
{
"input": "zzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzx\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz",
"output": "zzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzy"
},
{
"input": "q\nz",
"output": "r"
},
{
"input": "pnzcl\npnzdf",
"output": "pnzcm"
},
{
"input": "vklldrxnfgyorgfpfezvhbouyzzzzz\nvklldrxnfgyorgfpfezvhbouzaaadv",
"output": "vklldrxnfgyorgfpfezvhbouzaaaaa"
},
{
"input": "pkjlxzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\npkjlyaaaaaaaaaaaaaaaaaaaaaaaaaaaahr",
"output": "pkjlyaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "exoudpymnspkocwszzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\nexoudpymnspkocwtaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaabml",
"output": "exoudpymnspkocwtaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "anarzvsklmwvovozwnmhklkpcseeogdgauoppmzrukynbjjoxytuvsiecuzfquxnowewebhtuoxepocyeamqfrblpwqiokbcubil\nanarzvsklmwvovozwnmhklkpcseeogdgauoppmzrukynbjjoxytuvsiecuzfquxnowewebhtuoxepocyeamqfrblpwqiokbcubim",
"output": "No such string"
},
{
"input": "uqyugulumzwlxsjnxxkutzqayskrbjoaaekbhckjryhjjllzzz\nuqyugulumzwlxsjnxxkutzqayskrbjoaaekbhckjryhjjlmaaa",
"output": "No such string"
},
{
"input": "esfaeyxpblcrriizhnhfrxnbopqvhwtetgjqavlqdlxexaifgvkqfwzneibhxxdacbzzzzzzzzzzzzzz\nesfaeyxpblcrriizhnhfrxnbopqvhwtetgjqavlqdlxexaifgvkqfwzneibhxxdaccaaaaaaaaaaaatf",
"output": "esfaeyxpblcrriizhnhfrxnbopqvhwtetgjqavlqdlxexaifgvkqfwzneibhxxdaccaaaaaaaaaaaaaa"
},
{
"input": "oisjtilteipnzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\noisjtilteipoaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaao",
"output": "oisjtilteipoaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "svpoxbsudndfnnpugbouawegyxgtmvqzbewxpcwhopdbwscimgzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\nsvpoxbsudndfnnpugbouawegyxgtmvqzbewxpcwhopdbwscimhaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "No such string"
},
{
"input": "ddzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\ndeaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaao",
"output": "deaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "xqzbhslocdbifnyzyjenlpctocieaccsycmwlcebkqqkeibatfvylbqlutvjijgjhdetqsjqnoipqbmjhhzxggdobyvpczdavdzz\nxqzbhslocdbifnyzyjenlpctocieaccsycmwlcebkqqkeibatfvylbqlutvjijgjhdetqsjqnoipqbmjhhzxggdobyvpczdavilj",
"output": "xqzbhslocdbifnyzyjenlpctocieaccsycmwlcebkqqkeibatfvylbqlutvjijgjhdetqsjqnoipqbmjhhzxggdobyvpczdaveaa"
},
{
"input": "poflpxucohdobeisxfsnkbdzwizjjhgngufssqhmfgmydmmrnuminrvxxamoebhczlwsfefdtnchaisfxkfcovxmvppxnrfawfoq\npoflpxucohdobeisxfsnkbdzwizjjhgngufssqhmfgmydmmrnuminrvxxamoebhczlwsfefdtnchaisfxkfcovxmvppxnrfawujg",
"output": "poflpxucohdobeisxfsnkbdzwizjjhgngufssqhmfgmydmmrnuminrvxxamoebhczlwsfefdtnchaisfxkfcovxmvppxnrfawfor"
},
{
"input": "vonggnmokmvmguwtobkxoqgxkuxtyjmxrygyliohlhwxuxjmlkqcfuxboxjnzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\nvonggnmokmvmguwtobkxoqgxkuxtyjmxrygyliohlhwxuxjmlkqcfuxboxjoaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaac",
"output": "vonggnmokmvmguwtobkxoqgxkuxtyjmxrygyliohlhwxuxjmlkqcfuxboxjoaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "bqycw\nquhod",
"output": "bqycx"
},
{
"input": "hceslswecf\nnmxshuymaa",
"output": "hceslswecg"
},
{
"input": "awqtzslxowuaefe\nvujscakjpvxviki",
"output": "awqtzslxowuaeff"
},
{
"input": "lerlcnaogdravnogfogcyoxgi\nojrbithvjdqtempegvqxmgmmw",
"output": "lerlcnaogdravnogfogcyoxgj"
},
{
"input": "jbrhvicytqaivheqeourrlosvnsujsxdinryyawgalidsaufxv\noevvkhujmhagaholrmsatdjjyfmyblvgetpnxgjcilugjsncjs",
"output": "jbrhvicytqaivheqeourrlosvnsujsxdinryyawgalidsaufxw"
},
{
"input": "jrpogrcuhqdpmyzpuabuhaptlxaeiqjxhqkmuzsjbhqxvdtoocrkusaeasqdwlunomwzww\nspvgaswympzlscnumemgiznngnxqgccbubmxgqmaakbnyngkxlxjjsafricchhpecdjgxw",
"output": "jrpogrcuhqdpmyzpuabuhaptlxaeiqjxhqkmuzsjbhqxvdtoocrkusaeasqdwlunomwzwx"
},
{
"input": "mzmhjmfxaxaplzjmjkbyadeweltagyyuzpvrmnyvirjpdmebxyzjvdoezhnayfrvtnccryhkvhcvakcf\nohhhhkujfpjbgouebtmmbzizuhuumvrsqfniwpmxdtzhyiaivdyxhywnqzagicydixjtvbqbevhbqttu",
"output": "mzmhjmfxaxaplzjmjkbyadeweltagyyuzpvrmnyvirjpdmebxyzjvdoezhnayfrvtnccryhkvhcvakcg"
},
{
"input": "cdmwmzutsicpzhcokbbhwktqbomozxvvjlhwdgtiledgurxsfreisgczdwgupzxmjnfyjxcpdwzkggludkcmgppndl\nuvuqvyrnhtyubpevizhjxdvmpueittksrnosmfuuzbimnqussasdjufrthrgjbyzomauaxbvwferfvtmydmwmjaoxg",
"output": "cdmwmzutsicpzhcokbbhwktqbomozxvvjlhwdgtiledgurxsfreisgczdwgupzxmjnfyjxcpdwzkggludkcmgppndm"
},
{
"input": "dpnmrwpbgzvcmrcodwgvvfwpyagdwlngmhrazyvalszhruprxzmwltftxmujfyrrnwzvphgqlcphreumqkytswxziugburwrlyay\nqibcfxdfovoejutaeetbbwrgexdrvqywwmhipxgfrvhzovxkfawpfnpjvlhkyahessodqcclangxefcaixysqijnitevwmpalkzd",
"output": "dpnmrwpbgzvcmrcodwgvvfwpyagdwlngmhrazyvalszhruprxzmwltftxmujfyrrnwzvphgqlcphreumqkytswxziugburwrlyaz"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaab",
"output": "No such string"
},
{
"input": "phdvmuwqmvzyurtnshitcypuzbhpceovkibzbhhjwxkdtvqmbpoumeoiztxtvkvsjrlnhowsdmgftuiulzebdigmun\nphdvmuwqmvzyurtnshitcypuzbhpceovkibzbhhjwxkdtvqmbpoumeoiztxtvkvsjrlnhowsdmgftuiulzebdigmuo",
"output": "No such string"
},
{
"input": "hrsantdquixzjyjtqytcmnflnyehzbibkbgkqffgqpkgeuqmbmxzhbjwsnfkizvbcyoghyvnxxjavoahlqjxomtsouzoog\nhrsantdquixzjyjtqytcmnflnyehzbibkbgkqffgqpkgeuqmbmxzhbjwsnfkizvbcyoghyvnxxjavoahlqjxomtsouzooh",
"output": "No such string"
},
{
"input": "kexdbtpkjbwwyibjndbtmwqzolopqitgkomqggojevoankiepxirrcidxldlzsppehmoazdywltmjbxgsxgihwnwpmczjrcwpywl\nkexdbtpkjbwwyibjndbtmwqzolopqitgkomqggojevoankiepxirrcidxldlzsppehmoazdywltmjbxgsxgihwnwpmczjrcwpywm",
"output": "No such string"
},
{
"input": "yijdysvzfcnaedvnecswgoylhzgguxecmucepgstjbdkbjyfdlxxxejkrrxfiuwjpdmdhhqhlqeqzjwudtdryrfkpwfxdjlkowmk\nyijdysvzfcnaedvnecswgoylhzgguxecmucepgstjbdkbjyfdlxxxejkrrxfiuwjpdmdhhqhlqeqzjwudtdryrfkpwfxdjlkowml",
"output": "No such string"
},
{
"input": "a\nb",
"output": "No such string"
},
{
"input": "x\nz",
"output": "y"
},
{
"input": "a\nz",
"output": "b"
},
{
"input": "y\nz",
"output": "No such string"
},
{
"input": "zzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzy\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz",
"output": "No such string"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaac",
"output": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaab"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa\nzaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaab"
},
{
"input": "yzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz",
"output": "zaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
},
{
"input": "yyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyy\nzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz",
"output": "yyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyz"
},
{
"input": "aaa\naac",
"output": "aab"
},
{
"input": "aaa\naab",
"output": "No such string"
},
{
"input": "zzx\nzzz",
"output": "zzy"
},
{
"input": "zzy\nzzz",
"output": "No such string"
},
{
"input": "aba\naca",
"output": "abb"
},
{
"input": "aaa\nbbb",
"output": "aab"
},
{
"input": "azzz\ncaaa",
"output": "baaa"
}
] | 1,621,934,521 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 8 | 108 | 0 | a=input()
b=input()
s=''
x=len(a)
for i in range(x):
sub=ord(b[i])-ord(a[i])
if sub==0:
s+=a[i]
else:
s+=chr(ord(a[i])+1)
if s==b:
print('No such string')
else:
print(s)
| Title: Vitaly and Strings
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vitaly is a diligent student who never missed a lesson in his five years of studying in the university. He always does his homework on time and passes his exams in time.
During the last lesson the teacher has provided two strings *s* and *t* to Vitaly. The strings have the same length, they consist of lowercase English letters, string *s* is lexicographically smaller than string *t*. Vitaly wondered if there is such string that is lexicographically larger than string *s* and at the same is lexicographically smaller than string *t*. This string should also consist of lowercase English letters and have the length equal to the lengths of strings *s* and *t*.
Let's help Vitaly solve this easy problem!
Input Specification:
The first line contains string *s* (1<=≤<=|*s*|<=≤<=100), consisting of lowercase English letters. Here, |*s*| denotes the length of the string.
The second line contains string *t* (|*t*|<==<=|*s*|), consisting of lowercase English letters.
It is guaranteed that the lengths of strings *s* and *t* are the same and string *s* is lexicographically less than string *t*.
Output Specification:
If the string that meets the given requirements doesn't exist, print a single string "No such string" (without the quotes).
If such string exists, print it. If there are multiple valid strings, you may print any of them.
Demo Input:
['a\nc\n', 'aaa\nzzz\n', 'abcdefg\nabcdefh\n']
Demo Output:
['b\n', 'kkk\n', 'No such string\n']
Note:
String *s* = *s*<sub class="lower-index">1</sub>*s*<sub class="lower-index">2</sub>... *s*<sub class="lower-index">*n*</sub> is said to be lexicographically smaller than *t* = *t*<sub class="lower-index">1</sub>*t*<sub class="lower-index">2</sub>... *t*<sub class="lower-index">*n*</sub>, if there exists such *i*, that *s*<sub class="lower-index">1</sub> = *t*<sub class="lower-index">1</sub>, *s*<sub class="lower-index">2</sub> = *t*<sub class="lower-index">2</sub>, ... *s*<sub class="lower-index">*i* - 1</sub> = *t*<sub class="lower-index">*i* - 1</sub>, *s*<sub class="lower-index">*i*</sub> < *t*<sub class="lower-index">*i*</sub>. | ```python
a=input()
b=input()
s=''
x=len(a)
for i in range(x):
sub=ord(b[i])-ord(a[i])
if sub==0:
s+=a[i]
else:
s+=chr(ord(a[i])+1)
if s==b:
print('No such string')
else:
print(s)
``` | 0 | |
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"
}
] | 1,651,334,088 | 2,147,483,647 | Python 3 | RUNTIME_ERROR | TESTS | 0 | 15 | 0 | from sys import*
n=int(input())
a=list(map(int,input().split()))
a.append(91)
pr=0
rj=0
for i in a:
if i>pr+15:
print(pr+15)
sys.exit()
pr=i
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
from sys import*
n=int(input())
a=list(map(int,input().split()))
a.append(91)
pr=0
rj=0
for i in a:
if i>pr+15:
print(pr+15)
sys.exit()
pr=i
print(90)
``` | -1 | |
615 | A | Bulbs | PROGRAMMING | 800 | [
"implementation"
] | null | null | Vasya wants to turn on Christmas lights consisting of *m* bulbs. Initially, all bulbs are turned off. There are *n* buttons, each of them is connected to some set of bulbs. Vasya can press any of these buttons. When the button is pressed, it turns on all the bulbs it's connected to. Can Vasya light up all the bulbs?
If Vasya presses the button such that some bulbs connected to it are already turned on, they do not change their state, i.e. remain turned on. | The first line of the input contains integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of buttons and the number of bulbs respectively.
Each of the next *n* lines contains *x**i* (0<=≤<=*x**i*<=≤<=*m*) — the number of bulbs that are turned on by the *i*-th button, and then *x**i* numbers *y**ij* (1<=≤<=*y**ij*<=≤<=*m*) — the numbers of these bulbs. | If it's possible to turn on all *m* bulbs print "YES", otherwise print "NO". | [
"3 4\n2 1 4\n3 1 3 1\n1 2\n",
"3 3\n1 1\n1 2\n1 1\n"
] | [
"YES\n",
"NO\n"
] | In the first sample you can press each button once and turn on all the bulbs. In the 2 sample it is impossible to turn on the 3-rd lamp. | 500 | [
{
"input": "3 4\n2 1 4\n3 1 3 1\n1 2",
"output": "YES"
},
{
"input": "3 3\n1 1\n1 2\n1 1",
"output": "NO"
},
{
"input": "3 4\n1 1\n1 2\n1 3",
"output": "NO"
},
{
"input": "1 5\n5 1 2 3 4 5",
"output": "YES"
},
{
"input": "1 5\n5 4 4 1 2 3",
"output": "NO"
},
{
"input": "1 5\n5 1 1 1 1 5",
"output": "NO"
},
{
"input": "2 5\n4 3 1 4 2\n4 2 3 4 5",
"output": "YES"
},
{
"input": "5 7\n2 6 7\n5 1 1 1 1 1\n3 6 5 4\n0\n4 4 3 2 1",
"output": "YES"
},
{
"input": "100 100\n0\n0\n0\n1 53\n0\n0\n1 34\n1 54\n0\n1 14\n0\n1 33\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n1 82\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n1 34\n0\n0\n1 26\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n1 34\n0\n0\n0\n0\n0\n1 3\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n0\n1 40\n0\n0\n0\n1 26\n0\n0\n0\n0\n0\n1 97\n0\n1 5\n0\n0\n0\n0\n0",
"output": "NO"
},
{
"input": "100 100\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": "NO"
},
{
"input": "5 6\n3 1 2 6\n3 1 2 6\n1 1\n2 3 4\n3 1 5 6",
"output": "YES"
},
{
"input": "5 2\n1 1\n1 1\n1 1\n1 1\n1 1",
"output": "NO"
},
{
"input": "1 4\n3 1 2 3",
"output": "NO"
},
{
"input": "1 4\n3 2 3 4",
"output": "NO"
},
{
"input": "2 4\n3 2 3 4\n1 1",
"output": "YES"
},
{
"input": "2 4\n3 1 2 3\n1 4",
"output": "YES"
},
{
"input": "5 1\n0\n0\n0\n0\n0",
"output": "NO"
},
{
"input": "1 1\n0",
"output": "NO"
},
{
"input": "1 10\n10 1 2 3 4 5 6 7 8 9 10",
"output": "YES"
},
{
"input": "1 1\n1 1",
"output": "YES"
},
{
"input": "1 100\n99 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",
"output": "NO"
},
{
"input": "1 3\n3 1 2 1",
"output": "NO"
},
{
"input": "1 100\n100 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",
"output": "YES"
}
] | 1,598,432,869 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 4 | 124 | 0 | n=list(map(int,input().split()))
li=[]
for i in range(n[0]):
k=list(map(int,input().split()))
for j in k:
if j not in li:
li.append(j)
if len(li)==n[1]:
print('YES')
else:
print('NO')
| Title: Bulbs
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya wants to turn on Christmas lights consisting of *m* bulbs. Initially, all bulbs are turned off. There are *n* buttons, each of them is connected to some set of bulbs. Vasya can press any of these buttons. When the button is pressed, it turns on all the bulbs it's connected to. Can Vasya light up all the bulbs?
If Vasya presses the button such that some bulbs connected to it are already turned on, they do not change their state, i.e. remain turned on.
Input Specification:
The first line of the input contains integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of buttons and the number of bulbs respectively.
Each of the next *n* lines contains *x**i* (0<=≤<=*x**i*<=≤<=*m*) — the number of bulbs that are turned on by the *i*-th button, and then *x**i* numbers *y**ij* (1<=≤<=*y**ij*<=≤<=*m*) — the numbers of these bulbs.
Output Specification:
If it's possible to turn on all *m* bulbs print "YES", otherwise print "NO".
Demo Input:
['3 4\n2 1 4\n3 1 3 1\n1 2\n', '3 3\n1 1\n1 2\n1 1\n']
Demo Output:
['YES\n', 'NO\n']
Note:
In the first sample you can press each button once and turn on all the bulbs. In the 2 sample it is impossible to turn on the 3-rd lamp. | ```python
n=list(map(int,input().split()))
li=[]
for i in range(n[0]):
k=list(map(int,input().split()))
for j in k:
if j not in li:
li.append(j)
if len(li)==n[1]:
print('YES')
else:
print('NO')
``` | 0 | |
1,008 | A | Romaji | PROGRAMMING | 900 | [
"implementation",
"strings"
] | null | null | Vitya has just started learning Berlanese language. It is known that Berlanese uses the Latin alphabet. Vowel letters are "a", "o", "u", "i", and "e". Other letters are consonant.
In Berlanese, there has to be a vowel after every consonant, but there can be any letter after any vowel. The only exception is a consonant "n"; after this letter, there can be any letter (not only a vowel) or there can be no letter at all. For example, the words "harakiri", "yupie", "man", and "nbo" are Berlanese while the words "horse", "king", "my", and "nz" are not.
Help Vitya find out if a word $s$ is Berlanese. | The first line of the input contains the string $s$ consisting of $|s|$ ($1\leq |s|\leq 100$) lowercase Latin letters. | Print "YES" (without quotes) if there is a vowel after every consonant except "n", otherwise print "NO".
You can print each letter in any case (upper or lower). | [
"sumimasen\n",
"ninja\n",
"codeforces\n"
] | [
"YES\n",
"YES\n",
"NO\n"
] | In the first and second samples, a vowel goes after each consonant except "n", so the word is Berlanese.
In the third sample, the consonant "c" goes after the consonant "r", and the consonant "s" stands on the end, so the word is not Berlanese. | 500 | [
{
"input": "sumimasen",
"output": "YES"
},
{
"input": "ninja",
"output": "YES"
},
{
"input": "codeforces",
"output": "NO"
},
{
"input": "auuaoonntanonnuewannnnpuuinniwoonennyolonnnvienonpoujinndinunnenannmuveoiuuhikucuziuhunnnmunzancenen",
"output": "YES"
},
{
"input": "n",
"output": "YES"
},
{
"input": "necnei",
"output": "NO"
},
{
"input": "nternn",
"output": "NO"
},
{
"input": "aucunuohja",
"output": "NO"
},
{
"input": "a",
"output": "YES"
},
{
"input": "b",
"output": "NO"
},
{
"input": "nn",
"output": "YES"
},
{
"input": "nnnzaaa",
"output": "YES"
},
{
"input": "zn",
"output": "NO"
},
{
"input": "ab",
"output": "NO"
},
{
"input": "aaaaaaaaaa",
"output": "YES"
},
{
"input": "aaaaaaaaab",
"output": "NO"
},
{
"input": "aaaaaaaaan",
"output": "YES"
},
{
"input": "baaaaaaaaa",
"output": "YES"
},
{
"input": "naaaaaaaaa",
"output": "YES"
},
{
"input": "nbaaaaaaaa",
"output": "YES"
},
{
"input": "bbaaaaaaaa",
"output": "NO"
},
{
"input": "bnaaaaaaaa",
"output": "NO"
},
{
"input": "eonwonojannonnufimiiniewuqaienokacevecinfuqihatenhunliquuyebayiaenifuexuanenuaounnboancaeowonu",
"output": "YES"
},
{
"input": "uixinnepnlinqaingieianndeakuniooudidonnnqeaituioeneiroionxuowudiooonayenfeonuino",
"output": "NO"
},
{
"input": "nnnnnyigaveteononnnnxaalenxuiiwannntoxonyoqonlejuoxuoconnnentoinnul",
"output": "NO"
},
{
"input": "ndonneasoiunhomuunnhuitonnntunntoanerekonoupunanuauenu",
"output": "YES"
},
{
"input": "anujemogawautiedoneobninnibonuunaoennnyoorufonxionntinimiboonununnnnnleenqunminzayoutanlalo",
"output": "NO"
},
{
"input": "y",
"output": "NO"
},
{
"input": "by",
"output": "NO"
},
{
"input": "yy",
"output": "NO"
},
{
"input": "nbn",
"output": "NO"
},
{
"input": "nz",
"output": "NO"
},
{
"input": "king",
"output": "NO"
},
{
"input": "g",
"output": "NO"
},
{
"input": "az",
"output": "NO"
},
{
"input": "x",
"output": "NO"
},
{
"input": "z",
"output": "NO"
},
{
"input": "yn",
"output": "NO"
},
{
"input": "aeo",
"output": "YES"
},
{
"input": "nb",
"output": "NO"
},
{
"input": "npn",
"output": "NO"
},
{
"input": "kini",
"output": "YES"
},
{
"input": "pya",
"output": "NO"
},
{
"input": "m",
"output": "NO"
},
{
"input": "p",
"output": "NO"
},
{
"input": "aaaaaaaak",
"output": "NO"
},
{
"input": "aab",
"output": "NO"
},
{
"input": "d",
"output": "NO"
},
{
"input": "at",
"output": "NO"
},
{
"input": "aaaaaak",
"output": "NO"
},
{
"input": "aaz",
"output": "NO"
},
{
"input": "aaab",
"output": "NO"
},
{
"input": "s",
"output": "NO"
},
{
"input": "nzzen",
"output": "NO"
},
{
"input": "aeionnhhhn",
"output": "NO"
},
{
"input": "h",
"output": "NO"
},
{
"input": "ny",
"output": "NO"
}
] | 1,636,973,809 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 30 | 0 | a=input()
l=len(a)
c=0
print(l)
k=l-1
for i in range(l):
if(i!=k):
if(a[i]!="a" and a[i]!="e" and a[i]!="i" and a[i]!="o" and a[i]!="u" and a[i]!="n"):
if(a[i+1]=="a" or a[i+1]=="e" or a[i+1]=="i" or a[i+1]=="o" or a[i+1]=="u"):
c=c+1
if(a[i]=="a" or a[i]=="e" or a[i]=="i" or a[i]=="o" or a[i]=="u" or a[i]=="n"):
c=c+1
if(i==k):
if(a[i]=="a" or a[i]=="e" or a[i]=="i" or a[i]=="o" or a[i]=="u" or a[i]=="n"):
c=c+1
if(c==l):
print("YES")
else:
print("NO")
| Title: Romaji
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vitya has just started learning Berlanese language. It is known that Berlanese uses the Latin alphabet. Vowel letters are "a", "o", "u", "i", and "e". Other letters are consonant.
In Berlanese, there has to be a vowel after every consonant, but there can be any letter after any vowel. The only exception is a consonant "n"; after this letter, there can be any letter (not only a vowel) or there can be no letter at all. For example, the words "harakiri", "yupie", "man", and "nbo" are Berlanese while the words "horse", "king", "my", and "nz" are not.
Help Vitya find out if a word $s$ is Berlanese.
Input Specification:
The first line of the input contains the string $s$ consisting of $|s|$ ($1\leq |s|\leq 100$) lowercase Latin letters.
Output Specification:
Print "YES" (without quotes) if there is a vowel after every consonant except "n", otherwise print "NO".
You can print each letter in any case (upper or lower).
Demo Input:
['sumimasen\n', 'ninja\n', 'codeforces\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n']
Note:
In the first and second samples, a vowel goes after each consonant except "n", so the word is Berlanese.
In the third sample, the consonant "c" goes after the consonant "r", and the consonant "s" stands on the end, so the word is not Berlanese. | ```python
a=input()
l=len(a)
c=0
print(l)
k=l-1
for i in range(l):
if(i!=k):
if(a[i]!="a" and a[i]!="e" and a[i]!="i" and a[i]!="o" and a[i]!="u" and a[i]!="n"):
if(a[i+1]=="a" or a[i+1]=="e" or a[i+1]=="i" or a[i+1]=="o" or a[i+1]=="u"):
c=c+1
if(a[i]=="a" or a[i]=="e" or a[i]=="i" or a[i]=="o" or a[i]=="u" or a[i]=="n"):
c=c+1
if(i==k):
if(a[i]=="a" or a[i]=="e" or a[i]=="i" or a[i]=="o" or a[i]=="u" or a[i]=="n"):
c=c+1
if(c==l):
print("YES")
else:
print("NO")
``` | 0 | |
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"
},
{
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{
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},
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},
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{
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},
{
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{
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{
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{
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},
{
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},
{
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},
{
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},
{
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"output": "1110111111110010111000001100101010101011010100101010100101100011001001111111"
},
{
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"output": "10111011000111000101110100101000100111011011100011110110000101010001111010111"
},
{
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},
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{
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},
{
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},
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"output": "010010111000010101000111111110111011001101010000000011010101010101000110111110101001010011001101011"
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"output": "1111111010111111101011111110101111111010111111101011111110101111111010111111101011111110101111111011"
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{
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{
"input": "0\n1",
"output": "1"
}
] | 1,631,175,160 | 2,147,483,647 | Python 3 | OK | TESTS | 102 | 77 | 6,758,400 | '''m = [[0 for i in range(5)] for j in range(5)]
#print(m)
for i in range(5):
l = list(map(int,input().split()))
for j in range(5):
m[i][j] = l[j]
posi=0
posj=0
for i in range(5):
for j in range(5):
if m[i][j] == 1:
posi = i + 1
posj = j + 1
#print(posi,posj)
break
else:
continue
if posi<=3 and posj<=3:
print((3-posi)+(3-posj))
elif posi>=3 and posj<=3:
print((posi-3)+(3-posj))
elif posi<=3 and posj>=3:
print((3-posi)+(posj-3))
else:
print((posi-3)+(posj-3))'''
s1 = input()
s2 = input()
s3 = ""
for i in range(len(s1)):
if s1[i] != s2[i]:
s3 += '1'
else:
s3 += '0'
print(s3)
| 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
'''m = [[0 for i in range(5)] for j in range(5)]
#print(m)
for i in range(5):
l = list(map(int,input().split()))
for j in range(5):
m[i][j] = l[j]
posi=0
posj=0
for i in range(5):
for j in range(5):
if m[i][j] == 1:
posi = i + 1
posj = j + 1
#print(posi,posj)
break
else:
continue
if posi<=3 and posj<=3:
print((3-posi)+(3-posj))
elif posi>=3 and posj<=3:
print((posi-3)+(3-posj))
elif posi<=3 and posj>=3:
print((3-posi)+(posj-3))
else:
print((posi-3)+(posj-3))'''
s1 = input()
s2 = input()
s3 = ""
for i in range(len(s1)):
if s1[i] != s2[i]:
s3 += '1'
else:
s3 += '0'
print(s3)
``` | 3.968161 |
664 | A | Complicated GCD | PROGRAMMING | 800 | [
"math",
"number theory"
] | null | null | Greatest common divisor *GCD*(*a*,<=*b*) of two positive integers *a* and *b* is equal to the biggest integer *d* such that both integers *a* and *b* are divisible by *d*. There are many efficient algorithms to find greatest common divisor *GCD*(*a*,<=*b*), for example, Euclid algorithm.
Formally, find the biggest integer *d*, such that all integers *a*,<=*a*<=+<=1,<=*a*<=+<=2,<=...,<=*b* are divisible by *d*. To make the problem even more complicated we allow *a* and *b* to be up to googol, 10100 — such number do not fit even in 64-bit integer type! | The only line of the input contains two integers *a* and *b* (1<=≤<=*a*<=≤<=*b*<=≤<=10100). | Output one integer — greatest common divisor of all integers from *a* to *b* inclusive. | [
"1 2\n",
"61803398874989484820458683436563811772030917980576 61803398874989484820458683436563811772030917980576\n"
] | [
"1\n",
"61803398874989484820458683436563811772030917980576\n"
] | none | 500 | [
{
"input": "1 2",
"output": "1"
},
{
"input": "61803398874989484820458683436563811772030917980576 61803398874989484820458683436563811772030917980576",
"output": "61803398874989484820458683436563811772030917980576"
},
{
"input": "1 100",
"output": "1"
},
{
"input": "100 100000",
"output": "1"
},
{
"input": "12345 67890123456789123457",
"output": "1"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "2 2",
"output": "2"
},
{
"input": "8392739158839273915883927391588392739158839273915883927391588392739158839273915883927391588392739158 8392739158839273915883927391588392739158839273915883927391588392739158839273915883927391588392739158",
"output": "8392739158839273915883927391588392739158839273915883927391588392739158839273915883927391588392739158"
},
{
"input": "1 10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
"output": "1"
},
{
"input": "8328748239473982794239847237438782379810988324751 9328748239473982794239847237438782379810988324751",
"output": "1"
},
{
"input": "1029398958432734901284327523909481928483573793 1029398958432734901284327523909481928483573794",
"output": "1"
},
{
"input": "10000 1000000000",
"output": "1"
},
{
"input": "10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
"output": "10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000"
},
{
"input": "11210171722243 65715435710585778347",
"output": "1"
},
{
"input": "2921881079263974825226940825843 767693191032295360887755303860323261471",
"output": "1"
},
{
"input": "8025352957265704896940312528736939363590612908210603 96027920417708260814607687034511406492969694925539085",
"output": "1"
},
{
"input": "23510978780782786207241069904470895053213996267165977112058175452757132930 210352653280909370107314249722987050753257161175393375412301228883856435481424",
"output": "1"
},
{
"input": "8150070767079366215626260746398623663859344142817267779361251788637547414925170226504788118262 49924902262298336032630839998470954964895251605110946547855439236151401194070172107435992986913614",
"output": "1"
},
{
"input": "15943150466658398903 15943150466658398903",
"output": "15943150466658398903"
},
{
"input": "410470228200245407491525399055972 410470228200245407491525399055972",
"output": "410470228200245407491525399055972"
},
{
"input": "51894705655711504622197349350106792045098781545973899451307 51894705655711504622197349350106792045098781545973899451307",
"output": "51894705655711504622197349350106792045098781545973899451307"
},
{
"input": "60353594589897438036015726222485085035927634677598681595162804007836722215668410 60353594589897438036015726222485085035927634677598681595162804007836722215668410",
"output": "60353594589897438036015726222485085035927634677598681595162804007836722215668410"
},
{
"input": "761733780145118977868180796896376577405349682060892737466239031663476251177476275459280340045369535 761733780145118977868180796896376577405349682060892737466239031663476251177476275459280340045369535",
"output": "761733780145118977868180796896376577405349682060892737466239031663476251177476275459280340045369535"
},
{
"input": "1 2000000000",
"output": "1"
},
{
"input": "13 1928834874",
"output": "1"
},
{
"input": "87 2938984237482934238",
"output": "1"
},
{
"input": "213 413",
"output": "1"
},
{
"input": "3 4",
"output": "1"
}
] | 1,662,665,962 | 2,147,483,647 | PyPy 3-64 | RUNTIME_ERROR | TESTS | 0 | 77 | 2,867,200 | def file():
import sys
sys.stdin = open('input.txt','r')
sys.stdout = open('output.txt','w')
file()
# ██╗ ██╗ █████╗ ██╗ ██████╗ ███████╗ ████████╗ ██╗ ██╗
# ██║ ██╔╝██╔══██╗██║ ██╔══██╗ ██╔════╝ ██ ╔════╝ ██║ ██║
# █████╔╝ ███████║██║ ██║ ██║ █████╗ ████████║ ███████║
# ██╔═██╗ ██╔══██║██║ ██║ ██║ ██╔══╝ ╔════╝██║ ██╔══██║
# ██║ ██╗██║ ██║███████╗██████╔╝ ███████╗ ████████║ ██║ ██║
# ╚═╝ ╚═╝╚═╝ ╚═╝╚══════╝╚═════╝ ╚══════╝ ╚══════╝╚ ═╝ ╚═╝
MOD = int(1e9)+7
MOD = int(1e9)+7
from math import sqrt,ceil,log,log2,\
floor,gcd,pi,factorial,lcm
from collections import deque
from itertools import permutations
def solve():
print(a if a==b else 1)
if __name__=='__main__':
a,b = input().split()
solve()
| Title: Complicated GCD
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Greatest common divisor *GCD*(*a*,<=*b*) of two positive integers *a* and *b* is equal to the biggest integer *d* such that both integers *a* and *b* are divisible by *d*. There are many efficient algorithms to find greatest common divisor *GCD*(*a*,<=*b*), for example, Euclid algorithm.
Formally, find the biggest integer *d*, such that all integers *a*,<=*a*<=+<=1,<=*a*<=+<=2,<=...,<=*b* are divisible by *d*. To make the problem even more complicated we allow *a* and *b* to be up to googol, 10100 — such number do not fit even in 64-bit integer type!
Input Specification:
The only line of the input contains two integers *a* and *b* (1<=≤<=*a*<=≤<=*b*<=≤<=10100).
Output Specification:
Output one integer — greatest common divisor of all integers from *a* to *b* inclusive.
Demo Input:
['1 2\n', '61803398874989484820458683436563811772030917980576 61803398874989484820458683436563811772030917980576\n']
Demo Output:
['1\n', '61803398874989484820458683436563811772030917980576\n']
Note:
none | ```python
def file():
import sys
sys.stdin = open('input.txt','r')
sys.stdout = open('output.txt','w')
file()
# ██╗ ██╗ █████╗ ██╗ ██████╗ ███████╗ ████████╗ ██╗ ██╗
# ██║ ██╔╝██╔══██╗██║ ██╔══██╗ ██╔════╝ ██ ╔════╝ ██║ ██║
# █████╔╝ ███████║██║ ██║ ██║ █████╗ ████████║ ███████║
# ██╔═██╗ ██╔══██║██║ ██║ ██║ ██╔══╝ ╔════╝██║ ██╔══██║
# ██║ ██╗██║ ██║███████╗██████╔╝ ███████╗ ████████║ ██║ ██║
# ╚═╝ ╚═╝╚═╝ ╚═╝╚══════╝╚═════╝ ╚══════╝ ╚══════╝╚ ═╝ ╚═╝
MOD = int(1e9)+7
MOD = int(1e9)+7
from math import sqrt,ceil,log,log2,\
floor,gcd,pi,factorial,lcm
from collections import deque
from itertools import permutations
def solve():
print(a if a==b else 1)
if __name__=='__main__':
a,b = input().split()
solve()
``` | -1 | |
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"
}
] | 1,694,440,248 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 1 | 46 | 0 | n,m,a = list(map(int,input().split()))
count = 0
if n%a==0:
count+=int(n/a)
else:
count+=int(n/a)+1
if m%a==0:
count+=int(m/a)
else:
count+=int(m/a)+1
print(count) | 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
n,m,a = list(map(int,input().split()))
count = 0
if n%a==0:
count+=int(n/a)
else:
count+=int(n/a)+1
if m%a==0:
count+=int(m/a)
else:
count+=int(m/a)+1
print(count)
``` | 0 |
916 | B | Jamie and Binary Sequence (changed after round) | PROGRAMMING | 2,000 | [
"bitmasks",
"greedy",
"math"
] | null | null | Jamie is preparing a Codeforces round. He has got an idea for a problem, but does not know how to solve it. Help him write a solution to the following problem:
Find *k* integers such that the sum of two to the power of each number equals to the number *n* and the largest integer in the answer is as small as possible. As there may be multiple answers, you are asked to output the lexicographically largest one.
To be more clear, consider all integer sequence with length *k* (*a*1,<=*a*2,<=...,<=*a**k*) with . Give a value to each sequence. Among all sequence(s) that have the minimum *y* value, output the one that is the lexicographically largest.
For definitions of powers and lexicographical order see notes. | The first line consists of two integers *n* and *k* (1<=≤<=*n*<=≤<=1018,<=1<=≤<=*k*<=≤<=105) — the required sum and the length of the sequence. | Output "No" (without quotes) in a single line if there does not exist such sequence. Otherwise, output "Yes" (without quotes) in the first line, and *k* numbers separated by space in the second line — the required sequence.
It is guaranteed that the integers in the answer sequence fit the range [<=-<=1018,<=1018]. | [
"23 5\n",
"13 2\n",
"1 2\n"
] | [
"Yes\n3 3 2 1 0 \n",
"No\n",
"Yes\n-1 -1 \n"
] | Sample 1:
2<sup class="upper-index">3</sup> + 2<sup class="upper-index">3</sup> + 2<sup class="upper-index">2</sup> + 2<sup class="upper-index">1</sup> + 2<sup class="upper-index">0</sup> = 8 + 8 + 4 + 2 + 1 = 23
Answers like (3, 3, 2, 0, 1) or (0, 1, 2, 3, 3) are not lexicographically largest.
Answers like (4, 1, 1, 1, 0) do not have the minimum *y* value.
Sample 2:
It can be shown there does not exist a sequence with length 2.
Sample 3:
<img align="middle" class="tex-formula" src="https://espresso.codeforces.com/a8539b2d27aefc8d2fab6dfd8296d11c36dcaa40.png" style="max-width: 100.0%;max-height: 100.0%;"/>
Powers of 2:
If *x* > 0, then 2<sup class="upper-index">*x*</sup> = 2·2·2·...·2 (*x* times).
If *x* = 0, then 2<sup class="upper-index">*x*</sup> = 1.
If *x* < 0, then <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/766628f1c7814795eac1a0afaa1ff062c40ef29e.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
Lexicographical order:
Given two different sequences of the same length, (*a*<sub class="lower-index">1</sub>, *a*<sub class="lower-index">2</sub>, ... , *a*<sub class="lower-index">*k*</sub>) and (*b*<sub class="lower-index">1</sub>, *b*<sub class="lower-index">2</sub>, ... , *b*<sub class="lower-index">*k*</sub>), the first one is smaller than the second one for the lexicographical order, if and only if *a*<sub class="lower-index">*i*</sub> < *b*<sub class="lower-index">*i*</sub>, for the first *i* where *a*<sub class="lower-index">*i*</sub> and *b*<sub class="lower-index">*i*</sub> differ. | 1,000 | [
{
"input": "23 5",
"output": "Yes\n3 3 2 1 0 "
},
{
"input": "13 2",
"output": "No"
},
{
"input": "1 2",
"output": "Yes\n-1 -1 "
},
{
"input": "1 1",
"output": "Yes\n0 "
},
{
"input": "1000000000000000000 100000",
"output": "Yes\n44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44 44..."
},
{
"input": "7 2",
"output": "No"
},
{
"input": "7 3",
"output": "Yes\n2 1 0 "
},
{
"input": "7 4",
"output": "Yes\n1 1 1 0 "
},
{
"input": "521325125150442808 10",
"output": "No"
},
{
"input": "498518679725149504 1000",
"output": "Yes\n49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49..."
},
{
"input": "464823731286228582 100000",
"output": "Yes\n43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43..."
},
{
"input": "1 4",
"output": "Yes\n-2 -2 -2 -2 "
},
{
"input": "9 4",
"output": "Yes\n2 2 -1 -1 "
},
{
"input": "3 4",
"output": "Yes\n0 0 -1 -1 "
},
{
"input": "144 4",
"output": "Yes\n6 6 3 3 "
},
{
"input": "59 4",
"output": "No"
},
{
"input": "78 4",
"output": "Yes\n6 3 2 1 "
},
{
"input": "192 4",
"output": "Yes\n6 6 5 5 "
},
{
"input": "107 4",
"output": "No"
},
{
"input": "552 5",
"output": "Yes\n8 8 5 2 2 "
},
{
"input": "680 5",
"output": "Yes\n8 8 7 5 3 "
},
{
"input": "808 5",
"output": "Yes\n8 8 8 5 3 "
},
{
"input": "1528 5",
"output": "No"
},
{
"input": "1656 5",
"output": "No"
},
{
"input": "26972 8",
"output": "Yes\n14 13 11 8 6 4 3 2 "
},
{
"input": "23100 8",
"output": "Yes\n14 12 11 9 5 4 3 2 "
},
{
"input": "19228 8",
"output": "Yes\n13 13 11 9 8 4 3 2 "
},
{
"input": "22652 8",
"output": "Yes\n14 12 11 6 5 4 3 2 "
},
{
"input": "26076 8",
"output": "No"
},
{
"input": "329438 10",
"output": "Yes\n18 16 10 9 7 6 4 3 2 1 "
},
{
"input": "12862 10",
"output": "Yes\n12 12 12 9 5 4 3 2 0 0 "
},
{
"input": "96286 10",
"output": "Yes\n15 15 14 13 12 11 4 3 2 1 "
},
{
"input": "12414 10",
"output": "Yes\n12 12 12 6 5 4 3 2 0 0 "
},
{
"input": "95838 10",
"output": "No"
},
{
"input": "1728568411 16",
"output": "No"
},
{
"input": "611684539 16",
"output": "Yes\n28 28 26 22 21 20 18 16 15 12 7 5 4 3 1 0 "
},
{
"input": "84735259 16",
"output": "Yes\n25 25 24 19 18 15 14 13 12 10 8 4 3 1 -1 -1 "
},
{
"input": "6967851387 16",
"output": "No"
},
{
"input": "2145934811 16",
"output": "No"
},
{
"input": "6795804571172 20",
"output": "Yes\n41 41 41 37 35 34 33 30 26 24 23 18 14 13 12 10 9 5 1 1 "
},
{
"input": "1038982654596 20",
"output": "Yes\n38 38 38 37 36 32 31 30 29 27 21 20 16 13 11 9 7 1 0 0 "
},
{
"input": "11277865770724 20",
"output": "No"
},
{
"input": "5525338821444 20",
"output": "No"
},
{
"input": "15764221937572 20",
"output": "No"
},
{
"input": "922239521698513045 30",
"output": "Yes\n58 58 58 55 54 51 50 46 45 44 41 40 39 38 37 36 34 32 30 29 28 23 21 19 17 15 7 4 2 0 "
},
{
"input": "923065764876596469 30",
"output": "No"
},
{
"input": "923892008054679893 30",
"output": "No"
},
{
"input": "924718251232763317 30",
"output": "Yes\n58 58 58 55 54 52 50 48 46 41 38 36 35 32 31 29 25 19 18 15 12 11 10 8 7 5 4 2 -1 -1 "
},
{
"input": "925544490115879445 30",
"output": "Yes\n59 58 55 54 52 51 45 44 40 39 38 35 34 33 32 30 28 27 26 24 21 19 18 16 14 12 9 4 2 0 "
},
{
"input": "926370733293962869 30",
"output": "Yes\n57 57 57 57 57 57 55 54 52 51 49 48 45 40 38 34 33 28 27 22 19 18 17 10 9 6 5 4 2 0 "
},
{
"input": "927196976472046293 30",
"output": "No"
},
{
"input": "928023215355162421 30",
"output": "Yes\n58 58 58 55 54 53 48 37 36 33 31 27 26 25 23 19 18 17 16 14 13 11 10 9 8 5 4 2 -1 -1 "
},
{
"input": "928849458533245845 30",
"output": "No"
},
{
"input": "855969764271400156 30",
"output": "No"
},
{
"input": "856796007449483580 30",
"output": "No"
},
{
"input": "857622246332599708 30",
"output": "Yes\n58 58 57 56 55 54 53 50 49 47 46 45 41 39 38 37 33 32 31 29 21 15 11 10 8 7 4 3 1 1 "
},
{
"input": "858448489510683132 30",
"output": "No"
},
{
"input": "859274728393799260 30",
"output": "Yes\n59 57 56 55 54 53 51 50 47 46 40 39 38 36 28 26 25 22 21 16 15 14 13 12 10 9 6 4 3 2 "
},
{
"input": "860100975866849980 30",
"output": "No"
},
{
"input": "860927214749966108 30",
"output": "No"
},
{
"input": "861753457928049532 30",
"output": "Yes\n58 58 57 56 55 54 53 52 50 48 47 44 37 36 34 30 26 25 24 23 22 18 12 9 8 6 5 4 3 2 "
},
{
"input": "862579701106132957 30",
"output": "No"
},
{
"input": "863405944284216381 30",
"output": "No"
},
{
"input": "374585535361966567 30",
"output": "No"
},
{
"input": "4 1",
"output": "Yes\n2 "
},
{
"input": "4 9",
"output": "Yes\n-1 -1 -1 -1 -1 -1 -1 -2 -2 "
},
{
"input": "4 3",
"output": "Yes\n1 0 0 "
},
{
"input": "4 144",
"output": "Yes\n-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 -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 -6 -7 -8 -9 -10 -11 -12 -13 -14 -15 -16 -17 -18 -19 -20 -21 -21 "
},
{
"input": "4 59",
"output": "Yes\n-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 -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 -30 "
},
{
"input": "4 78",
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{
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{
"input": "4 107",
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{
"input": "5 552",
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},
{
"input": "5 680",
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},
{
"input": "5 808",
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},
{
"input": "5 1528",
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},
{
"input": "5 1656",
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},
{
"input": "8 26972",
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},
{
"input": "8 23100",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "8 19228",
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},
{
"input": "8 22652",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "8 26076",
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},
{
"input": "23 19354",
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},
{
"input": "23 35482",
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},
{
"input": "23 18906",
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},
{
"input": "23 2330",
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},
{
"input": "23 85754",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "23 1882",
"output": "Yes\n-6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6 -6..."
},
{
"input": "23 85306",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "23 68730",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "23 84859",
"output": "Yes\n-11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -11 -1..."
},
{
"input": "23 45148",
"output": "Yes\n-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 -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 -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 -1..."
},
{
"input": "281474976710656 5",
"output": "Yes\n46 46 46 45 45 "
},
{
"input": "288230376151973890 5",
"output": "Yes\n57 57 18 0 0 "
},
{
"input": "36029346774812736 5",
"output": "Yes\n55 39 15 11 6 "
},
{
"input": "901283150305558530 5",
"output": "No"
},
{
"input": "288318372649779720 50",
"output": "Yes\n53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 53 46 44 35 30 27 17 14 9 2 1 0 -1 -2 -3 -4 -5 -6 -6 "
},
{
"input": "513703875844698663 50",
"output": "Yes\n55 55 55 55 55 55 55 55 55 55 55 55 55 55 53 48 43 41 39 38 37 36 34 27 26 25 24 22 21 20 18 17 15 14 13 12 9 5 2 1 -1 -2 -3 -4 -5 -6 -7 -8 -9 -9 "
},
{
"input": "287632104387196918 50",
"output": "Yes\n57 56 55 54 53 52 51 50 48 47 46 44 43 42 41 40 39 38 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 13 12 10 9 8 7 6 5 4 2 1 "
},
{
"input": "864690028406636543 58",
"output": "Yes\n58 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 39 38 37 36 35 34 33 32 31 30 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 0 "
},
{
"input": "576460752303423487 60",
"output": "Yes\n57 57 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 0 "
},
{
"input": "141012366262272 1",
"output": "No"
},
{
"input": "1100585377792 4",
"output": "Yes\n39 39 30 13 "
},
{
"input": "18598239186190594 9",
"output": "Yes\n54 49 44 41 40 21 18 8 1 "
},
{
"input": "18647719372456016 19",
"output": "Yes\n51 51 51 51 51 51 51 51 49 46 31 24 20 16 6 3 2 1 1 "
},
{
"input": "9297478914673158 29",
"output": "Yes\n49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 49 48 43 33 18 11 9 2 0 -1 -2 -3 -4 -4 "
},
{
"input": "668507368948226 39",
"output": "Yes\n45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 45 32 22 16 15 9 0 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -12 -13 -13 "
},
{
"input": "1143595340402690 49",
"output": "Yes\n45 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 44 36 35 27 25 19 12 0 -1 -2 -3 -4 -5 -6 -7 -8 -8 "
},
{
"input": "35527987183872 59",
"output": "Yes\n40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 40 38 36 24 19 18 17 14 7 6 5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -11 "
},
{
"input": "324634416758413825 9",
"output": "No"
},
{
"input": "577030480059438572 19",
"output": "Yes\n59 49 42 41 37 35 33 28 26 23 18 12 10 8 7 6 5 3 2 "
},
{
"input": "185505960265024385 29",
"output": "Yes\n54 54 54 54 54 54 54 54 54 54 52 49 48 43 42 39 37 36 29 24 22 20 15 9 8 7 -1 -2 -2 "
},
{
"input": "57421517433081233 39",
"output": "Yes\n52 52 52 52 52 52 52 52 52 52 52 52 51 50 39 36 31 30 28 27 26 24 20 11 10 8 7 4 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -10 "
},
{
"input": "90131572647657641 49",
"output": "Yes\n52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 52 45 44 42 41 37 36 28 25 23 21 20 18 17 7 5 3 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -12 -12 "
},
{
"input": "732268459757413905 59",
"output": "Yes\n54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 53 51 48 47 43 41 38 35 31 30 28 20 13 10 9 4 -1 -2 -2 "
},
{
"input": "226111453445787190 9",
"output": "No"
},
{
"input": "478818723873062027 19",
"output": "No"
},
{
"input": "337790572680259391 29",
"output": "Yes\n58 55 53 52 44 41 39 37 36 35 34 30 29 28 26 24 20 18 16 13 10 9 8 5 4 3 2 1 0 "
},
{
"input": "168057637182978458 39",
"output": "Yes\n54 54 54 54 54 54 54 54 54 52 50 48 43 42 41 40 39 34 33 32 31 30 28 26 25 20 18 16 13 12 11 8 7 4 3 0 -1 -2 -2 "
},
{
"input": "401486559567818547 49",
"output": "Yes\n54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 54 52 49 46 44 43 42 40 39 38 37 34 33 28 26 24 21 17 13 11 10 9 8 5 4 1 -1 -1 "
},
{
"input": "828935109688089201 59",
"output": "Yes\n55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 47 46 45 44 43 36 34 33 32 29 25 23 22 19 18 17 15 14 12 11 9 6 5 4 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -11 "
},
{
"input": "954687629161163764 9",
"output": "No"
},
{
"input": "287025268967992526 19",
"output": "No"
},
{
"input": "844118423640988373 29",
"output": "No"
},
{
"input": "128233154575908599 39",
"output": "Yes\n56 55 54 50 49 48 47 44 41 40 38 36 35 34 33 32 31 30 29 27 25 23 22 21 19 18 15 13 12 11 10 9 7 6 5 4 2 1 0 "
},
{
"input": "792058388714085231 49",
"output": "Yes\n56 56 56 56 56 56 56 56 56 56 55 54 53 52 51 50 48 47 46 45 44 42 39 38 37 35 30 29 28 26 23 21 19 17 16 15 14 12 11 9 8 6 5 3 2 1 -1 -2 -2 "
},
{
"input": "827183623566145225 59",
"output": "Yes\n55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 55 54 53 52 51 49 47 45 44 43 42 41 40 36 35 34 33 32 30 29 28 27 26 25 23 21 19 18 17 13 12 10 9 7 6 3 -1 -1 "
},
{
"input": "846113779983498737 9",
"output": "No"
},
{
"input": "780248358343081983 19",
"output": "No"
},
{
"input": "576460580458522095 29",
"output": "No"
},
{
"input": "540145805193625598 39",
"output": "No"
},
{
"input": "576388182371377103 49",
"output": "Yes\n58 57 56 55 54 53 52 51 50 49 48 47 45 44 43 42 40 39 38 37 36 35 34 33 32 30 29 28 27 26 25 23 22 21 20 19 17 15 12 11 10 9 8 7 6 3 2 1 0 "
},
{
"input": "567448991726268409 59",
"output": "Yes\n56 56 56 56 56 56 56 55 54 52 51 50 49 48 47 46 45 44 43 41 40 39 38 36 35 32 31 30 29 28 27 25 24 23 22 21 20 19 18 17 16 14 13 11 10 9 8 7 6 5 4 3 -1 -2 -3 -4 -5 -6 -6 "
},
{
"input": "576460752303423487 9",
"output": "No"
},
{
"input": "576460752303423487 19",
"output": "No"
},
{
"input": "864691128455135231 29",
"output": "No"
},
{
"input": "864691128455135231 39",
"output": "No"
},
{
"input": "576460752303423487 49",
"output": "No"
},
{
"input": "864691128455135231 59",
"output": "Yes\n59 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 0 "
},
{
"input": "628839188486443015 2412",
"output": "Yes\n48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48 48..."
},
{
"input": "558445254282313727 89558",
"output": "Yes\n43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43..."
},
{
"input": "576460752303423487 100000",
"output": "Yes\n43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43 43..."
},
{
"input": "1 100000",
"output": "Yes\n-16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -16 -1..."
},
{
"input": "99997 100000",
"output": "Yes\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 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 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 ..."
},
{
"input": "99998 100000",
"output": "Yes\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 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 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 ..."
},
{
"input": "99999 100000",
"output": "Yes\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 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 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 ..."
},
{
"input": "100000 100000",
"output": "Yes\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 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 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 ..."
},
{
"input": "100001 100000",
"output": "Yes\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 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 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": "100002 100000",
"output": "Yes\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 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 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": "100003 100000",
"output": "Yes\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 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 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": "12 202",
"output": "Yes\n-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 -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 -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 -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 -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 -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": "1 4",
"output": "Yes\n-2 -2 -2 -2 "
},
{
"input": "2 64",
"output": "Yes\n-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": "2 8",
"output": "Yes\n-2 -2 -2 -2 -2 -2 -2 -2 "
},
{
"input": "1 5",
"output": "Yes\n-2 -2 -2 -3 -3 "
},
{
"input": "1 7",
"output": "Yes\n-2 -2 -2 -3 -4 -5 -5 "
},
{
"input": "19 5",
"output": "Yes\n3 3 1 -1 -1 "
},
{
"input": "1 30",
"output": "Yes\n-4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -4 -5 -6 -7 -8 -9 -10 -11 -12 -13 -14 -15 -16 -17 -18 -18 "
}
] | 1,516,376,072 | 3,572 | Python 3 | RUNTIME_ERROR | PRETESTS | 4 | 46 | 6,348,800 | n,k=map(int,input().split())
if n==1:
if k==1:
print('Yes')
print(0)
elif k==2:
print('Yes')
print(-1,-1)
else:
print('No')
else:
L=[1]*k
p=[0]*k
if sum(L)>n:
print('No')
elif sum(L)==n:
print('Yes')
print(*p)
else:
nn=n
bi=[]
pui=[]
p=0
while nn!=0:
bi.insert(0,nn%2)
pui.insert(0,p)
p+=1
nn=nn//2
if sum(bi)==k:
if sum([2**pui[i] for i in range(k)])==n:
print('Yes')
print(*pui)
else:
print('No')
elif sum(bi)>k:
print('No')
else:
while sum(bi)<k and sum([2**pui[i] for i in range(k)])!=n:
mx=max(pui)
posmx=pui.index(mx)
posmi=bi.index(0)
pui[posmx]-=1
pui[posmi]=pui[posmx]
bi[posmi]=1
pui.sort(reverse=True)
print('Yes')
print(*pui)
| Title: Jamie and Binary Sequence (changed after round)
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Jamie is preparing a Codeforces round. He has got an idea for a problem, but does not know how to solve it. Help him write a solution to the following problem:
Find *k* integers such that the sum of two to the power of each number equals to the number *n* and the largest integer in the answer is as small as possible. As there may be multiple answers, you are asked to output the lexicographically largest one.
To be more clear, consider all integer sequence with length *k* (*a*1,<=*a*2,<=...,<=*a**k*) with . Give a value to each sequence. Among all sequence(s) that have the minimum *y* value, output the one that is the lexicographically largest.
For definitions of powers and lexicographical order see notes.
Input Specification:
The first line consists of two integers *n* and *k* (1<=≤<=*n*<=≤<=1018,<=1<=≤<=*k*<=≤<=105) — the required sum and the length of the sequence.
Output Specification:
Output "No" (without quotes) in a single line if there does not exist such sequence. Otherwise, output "Yes" (without quotes) in the first line, and *k* numbers separated by space in the second line — the required sequence.
It is guaranteed that the integers in the answer sequence fit the range [<=-<=1018,<=1018].
Demo Input:
['23 5\n', '13 2\n', '1 2\n']
Demo Output:
['Yes\n3 3 2 1 0 \n', 'No\n', 'Yes\n-1 -1 \n']
Note:
Sample 1:
2<sup class="upper-index">3</sup> + 2<sup class="upper-index">3</sup> + 2<sup class="upper-index">2</sup> + 2<sup class="upper-index">1</sup> + 2<sup class="upper-index">0</sup> = 8 + 8 + 4 + 2 + 1 = 23
Answers like (3, 3, 2, 0, 1) or (0, 1, 2, 3, 3) are not lexicographically largest.
Answers like (4, 1, 1, 1, 0) do not have the minimum *y* value.
Sample 2:
It can be shown there does not exist a sequence with length 2.
Sample 3:
<img align="middle" class="tex-formula" src="https://espresso.codeforces.com/a8539b2d27aefc8d2fab6dfd8296d11c36dcaa40.png" style="max-width: 100.0%;max-height: 100.0%;"/>
Powers of 2:
If *x* > 0, then 2<sup class="upper-index">*x*</sup> = 2·2·2·...·2 (*x* times).
If *x* = 0, then 2<sup class="upper-index">*x*</sup> = 1.
If *x* < 0, then <img align="middle" class="tex-formula" src="https://espresso.codeforces.com/766628f1c7814795eac1a0afaa1ff062c40ef29e.png" style="max-width: 100.0%;max-height: 100.0%;"/>.
Lexicographical order:
Given two different sequences of the same length, (*a*<sub class="lower-index">1</sub>, *a*<sub class="lower-index">2</sub>, ... , *a*<sub class="lower-index">*k*</sub>) and (*b*<sub class="lower-index">1</sub>, *b*<sub class="lower-index">2</sub>, ... , *b*<sub class="lower-index">*k*</sub>), the first one is smaller than the second one for the lexicographical order, if and only if *a*<sub class="lower-index">*i*</sub> < *b*<sub class="lower-index">*i*</sub>, for the first *i* where *a*<sub class="lower-index">*i*</sub> and *b*<sub class="lower-index">*i*</sub> differ. | ```python
n,k=map(int,input().split())
if n==1:
if k==1:
print('Yes')
print(0)
elif k==2:
print('Yes')
print(-1,-1)
else:
print('No')
else:
L=[1]*k
p=[0]*k
if sum(L)>n:
print('No')
elif sum(L)==n:
print('Yes')
print(*p)
else:
nn=n
bi=[]
pui=[]
p=0
while nn!=0:
bi.insert(0,nn%2)
pui.insert(0,p)
p+=1
nn=nn//2
if sum(bi)==k:
if sum([2**pui[i] for i in range(k)])==n:
print('Yes')
print(*pui)
else:
print('No')
elif sum(bi)>k:
print('No')
else:
while sum(bi)<k and sum([2**pui[i] for i in range(k)])!=n:
mx=max(pui)
posmx=pui.index(mx)
posmi=bi.index(0)
pui[posmx]-=1
pui[posmi]=pui[posmx]
bi[posmi]=1
pui.sort(reverse=True)
print('Yes')
print(*pui)
``` | -1 | |
450 | B | Jzzhu and Sequences | PROGRAMMING | 1,300 | [
"implementation",
"math"
] | null | null | Jzzhu has invented a kind of sequences, they meet the following property:
You are given *x* and *y*, please calculate *f**n* modulo 1000000007 (109<=+<=7). | The first line contains two integers *x* and *y* (|*x*|,<=|*y*|<=≤<=109). The second line contains a single integer *n* (1<=≤<=*n*<=≤<=2·109). | Output a single integer representing *f**n* modulo 1000000007 (109<=+<=7). | [
"2 3\n3\n",
"0 -1\n2\n"
] | [
"1\n",
"1000000006\n"
] | In the first sample, *f*<sub class="lower-index">2</sub> = *f*<sub class="lower-index">1</sub> + *f*<sub class="lower-index">3</sub>, 3 = 2 + *f*<sub class="lower-index">3</sub>, *f*<sub class="lower-index">3</sub> = 1.
In the second sample, *f*<sub class="lower-index">2</sub> = - 1; - 1 modulo (10<sup class="upper-index">9</sup> + 7) equals (10<sup class="upper-index">9</sup> + 6). | 1,000 | [
{
"input": "2 3\n3",
"output": "1"
},
{
"input": "0 -1\n2",
"output": "1000000006"
},
{
"input": "-9 -11\n12345",
"output": "1000000005"
},
{
"input": "0 0\n1000000000",
"output": "0"
},
{
"input": "-1000000000 1000000000\n2000000000",
"output": "1000000000"
},
{
"input": "-12345678 12345678\n1912345678",
"output": "12345678"
},
{
"input": "728374857 678374857\n1928374839",
"output": "950000007"
},
{
"input": "278374837 992837483\n1000000000",
"output": "721625170"
},
{
"input": "-693849384 502938493\n982838498",
"output": "502938493"
},
{
"input": "-783928374 983738273\n992837483",
"output": "16261734"
},
{
"input": "-872837483 -682738473\n999999999",
"output": "190099010"
},
{
"input": "-892837483 -998273847\n999283948",
"output": "892837483"
},
{
"input": "-283938494 738473848\n1999999999",
"output": "716061513"
},
{
"input": "-278374857 819283838\n1",
"output": "721625150"
},
{
"input": "-1000000000 123456789\n1",
"output": "7"
},
{
"input": "-529529529 -524524524\n2",
"output": "475475483"
},
{
"input": "1 2\n2000000000",
"output": "2"
},
{
"input": "-1 -2\n2000000000",
"output": "1000000005"
},
{
"input": "1 2\n1999999999",
"output": "1"
},
{
"input": "1 2\n1999999998",
"output": "1000000006"
},
{
"input": "1 2\n1999999997",
"output": "1000000005"
},
{
"input": "1 2\n1999999996",
"output": "1000000006"
},
{
"input": "69975122 366233206\n1189460676",
"output": "703741923"
},
{
"input": "812229413 904420051\n806905621",
"output": "812229413"
},
{
"input": "872099024 962697902\n1505821695",
"output": "90598878"
},
{
"input": "887387283 909670917\n754835014",
"output": "112612724"
},
{
"input": "37759824 131342932\n854621399",
"output": "868657075"
},
{
"input": "-246822123 800496170\n626323615",
"output": "753177884"
},
{
"input": "-861439463 974126967\n349411083",
"output": "835566423"
},
{
"input": "-69811049 258093841\n1412447",
"output": "741906166"
},
{
"input": "844509330 -887335829\n123329059",
"output": "844509330"
},
{
"input": "83712471 -876177148\n1213284777",
"output": "40110388"
},
{
"input": "598730524 -718984219\n1282749880",
"output": "401269483"
},
{
"input": "-474244697 -745885656\n1517883612",
"output": "271640959"
},
{
"input": "-502583588 -894906953\n1154189557",
"output": "497416419"
},
{
"input": "-636523651 -873305815\n154879215",
"output": "763217843"
},
{
"input": "721765550 594845720\n78862386",
"output": "126919830"
},
{
"input": "364141461 158854993\n1337196589",
"output": "364141461"
},
{
"input": "878985260 677031952\n394707801",
"output": "798046699"
},
{
"input": "439527072 -24854079\n1129147002",
"output": "464381151"
},
{
"input": "840435009 -612103127\n565968986",
"output": "387896880"
},
{
"input": "875035447 -826471373\n561914518",
"output": "124964560"
},
{
"input": "-342526698 305357084\n70776744",
"output": "352116225"
},
{
"input": "-903244186 899202229\n1527859274",
"output": "899202229"
},
{
"input": "-839482546 815166320\n1127472130",
"output": "839482546"
},
{
"input": "-976992569 -958313041\n1686580818",
"output": "981320479"
},
{
"input": "-497338894 -51069176\n737081851",
"output": "502661113"
},
{
"input": "-697962643 -143148799\n1287886520",
"output": "856851208"
},
{
"input": "-982572938 -482658433\n1259858332",
"output": "982572938"
},
{
"input": "123123 78817\n2000000000",
"output": "78817"
},
{
"input": "1000000000 -1000000000\n3",
"output": "14"
},
{
"input": "-1000000000 1000000000\n6",
"output": "14"
},
{
"input": "2 3\n6",
"output": "1000000006"
},
{
"input": "0 -1\n6",
"output": "1"
},
{
"input": "500000000 -1000000000\n600000003",
"output": "500000014"
},
{
"input": "-1000000000 1000000000\n3",
"output": "999999993"
},
{
"input": "1 3\n6",
"output": "1000000005"
},
{
"input": "1 2\n12",
"output": "1000000006"
},
{
"input": "7 -1000000000\n3",
"output": "0"
},
{
"input": "-999999997 999999997\n6",
"output": "20"
},
{
"input": "3 4\n6",
"output": "1000000006"
},
{
"input": "-1 2\n6",
"output": "1000000004"
},
{
"input": "2 3\n12",
"output": "1000000006"
},
{
"input": "4 18\n6",
"output": "999999993"
},
{
"input": "1 2\n6",
"output": "1000000006"
},
{
"input": "1000000000 -1000000000\n6",
"output": "999999993"
},
{
"input": "999999999 -999999999\n3",
"output": "16"
},
{
"input": "-1 0\n1",
"output": "1000000006"
},
{
"input": "1000000000 -1000000000\n9",
"output": "14"
},
{
"input": "999999999 -1000000000\n12",
"output": "999999992"
},
{
"input": "1000000000 -7\n3",
"output": "0"
},
{
"input": "-5 5\n6",
"output": "999999997"
},
{
"input": "5 9\n6",
"output": "1000000003"
},
{
"input": "-15 -10\n1",
"output": "999999992"
}
] | 1,699,006,374 | 2,147,483,647 | Python 3 | OK | TESTS | 74 | 46 | 0 | a, b = map(int, input().split())
n = int(input())
m = 1000000007
c = [a - b, a, b, b - a, -a, -b]
print((c[n % 6] + 2 * m) % m)
| Title: Jzzhu and Sequences
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Jzzhu has invented a kind of sequences, they meet the following property:
You are given *x* and *y*, please calculate *f**n* modulo 1000000007 (109<=+<=7).
Input Specification:
The first line contains two integers *x* and *y* (|*x*|,<=|*y*|<=≤<=109). The second line contains a single integer *n* (1<=≤<=*n*<=≤<=2·109).
Output Specification:
Output a single integer representing *f**n* modulo 1000000007 (109<=+<=7).
Demo Input:
['2 3\n3\n', '0 -1\n2\n']
Demo Output:
['1\n', '1000000006\n']
Note:
In the first sample, *f*<sub class="lower-index">2</sub> = *f*<sub class="lower-index">1</sub> + *f*<sub class="lower-index">3</sub>, 3 = 2 + *f*<sub class="lower-index">3</sub>, *f*<sub class="lower-index">3</sub> = 1.
In the second sample, *f*<sub class="lower-index">2</sub> = - 1; - 1 modulo (10<sup class="upper-index">9</sup> + 7) equals (10<sup class="upper-index">9</sup> + 6). | ```python
a, b = map(int, input().split())
n = int(input())
m = 1000000007
c = [a - b, a, b, b - a, -a, -b]
print((c[n % 6] + 2 * m) % m)
``` | 3 | |
0 | none | none | none | 0 | [
"none"
] | null | null | Polycarp has interviewed Oleg and has written the interview down without punctuation marks and spaces to save time. Thus, the interview is now a string *s* consisting of *n* lowercase English letters.
There is a filler word ogo in Oleg's speech. All words that can be obtained from ogo by adding go several times to the end of it are also considered to be fillers. For example, the words ogo, ogogo, ogogogo are fillers, but the words go, og, ogog, ogogog and oggo are not fillers.
The fillers have maximal size, for example, for ogogoo speech we can't consider ogo a filler and goo as a normal phrase. We should consider ogogo as a filler here.
To print the interview, Polycarp has to replace each of the fillers with three asterisks. Note that a filler word is replaced with exactly three asterisks regardless of its length.
Polycarp has dealt with this problem in no time. Can you do the same? The clock is ticking! | The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100) — the length of the interview.
The second line contains the string *s* of length *n*, consisting of lowercase English letters. | Print the interview text after the replacement of each of the fillers with "***". It is allowed for the substring "***" to have several consecutive occurences. | [
"7\naogogob\n",
"13\nogogmgogogogo\n",
"9\nogoogoogo\n"
] | [
"a***b\n",
"***gmg***\n",
"*********\n"
] | The first sample contains one filler word ogogo, so the interview for printing is "a***b".
The second sample contains two fillers ogo and ogogogo. Thus, the interview is transformed to "***gmg***". | 0 | [
{
"input": "7\naogogob",
"output": "a***b"
},
{
"input": "13\nogogmgogogogo",
"output": "***gmg***"
},
{
"input": "9\nogoogoogo",
"output": "*********"
},
{
"input": "32\nabcdefogoghijklmnogoopqrstuvwxyz",
"output": "abcdef***ghijklmn***opqrstuvwxyz"
},
{
"input": "100\nggogogoooggogooggoggogggggogoogoggooooggooggoooggogoooggoggoogggoogoggogggoooggoggoggogggogoogggoooo",
"output": "gg***oogg***oggoggoggggg******ggooooggooggooogg***ooggoggoogggo***ggogggoooggoggoggoggg***ogggoooo"
},
{
"input": "10\nogooggoggo",
"output": "***oggoggo"
},
{
"input": "20\nooggooogooogooogooog",
"output": "ooggoo***o***o***oog"
},
{
"input": "30\ngoggogoooggooggggoggoggoogoggo",
"output": "gogg***ooggooggggoggoggo***ggo"
},
{
"input": "40\nogggogooggoogoogggogooogogggoogggooggooo",
"output": "oggg***oggo***oggg***o***gggoogggooggooo"
},
{
"input": "50\noggggogoogggggggoogogggoooggooogoggogooogogggogooo",
"output": "ogggg***ogggggggo***gggoooggoo***gg***o***ggg***oo"
},
{
"input": "60\nggoooogoggogooogogooggoogggggogogogggggogggogooogogogggogooo",
"output": "ggooo***gg***o***oggooggggg***gggggoggg***o***ggg***oo"
},
{
"input": "70\ngogoooggggoggoggggggoggggoogooogogggggooogggogoogoogoggogggoggogoooooo",
"output": "g***ooggggoggoggggggoggggo***o***gggggoooggg*********ggogggogg***ooooo"
},
{
"input": "80\nooogoggoooggogogoggooooogoogogooogoggggogggggogoogggooogooooooggoggoggoggogoooog",
"output": "oo***ggooogg***ggoooo******o***ggggoggggg***ogggoo***oooooggoggoggogg***ooog"
},
{
"input": "90\nooogoggggooogoggggoooogggggooggoggoggooooooogggoggogggooggggoooooogoooogooggoooogggggooooo",
"output": "oo***ggggoo***ggggoooogggggooggoggoggooooooogggoggogggooggggooooo***oo***oggoooogggggooooo"
},
{
"input": "100\ngooogoggooggggoggoggooooggogoogggoogogggoogogoggogogogoggogggggogggggoogggooogogoggoooggogoooooogogg",
"output": "goo***ggooggggoggoggoooogg***ogggo***gggo***gg***ggogggggogggggoogggoo***ggooogg***oooo***gg"
},
{
"input": "100\ngoogoogggogoooooggoogooogoogoogogoooooogooogooggggoogoggogooogogogoogogooooggoggogoooogooooooggogogo",
"output": "go***oggg***ooooggo***o*********oooo***o***oggggo***gg***o******oooggogg***oo***ooooogg***"
},
{
"input": "100\ngoogoggggogggoooggoogoogogooggoggooggggggogogggogogggoogogggoogoggoggogooogogoooogooggggogggogggoooo",
"output": "go***ggggogggoooggo******oggoggoogggggg***ggg***gggo***gggo***ggogg***o***oo***oggggogggogggoooo"
},
{
"input": "100\nogogogogogoggogogogogogogoggogogogoogoggoggooggoggogoogoooogogoogggogogogogogoggogogogogogogogogogoe",
"output": "***gg***gg******ggoggooggogg******oo***oggg***gg***e"
},
{
"input": "5\nogoga",
"output": "***ga"
},
{
"input": "1\no",
"output": "o"
},
{
"input": "100\nogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogog",
"output": "***g"
},
{
"input": "99\nogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogogo",
"output": "***"
},
{
"input": "5\nggggg",
"output": "ggggg"
},
{
"input": "6\ngoogoo",
"output": "go***o"
},
{
"input": "7\nooogooo",
"output": "oo***oo"
},
{
"input": "8\ngggggggg",
"output": "gggggggg"
},
{
"input": "9\nogggogggg",
"output": "ogggogggg"
},
{
"input": "10\nogogoggogo",
"output": "***gg***"
},
{
"input": "11\noooggooggog",
"output": "oooggooggog"
},
{
"input": "12\nogggooooggog",
"output": "ogggooooggog"
},
{
"input": "13\nogoggogogooog",
"output": "***gg***oog"
},
{
"input": "15\nggooogoooggoggg",
"output": "ggoo***ooggoggg"
},
{
"input": "14\noogooooggooggo",
"output": "o***oooggooggo"
},
{
"input": "1\na",
"output": "a"
},
{
"input": "1\ng",
"output": "g"
},
{
"input": "1\nz",
"output": "z"
},
{
"input": "46\nsdfkogogogogergergogogergerogogogogoergoegogog",
"output": "sdfk***gergerg***gerger***ergoeg***g"
},
{
"input": "86\ngdfggogogodfogogdofgoodfogodgodgfogoogdodhbofgobgbgfogoogdfogogogogogoogggsgfosogodgon",
"output": "gdfgg***df***gdofgoodf***dgodgf***ogdodhbofgobgbgf***ogdf***ogggsgfos***dgon"
},
{
"input": "83\nergegergoogogogerogoerorogroeorgefxcfgzdgawofqpwzxcvbnmsdfkfpweoriqgtogooggsdgogoog",
"output": "ergegergo***ger***erorogroeorgefxcfgzdgawofqpwzxcvbnmsdfkfpweoriqgt***oggsdg***og"
},
{
"input": "2\nog",
"output": "og"
},
{
"input": "4\nogog",
"output": "***g"
},
{
"input": "4\nogoo",
"output": "***o"
},
{
"input": "29\naaaogogogogogogogogogogogobbb",
"output": "aaa***bbb"
},
{
"input": "11\nogogogogogo",
"output": "***"
},
{
"input": "9\nogogogogo",
"output": "***"
},
{
"input": "3\nogo",
"output": "***"
},
{
"input": "15\nogogogogogogogo",
"output": "***"
},
{
"input": "25\nogogogogogogogogogogogogo",
"output": "***"
}
] | 1,479,634,459 | 1,759 | Python 3 | COMPILATION_ERROR | PRETESTS | 0 | 0 | 0 | n=int.input()
s=str.input()
print str.replace("ogo", "***", 3)
| Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Polycarp has interviewed Oleg and has written the interview down without punctuation marks and spaces to save time. Thus, the interview is now a string *s* consisting of *n* lowercase English letters.
There is a filler word ogo in Oleg's speech. All words that can be obtained from ogo by adding go several times to the end of it are also considered to be fillers. For example, the words ogo, ogogo, ogogogo are fillers, but the words go, og, ogog, ogogog and oggo are not fillers.
The fillers have maximal size, for example, for ogogoo speech we can't consider ogo a filler and goo as a normal phrase. We should consider ogogo as a filler here.
To print the interview, Polycarp has to replace each of the fillers with three asterisks. Note that a filler word is replaced with exactly three asterisks regardless of its length.
Polycarp has dealt with this problem in no time. Can you do the same? The clock is ticking!
Input Specification:
The first line contains a positive integer *n* (1<=≤<=*n*<=≤<=100) — the length of the interview.
The second line contains the string *s* of length *n*, consisting of lowercase English letters.
Output Specification:
Print the interview text after the replacement of each of the fillers with "***". It is allowed for the substring "***" to have several consecutive occurences.
Demo Input:
['7\naogogob\n', '13\nogogmgogogogo\n', '9\nogoogoogo\n']
Demo Output:
['a***b\n', '***gmg***\n', '*********\n']
Note:
The first sample contains one filler word ogogo, so the interview for printing is "a***b".
The second sample contains two fillers ogo and ogogogo. Thus, the interview is transformed to "***gmg***". | ```python
n=int.input()
s=str.input()
print str.replace("ogo", "***", 3)
``` | -1 | |
9 | A | Die Roll | PROGRAMMING | 800 | [
"math",
"probabilities"
] | A. Die Roll | 1 | 64 | Yakko, Wakko and Dot, world-famous animaniacs, decided to rest from acting in cartoons, and take a leave to travel a bit. Yakko dreamt to go to Pennsylvania, his Motherland and the Motherland of his ancestors. Wakko thought about Tasmania, its beaches, sun and sea. Dot chose Transylvania as the most mysterious and unpredictable place.
But to their great regret, the leave turned to be very short, so it will be enough to visit one of the three above named places. That's why Yakko, as the cleverest, came up with a truly genius idea: let each of the three roll an ordinary six-sided die, and the one with the highest amount of points will be the winner, and will take the other two to the place of his/her dreams.
Yakko thrown a die and got Y points, Wakko — W points. It was Dot's turn. But she didn't hurry. Dot wanted to know for sure what were her chances to visit Transylvania.
It is known that Yakko and Wakko are true gentlemen, that's why if they have the same amount of points with Dot, they will let Dot win. | The only line of the input file contains two natural numbers Y and W — the results of Yakko's and Wakko's die rolls. | Output the required probability in the form of irreducible fraction in format «A/B», where A — the numerator, and B — the denominator. If the required probability equals to zero, output «0/1». If the required probability equals to 1, output «1/1». | [
"4 2\n"
] | [
"1/2\n"
] | Dot will go to Transylvania, if she is lucky to roll 4, 5 or 6 points. | 0 | [
{
"input": "4 2",
"output": "1/2"
},
{
"input": "1 1",
"output": "1/1"
},
{
"input": "1 2",
"output": "5/6"
},
{
"input": "1 3",
"output": "2/3"
},
{
"input": "1 4",
"output": "1/2"
},
{
"input": "1 5",
"output": "1/3"
},
{
"input": "1 6",
"output": "1/6"
},
{
"input": "2 1",
"output": "5/6"
},
{
"input": "2 2",
"output": "5/6"
},
{
"input": "2 3",
"output": "2/3"
},
{
"input": "2 4",
"output": "1/2"
},
{
"input": "2 5",
"output": "1/3"
},
{
"input": "2 6",
"output": "1/6"
},
{
"input": "3 1",
"output": "2/3"
},
{
"input": "3 2",
"output": "2/3"
},
{
"input": "3 3",
"output": "2/3"
},
{
"input": "3 4",
"output": "1/2"
},
{
"input": "3 5",
"output": "1/3"
},
{
"input": "3 6",
"output": "1/6"
},
{
"input": "4 1",
"output": "1/2"
},
{
"input": "4 3",
"output": "1/2"
},
{
"input": "4 4",
"output": "1/2"
},
{
"input": "4 5",
"output": "1/3"
},
{
"input": "4 6",
"output": "1/6"
},
{
"input": "5 1",
"output": "1/3"
},
{
"input": "5 2",
"output": "1/3"
},
{
"input": "5 3",
"output": "1/3"
},
{
"input": "5 4",
"output": "1/3"
},
{
"input": "5 5",
"output": "1/3"
},
{
"input": "5 6",
"output": "1/6"
},
{
"input": "6 1",
"output": "1/6"
},
{
"input": "6 2",
"output": "1/6"
},
{
"input": "6 3",
"output": "1/6"
},
{
"input": "6 4",
"output": "1/6"
},
{
"input": "6 5",
"output": "1/6"
},
{
"input": "6 6",
"output": "1/6"
}
] | 1,664,249,978 | 2,147,483,647 | PyPy 3-64 | OK | TESTS | 36 | 124 | 0 | def gcd(a, b):
if(b == 1):
return a
elif(b % a == 0):
return a
else:
return gcd(b%a, a)
Y, W = [int(x) for x in input().split()]
high = max(Y, W)
divider = gcd(6 - high + 1, 6)
print(str((6 - high + 1)//divider) + "/" + str(6//divider)) | Title: Die Roll
Time Limit: 1 seconds
Memory Limit: 64 megabytes
Problem Description:
Yakko, Wakko and Dot, world-famous animaniacs, decided to rest from acting in cartoons, and take a leave to travel a bit. Yakko dreamt to go to Pennsylvania, his Motherland and the Motherland of his ancestors. Wakko thought about Tasmania, its beaches, sun and sea. Dot chose Transylvania as the most mysterious and unpredictable place.
But to their great regret, the leave turned to be very short, so it will be enough to visit one of the three above named places. That's why Yakko, as the cleverest, came up with a truly genius idea: let each of the three roll an ordinary six-sided die, and the one with the highest amount of points will be the winner, and will take the other two to the place of his/her dreams.
Yakko thrown a die and got Y points, Wakko — W points. It was Dot's turn. But she didn't hurry. Dot wanted to know for sure what were her chances to visit Transylvania.
It is known that Yakko and Wakko are true gentlemen, that's why if they have the same amount of points with Dot, they will let Dot win.
Input Specification:
The only line of the input file contains two natural numbers Y and W — the results of Yakko's and Wakko's die rolls.
Output Specification:
Output the required probability in the form of irreducible fraction in format «A/B», where A — the numerator, and B — the denominator. If the required probability equals to zero, output «0/1». If the required probability equals to 1, output «1/1».
Demo Input:
['4 2\n']
Demo Output:
['1/2\n']
Note:
Dot will go to Transylvania, if she is lucky to roll 4, 5 or 6 points. | ```python
def gcd(a, b):
if(b == 1):
return a
elif(b % a == 0):
return a
else:
return gcd(b%a, a)
Y, W = [int(x) for x in input().split()]
high = max(Y, W)
divider = gcd(6 - high + 1, 6)
print(str((6 - high + 1)//divider) + "/" + str(6//divider))
``` | 3.938 |
0 | none | none | none | 0 | [
"none"
] | null | null | Arpa has found a list containing *n* numbers. He calls a list bad if and only if it is not empty and gcd (see notes section for more information) of numbers in the list is 1.
Arpa can perform two types of operations:
- Choose a number and delete it with cost *x*. - Choose a number and increase it by 1 with cost *y*.
Arpa can apply these operations to as many numbers as he wishes, and he is allowed to apply the second operation arbitrarily many times on the same number.
Help Arpa to find the minimum possible cost to make the list good. | First line contains three integers *n*, *x* and *y* (1<=≤<=*n*<=≤<=5·105, 1<=≤<=*x*,<=*y*<=≤<=109) — the number of elements in the list and the integers *x* and *y*.
Second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=106) — the elements of the list. | Print a single integer: the minimum possible cost to make the list good. | [
"4 23 17\n1 17 17 16\n",
"10 6 2\n100 49 71 73 66 96 8 60 41 63\n"
] | [
"40\n",
"10\n"
] | In example, number 1 must be deleted (with cost 23) and number 16 must increased by 1 (with cost 17).
A gcd (greatest common divisor) of a set of numbers is the maximum integer that divides all integers in the set. Read more about gcd [here](https://en.wikipedia.org/wiki/Greatest_common_divisor). | 0 | [] | 1,504,539,518 | 3,818 | Python 3 | COMPILATION_ERROR | PRETESTS | 0 | 0 | 0 | import java.io.BufferedReader;
import java.io.IOException;
import java.io.InputStreamReader;
import java.math.BigInteger;
import java.util.*;
import java.util.concurrent.ThreadLocalRandom;
import java.util.concurrent.atomic.AtomicLong;
import java.util.stream.Collectors;
import java.util.stream.IntStream;
import java.util.stream.Stream;
public class ArpaNumbers {
public static void main(String[] args) {
FastScanner scanner = new FastScanner();
int n = scanner.nextInt();
long x = scanner.nextLong();
long y = scanner.nextLong();
int[] a = scanner.nextIntArray(n);
int[] primeList = new int[78498];
primeSieve(primeList);
long bestCost = n*x;
long currentCost = 0;
int prime = 0;
int modVal = 0;
for (int i=0;i<78498;i++) {
prime = primeList[i];
currentCost = 0;
for (int j=0;j<n;j++) {
modVal = a[j] % prime;
modVal = (modVal==0 ? 0 : prime-modVal);
currentCost+= (x<modVal*y ? x : modVal*y);
}
bestCost = (currentCost<bestCost ? currentCost : bestCost);
}
System.out.println(bestCost);
}
public static void primeSieve(int primeList[]) {
int n = 1000000;
// initially assume all integers are prime
boolean[] isPrime = new boolean[n+1];
for (int i = 2; i <= n; i++) {
isPrime[i] = true;
}
// mark non-primes <= n using Sieve of Eratosthenes
for (int factor = 2; factor*factor <= n; factor++) {
// if factor is prime, then mark multiples of factor as nonprime
// suffices to consider mutiples factor, factor+1, ..., n/factor
if (isPrime[factor]) {
for (int j = factor; factor*j <= n; j++) {
isPrime[factor*j] = false;
}
}
}
int primes = 0;
for (int i = 2; i <= n; i++) {
if (isPrime[i]) {
primeList[primes] = i;
primes++;
}
}
}
static class GroupContainer {
int number;
public GroupContainer(int number) {
this.number = number;
}
}
public static class FastScanner {
BufferedReader br;
StringTokenizer st;
public FastScanner() {
br = new BufferedReader(new InputStreamReader(System.in));
}
String nextToken() {
while (st == null || !st.hasMoreElements()) {
try {
st = new StringTokenizer(br.readLine());
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
}
return st.nextToken();
}
String nextLine() {
try {
return br.readLine();
} catch (Exception e) {
e.printStackTrace();
throw new RuntimeException();
}
}
int nextInt() {
return Integer.parseInt(nextToken());
}
long nextLong() {
return Long.parseLong(nextToken());
}
double nextDouble() {
return Double.parseDouble(nextToken());
}
int[] nextIntArray(int n) {
int[] res = new int[n];
for (int i = 0; i < n; i++) res[i] = nextInt();
return res;
}
long[] nextLongArray(int n) {
long[] res = new long[n];
for (int i = 0; i < n; i++) res[i] = nextLong();
return res;
}
String[] nextStringArray(int n) {
String[] res = new String[n];
for (int i = 0; i < n; i++) res[i] = nextToken();
return res;
}
}
}
| Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Arpa has found a list containing *n* numbers. He calls a list bad if and only if it is not empty and gcd (see notes section for more information) of numbers in the list is 1.
Arpa can perform two types of operations:
- Choose a number and delete it with cost *x*. - Choose a number and increase it by 1 with cost *y*.
Arpa can apply these operations to as many numbers as he wishes, and he is allowed to apply the second operation arbitrarily many times on the same number.
Help Arpa to find the minimum possible cost to make the list good.
Input Specification:
First line contains three integers *n*, *x* and *y* (1<=≤<=*n*<=≤<=5·105, 1<=≤<=*x*,<=*y*<=≤<=109) — the number of elements in the list and the integers *x* and *y*.
Second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=106) — the elements of the list.
Output Specification:
Print a single integer: the minimum possible cost to make the list good.
Demo Input:
['4 23 17\n1 17 17 16\n', '10 6 2\n100 49 71 73 66 96 8 60 41 63\n']
Demo Output:
['40\n', '10\n']
Note:
In example, number 1 must be deleted (with cost 23) and number 16 must increased by 1 (with cost 17).
A gcd (greatest common divisor) of a set of numbers is the maximum integer that divides all integers in the set. Read more about gcd [here](https://en.wikipedia.org/wiki/Greatest_common_divisor). | ```python
import java.io.BufferedReader;
import java.io.IOException;
import java.io.InputStreamReader;
import java.math.BigInteger;
import java.util.*;
import java.util.concurrent.ThreadLocalRandom;
import java.util.concurrent.atomic.AtomicLong;
import java.util.stream.Collectors;
import java.util.stream.IntStream;
import java.util.stream.Stream;
public class ArpaNumbers {
public static void main(String[] args) {
FastScanner scanner = new FastScanner();
int n = scanner.nextInt();
long x = scanner.nextLong();
long y = scanner.nextLong();
int[] a = scanner.nextIntArray(n);
int[] primeList = new int[78498];
primeSieve(primeList);
long bestCost = n*x;
long currentCost = 0;
int prime = 0;
int modVal = 0;
for (int i=0;i<78498;i++) {
prime = primeList[i];
currentCost = 0;
for (int j=0;j<n;j++) {
modVal = a[j] % prime;
modVal = (modVal==0 ? 0 : prime-modVal);
currentCost+= (x<modVal*y ? x : modVal*y);
}
bestCost = (currentCost<bestCost ? currentCost : bestCost);
}
System.out.println(bestCost);
}
public static void primeSieve(int primeList[]) {
int n = 1000000;
// initially assume all integers are prime
boolean[] isPrime = new boolean[n+1];
for (int i = 2; i <= n; i++) {
isPrime[i] = true;
}
// mark non-primes <= n using Sieve of Eratosthenes
for (int factor = 2; factor*factor <= n; factor++) {
// if factor is prime, then mark multiples of factor as nonprime
// suffices to consider mutiples factor, factor+1, ..., n/factor
if (isPrime[factor]) {
for (int j = factor; factor*j <= n; j++) {
isPrime[factor*j] = false;
}
}
}
int primes = 0;
for (int i = 2; i <= n; i++) {
if (isPrime[i]) {
primeList[primes] = i;
primes++;
}
}
}
static class GroupContainer {
int number;
public GroupContainer(int number) {
this.number = number;
}
}
public static class FastScanner {
BufferedReader br;
StringTokenizer st;
public FastScanner() {
br = new BufferedReader(new InputStreamReader(System.in));
}
String nextToken() {
while (st == null || !st.hasMoreElements()) {
try {
st = new StringTokenizer(br.readLine());
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
}
return st.nextToken();
}
String nextLine() {
try {
return br.readLine();
} catch (Exception e) {
e.printStackTrace();
throw new RuntimeException();
}
}
int nextInt() {
return Integer.parseInt(nextToken());
}
long nextLong() {
return Long.parseLong(nextToken());
}
double nextDouble() {
return Double.parseDouble(nextToken());
}
int[] nextIntArray(int n) {
int[] res = new int[n];
for (int i = 0; i < n; i++) res[i] = nextInt();
return res;
}
long[] nextLongArray(int n) {
long[] res = new long[n];
for (int i = 0; i < n; i++) res[i] = nextLong();
return res;
}
String[] nextStringArray(int n) {
String[] res = new String[n];
for (int i = 0; i < n; i++) res[i] = nextToken();
return res;
}
}
}
``` | -1 | |
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"
}
] | 1,568,814,362 | 2,147,483,647 | Python 3 | OK | TESTS | 84 | 124 | 0 | c=1; input(); l=sorted(set(map(int,input().split())))
for i in range(len(l)-1):
if l[i+1]-l[i]==1:c+=1
else:c=1
if c==3:break
print(["NO","YES"][c==3]) | 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
c=1; input(); l=sorted(set(map(int,input().split())))
for i in range(len(l)-1):
if l[i+1]-l[i]==1:c+=1
else:c=1
if c==3:break
print(["NO","YES"][c==3])
``` | 3 | |
962 | A | Equator | PROGRAMMING | 1,300 | [
"implementation"
] | null | null | Polycarp has created his own training plan to prepare for the programming contests. He will train for $n$ days, all days are numbered from $1$ to $n$, beginning from the first.
On the $i$-th day Polycarp will necessarily solve $a_i$ problems. One evening Polycarp plans to celebrate the equator. He will celebrate it on the first evening of such a day that from the beginning of the training and to this day inclusive he will solve half or more of all the problems.
Determine the index of day when Polycarp will celebrate the equator. | The first line contains a single integer $n$ ($1 \le n \le 200\,000$) — the number of days to prepare for the programming contests.
The second line contains a sequence $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 10\,000$), where $a_i$ equals to the number of problems, which Polycarp will solve on the $i$-th day. | Print the index of the day when Polycarp will celebrate the equator. | [
"4\n1 3 2 1\n",
"6\n2 2 2 2 2 2\n"
] | [
"2\n",
"3\n"
] | In the first example Polycarp will celebrate the equator on the evening of the second day, because up to this day (inclusive) he will solve $4$ out of $7$ scheduled problems on four days of the training.
In the second example Polycarp will celebrate the equator on the evening of the third day, because up to this day (inclusive) he will solve $6$ out of $12$ scheduled problems on six days of the training. | 0 | [
{
"input": "4\n1 3 2 1",
"output": "2"
},
{
"input": "6\n2 2 2 2 2 2",
"output": "3"
},
{
"input": "1\n10000",
"output": "1"
},
{
"input": "3\n2 1 1",
"output": "1"
},
{
"input": "2\n1 3",
"output": "2"
},
{
"input": "4\n2 1 1 3",
"output": "3"
},
{
"input": "3\n1 1 3",
"output": "3"
},
{
"input": "3\n1 1 1",
"output": "2"
},
{
"input": "2\n1 2",
"output": "2"
},
{
"input": "3\n2 1 2",
"output": "2"
},
{
"input": "5\n1 2 4 3 5",
"output": "4"
},
{
"input": "5\n2 2 2 4 3",
"output": "4"
},
{
"input": "4\n1 2 3 1",
"output": "3"
},
{
"input": "6\n7 3 10 7 3 11",
"output": "4"
},
{
"input": "2\n3 4",
"output": "2"
},
{
"input": "5\n1 1 1 1 1",
"output": "3"
},
{
"input": "4\n1 3 2 3",
"output": "3"
},
{
"input": "2\n2 3",
"output": "2"
},
{
"input": "3\n32 10 23",
"output": "2"
},
{
"input": "7\n1 1 1 1 1 1 1",
"output": "4"
},
{
"input": "3\n1 2 4",
"output": "3"
},
{
"input": "6\n3 3 3 2 4 4",
"output": "4"
},
{
"input": "9\n1 1 1 1 1 1 1 1 1",
"output": "5"
},
{
"input": "5\n1 3 3 1 1",
"output": "3"
},
{
"input": "4\n1 1 1 2",
"output": "3"
},
{
"input": "4\n1 2 1 3",
"output": "3"
},
{
"input": "3\n2 2 1",
"output": "2"
},
{
"input": "4\n2 3 3 3",
"output": "3"
},
{
"input": "4\n3 2 3 3",
"output": "3"
},
{
"input": "4\n2 1 1 1",
"output": "2"
},
{
"input": "3\n2 1 4",
"output": "3"
},
{
"input": "2\n6 7",
"output": "2"
},
{
"input": "4\n3 3 4 3",
"output": "3"
},
{
"input": "4\n1 1 2 5",
"output": "4"
},
{
"input": "4\n1 8 7 3",
"output": "3"
},
{
"input": "6\n2 2 2 2 2 3",
"output": "4"
},
{
"input": "3\n2 2 5",
"output": "3"
},
{
"input": "4\n1 1 2 1",
"output": "3"
},
{
"input": "5\n1 1 2 2 3",
"output": "4"
},
{
"input": "5\n9 5 3 4 8",
"output": "3"
},
{
"input": "3\n3 3 1",
"output": "2"
},
{
"input": "4\n1 2 2 2",
"output": "3"
},
{
"input": "3\n1 3 5",
"output": "3"
},
{
"input": "4\n1 1 3 6",
"output": "4"
},
{
"input": "6\n1 2 1 1 1 1",
"output": "3"
},
{
"input": "3\n3 1 3",
"output": "2"
},
{
"input": "5\n3 4 5 1 2",
"output": "3"
},
{
"input": "11\n1 1 1 1 1 1 1 1 1 1 1",
"output": "6"
},
{
"input": "5\n3 1 2 5 2",
"output": "4"
},
{
"input": "4\n1 1 1 4",
"output": "4"
},
{
"input": "4\n2 6 1 10",
"output": "4"
},
{
"input": "4\n2 2 3 2",
"output": "3"
},
{
"input": "4\n4 2 2 1",
"output": "2"
},
{
"input": "6\n1 1 1 1 1 4",
"output": "5"
},
{
"input": "3\n3 2 2",
"output": "2"
},
{
"input": "6\n1 3 5 1 7 4",
"output": "5"
},
{
"input": "5\n1 2 4 8 16",
"output": "5"
},
{
"input": "5\n1 2 4 4 4",
"output": "4"
},
{
"input": "6\n4 2 1 2 3 1",
"output": "3"
},
{
"input": "4\n3 2 1 5",
"output": "3"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "3\n2 4 7",
"output": "3"
},
{
"input": "5\n1 1 1 1 3",
"output": "4"
},
{
"input": "3\n3 1 5",
"output": "3"
},
{
"input": "4\n1 2 3 7",
"output": "4"
},
{
"input": "3\n1 4 6",
"output": "3"
},
{
"input": "4\n2 1 2 2",
"output": "3"
},
{
"input": "2\n4 5",
"output": "2"
},
{
"input": "5\n1 2 1 2 1",
"output": "3"
},
{
"input": "3\n2 3 6",
"output": "3"
},
{
"input": "6\n1 1 4 1 1 5",
"output": "4"
},
{
"input": "5\n2 2 2 2 1",
"output": "3"
},
{
"input": "2\n5 6",
"output": "2"
},
{
"input": "4\n2 2 1 4",
"output": "3"
},
{
"input": "5\n2 2 3 4 4",
"output": "4"
},
{
"input": "4\n3 1 1 2",
"output": "2"
},
{
"input": "5\n3 4 1 4 5",
"output": "4"
},
{
"input": "4\n1 3 1 6",
"output": "4"
},
{
"input": "5\n1 1 1 2 2",
"output": "4"
},
{
"input": "4\n1 4 2 4",
"output": "3"
},
{
"input": "10\n1 1 1 1 1 1 1 1 1 8",
"output": "9"
},
{
"input": "4\n1 4 5 1",
"output": "3"
},
{
"input": "5\n1 1 1 1 5",
"output": "5"
},
{
"input": "4\n1 3 4 1",
"output": "3"
},
{
"input": "4\n2 2 2 3",
"output": "3"
},
{
"input": "4\n2 3 2 4",
"output": "3"
},
{
"input": "5\n2 2 1 2 2",
"output": "3"
},
{
"input": "3\n4 3 2",
"output": "2"
},
{
"input": "3\n6 5 2",
"output": "2"
},
{
"input": "69\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",
"output": "35"
},
{
"input": "6\n1 1 1 1 1 2",
"output": "4"
},
{
"input": "5\n1 2 5 4 5",
"output": "4"
},
{
"input": "2\n9 10",
"output": "2"
},
{
"input": "3\n1 1 5",
"output": "3"
},
{
"input": "4\n3 4 3 5",
"output": "3"
},
{
"input": "4\n1 4 3 3",
"output": "3"
},
{
"input": "4\n7 1 3 4",
"output": "2"
},
{
"input": "3\n100 100 1",
"output": "2"
},
{
"input": "4\n5 2 2 2",
"output": "2"
}
] | 1,587,892,281 | 2,147,483,647 | PyPy 3 | OK | TESTS | 106 | 217 | 14,848,000 | n = int(input())
a = [int(x) for x in input().split()]
total = sum(a)
total = total//2 + total%2
s = 0
for i in range(n):
s += a[i]
if s>=total:
print(i+1)
break
| Title: Equator
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Polycarp has created his own training plan to prepare for the programming contests. He will train for $n$ days, all days are numbered from $1$ to $n$, beginning from the first.
On the $i$-th day Polycarp will necessarily solve $a_i$ problems. One evening Polycarp plans to celebrate the equator. He will celebrate it on the first evening of such a day that from the beginning of the training and to this day inclusive he will solve half or more of all the problems.
Determine the index of day when Polycarp will celebrate the equator.
Input Specification:
The first line contains a single integer $n$ ($1 \le n \le 200\,000$) — the number of days to prepare for the programming contests.
The second line contains a sequence $a_1, a_2, \dots, a_n$ ($1 \le a_i \le 10\,000$), where $a_i$ equals to the number of problems, which Polycarp will solve on the $i$-th day.
Output Specification:
Print the index of the day when Polycarp will celebrate the equator.
Demo Input:
['4\n1 3 2 1\n', '6\n2 2 2 2 2 2\n']
Demo Output:
['2\n', '3\n']
Note:
In the first example Polycarp will celebrate the equator on the evening of the second day, because up to this day (inclusive) he will solve $4$ out of $7$ scheduled problems on four days of the training.
In the second example Polycarp will celebrate the equator on the evening of the third day, because up to this day (inclusive) he will solve $6$ out of $12$ scheduled problems on six days of the training. | ```python
n = int(input())
a = [int(x) for x in input().split()]
total = sum(a)
total = total//2 + total%2
s = 0
for i in range(n):
s += a[i]
if s>=total:
print(i+1)
break
``` | 3 | |
538 | A | Cutting Banner | PROGRAMMING | 1,400 | [
"brute force",
"implementation"
] | null | null | A large banner with word CODEFORCES was ordered for the 1000-th onsite round of Codeforcesω that takes place on the Miami beach. Unfortunately, the company that made the banner mixed up two orders and delivered somebody else's banner that contains someone else's word. The word on the banner consists only of upper-case English letters.
There is very little time to correct the mistake. All that we can manage to do is to cut out some substring from the banner, i.e. several consecutive letters. After that all the resulting parts of the banner will be glued into a single piece (if the beginning or the end of the original banner was cut out, only one part remains); it is not allowed change the relative order of parts of the banner (i.e. after a substring is cut, several first and last letters are left, it is allowed only to glue the last letters to the right of the first letters). Thus, for example, for example, you can cut a substring out from string 'TEMPLATE' and get string 'TEMPLE' (if you cut out string AT), 'PLATE' (if you cut out TEM), 'T' (if you cut out EMPLATE), etc.
Help the organizers of the round determine whether it is possible to cut out of the banner some substring in such a way that the remaining parts formed word CODEFORCES. | The single line of the input contains the word written on the banner. The word only consists of upper-case English letters. The word is non-empty and its length doesn't exceed 100 characters. It is guaranteed that the word isn't word CODEFORCES. | Print 'YES', if there exists a way to cut out the substring, and 'NO' otherwise (without the quotes). | [
"CODEWAITFORITFORCES\n",
"BOTTOMCODER\n",
"DECODEFORCES\n",
"DOGEFORCES\n"
] | [
"YES\n",
"NO\n",
"YES\n",
"NO\n"
] | none | 500 | [
{
"input": "CODEWAITFORITFORCES",
"output": "YES"
},
{
"input": "BOTTOMCODER",
"output": "NO"
},
{
"input": "DECODEFORCES",
"output": "YES"
},
{
"input": "DOGEFORCES",
"output": "NO"
},
{
"input": "ABACABA",
"output": "NO"
},
{
"input": "CODEFORCE",
"output": "NO"
},
{
"input": "C",
"output": "NO"
},
{
"input": "NQTSMZEBLY",
"output": "NO"
},
{
"input": "CODEFZORCES",
"output": "YES"
},
{
"input": "EDYKHVZCNTLJUUOQGHPTIOETQNFLLWEKZOHIUAXELGECABVSBIBGQODQXVYFKBYJWTGBYHVSSNTINKWSINWSMALUSIWNJMTCOOVF",
"output": "NO"
},
{
"input": "OCECFDSRDE",
"output": "NO"
},
{
"input": "MDBUWCZFFZKFMJTTJFXRHTGRPREORKDVUXOEMFYSOMSQGHUKGYCRCVJTNDLFDEWFS",
"output": "NO"
},
{
"input": "CODEFYTORCHES",
"output": "NO"
},
{
"input": "BCODEFORCES",
"output": "YES"
},
{
"input": "CVODEFORCES",
"output": "YES"
},
{
"input": "COAKDEFORCES",
"output": "YES"
},
{
"input": "CODFMWEFORCES",
"output": "YES"
},
{
"input": "CODEVCSYRFORCES",
"output": "YES"
},
{
"input": "CODEFXHHPWCVQORCES",
"output": "YES"
},
{
"input": "CODEFORQWUFJLOFFXTXRCES",
"output": "YES"
},
{
"input": "CODEFORBWFURYIDURNRKRDLHCLXZCES",
"output": "YES"
},
{
"input": "CODEFORCQSYSLYKCDFFUPSAZCJIAENCKZUFJZEINQIES",
"output": "YES"
},
{
"input": "CODEFORCEVENMDBQLSVPQIIBGSHBVOPYZXNWVSTVWDRONUREYJJIJIPMEBPQDCPFS",
"output": "YES"
},
{
"input": "CODEFORCESCFNNPAHNHDIPPBAUSPKJYAQDBVZNLSTSDCREZACVLMRFGVKGVHHZLXOHCTJDBQKIDWBUXDUJARLWGFGFCTTXUCAZB",
"output": "YES"
},
{
"input": "CODJRDPDEFOROES",
"output": "NO"
},
{
"input": "CODEFOGSIUZMZCMWAVQHNYFEKIEZQMAZOVEMDRMOEDBHAXPLBLDYYXCVTOOSJZVSQAKFXTBTZFWAYRZEMDEMVDJTDRXXAQBURCES",
"output": "YES"
},
{
"input": "CODEMKUYHAZSGJBQLXTHUCZZRJJJXUSEBOCNZASOKDZHMSGWZSDFBGHXFLABVPDQBJYXSHHAZAKHSTRGOKJYHRVSSUGDCMFOGCES",
"output": "NO"
},
{
"input": "CODEFORCESCODEFORCESCODEFORCESCODEFORCESCODEFORCESCODEFORCESCODEFORCESCODEFORCESCODEFORCES",
"output": "YES"
},
{
"input": "CCODEFORCESODECODEFORCCODEFORCESODCODEFORCESEFCODEFORCESORCODEFORCESCESCESFORCODEFORCESCES",
"output": "NO"
},
{
"input": "CCODEFORCESC",
"output": "NO"
},
{
"input": "CODEAFORBCES",
"output": "NO"
},
{
"input": "CODERRRRRFORCRRRRES",
"output": "NO"
},
{
"input": "CODELFORCELS",
"output": "NO"
},
{
"input": "CPOPDPEPFPOPRPCPEPS",
"output": "NO"
},
{
"input": "COXDEXFORXCEXS",
"output": "NO"
},
{
"input": "CODAAAAAFORCES",
"output": "NO"
},
{
"input": "CAOADEFORCES",
"output": "NO"
},
{
"input": "FORCESXCODE",
"output": "NO"
},
{
"input": "FORCESACODE",
"output": "NO"
},
{
"input": "ACAOADAEFORCES",
"output": "NO"
},
{
"input": "CCODEFORCESS",
"output": "NO"
},
{
"input": "ZCODEFORCEZ",
"output": "NO"
},
{
"input": "CODXEFORXCES",
"output": "NO"
},
{
"input": "CODEFORCEZ",
"output": "NO"
},
{
"input": "CODEFORCEST",
"output": "YES"
},
{
"input": "AXODEFORCES",
"output": "NO"
},
{
"input": "RCODEFORCESR",
"output": "NO"
},
{
"input": "CODECODEFORCESFORCES",
"output": "YES"
},
{
"input": "TTTWWWCODEFORCES",
"output": "YES"
},
{
"input": "CODEFORRCEST",
"output": "NO"
},
{
"input": "UJYTYUCODEFORCES",
"output": "YES"
},
{
"input": "CODEXXXXXXXXXXXXXXXXXXCODEFORCESXXXXXXXXXXXXXXXXXXXXXFORCES",
"output": "YES"
},
{
"input": "COXEDYFORCES",
"output": "NO"
},
{
"input": "UJYTYCODEFORCES",
"output": "YES"
},
{
"input": "UJYTCODEFORCES",
"output": "YES"
}
] | 1,491,464,876 | 2,147,483,647 | Python 3 | OK | TESTS | 55 | 62 | 5,529,600 | strInp = input()
if len(strInp) < 10:
print('NO')
exit()
val = 'CODEFORCES'
cnt = 0
if strInp.find(val) != -1:
if strInp[:len(val)] == val or strInp[-len(val):] == val:
print('YES')
exit()
for letter in strInp:
if val[cnt] == letter:
cnt += 1
else:
print('YES') if strInp[-(len(val) - cnt):] == val[-(len(val) - cnt):] else print('NO')
exit() | Title: Cutting Banner
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A large banner with word CODEFORCES was ordered for the 1000-th onsite round of Codeforcesω that takes place on the Miami beach. Unfortunately, the company that made the banner mixed up two orders and delivered somebody else's banner that contains someone else's word. The word on the banner consists only of upper-case English letters.
There is very little time to correct the mistake. All that we can manage to do is to cut out some substring from the banner, i.e. several consecutive letters. After that all the resulting parts of the banner will be glued into a single piece (if the beginning or the end of the original banner was cut out, only one part remains); it is not allowed change the relative order of parts of the banner (i.e. after a substring is cut, several first and last letters are left, it is allowed only to glue the last letters to the right of the first letters). Thus, for example, for example, you can cut a substring out from string 'TEMPLATE' and get string 'TEMPLE' (if you cut out string AT), 'PLATE' (if you cut out TEM), 'T' (if you cut out EMPLATE), etc.
Help the organizers of the round determine whether it is possible to cut out of the banner some substring in such a way that the remaining parts formed word CODEFORCES.
Input Specification:
The single line of the input contains the word written on the banner. The word only consists of upper-case English letters. The word is non-empty and its length doesn't exceed 100 characters. It is guaranteed that the word isn't word CODEFORCES.
Output Specification:
Print 'YES', if there exists a way to cut out the substring, and 'NO' otherwise (without the quotes).
Demo Input:
['CODEWAITFORITFORCES\n', 'BOTTOMCODER\n', 'DECODEFORCES\n', 'DOGEFORCES\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n', 'NO\n']
Note:
none | ```python
strInp = input()
if len(strInp) < 10:
print('NO')
exit()
val = 'CODEFORCES'
cnt = 0
if strInp.find(val) != -1:
if strInp[:len(val)] == val or strInp[-len(val):] == val:
print('YES')
exit()
for letter in strInp:
if val[cnt] == letter:
cnt += 1
else:
print('YES') if strInp[-(len(val) - cnt):] == val[-(len(val) - cnt):] else print('NO')
exit()
``` | 3 | |
863 | A | Quasi-palindrome | PROGRAMMING | 900 | [
"brute force",
"implementation"
] | null | null | Let quasi-palindromic number be such number that adding some leading zeros (possible none) to it produces a palindromic string.
String *t* is called a palindrome, if it reads the same from left to right and from right to left.
For example, numbers 131 and 2010200 are quasi-palindromic, they can be transformed to strings "131" and "002010200", respectively, which are palindromes.
You are given some integer number *x*. Check if it's a quasi-palindromic number. | The first line contains one integer number *x* (1<=≤<=*x*<=≤<=109). This number is given without any leading zeroes. | Print "YES" if number *x* is quasi-palindromic. Otherwise, print "NO" (without quotes). | [
"131\n",
"320\n",
"2010200\n"
] | [
"YES\n",
"NO\n",
"YES\n"
] | none | 0 | [
{
"input": "131",
"output": "YES"
},
{
"input": "320",
"output": "NO"
},
{
"input": "2010200",
"output": "YES"
},
{
"input": "1",
"output": "YES"
},
{
"input": "1000000000",
"output": "YES"
},
{
"input": "999999999",
"output": "YES"
},
{
"input": "999999998",
"output": "NO"
},
{
"input": "102000",
"output": "NO"
},
{
"input": "210000000",
"output": "NO"
},
{
"input": "213443120",
"output": "YES"
},
{
"input": "99",
"output": "YES"
},
{
"input": "22002",
"output": "NO"
},
{
"input": "1010",
"output": "YES"
},
{
"input": "1201",
"output": "NO"
},
{
"input": "6460046",
"output": "NO"
},
{
"input": "503435",
"output": "NO"
},
{
"input": "21002",
"output": "NO"
},
{
"input": "101001",
"output": "NO"
},
{
"input": "200102",
"output": "NO"
},
{
"input": "20010002",
"output": "NO"
},
{
"input": "33003",
"output": "NO"
},
{
"input": "100101",
"output": "NO"
},
{
"input": "1021",
"output": "NO"
},
{
"input": "1101",
"output": "NO"
},
{
"input": "10101100",
"output": "NO"
},
{
"input": "101",
"output": "YES"
},
{
"input": "1011",
"output": "NO"
},
{
"input": "11010",
"output": "NO"
},
{
"input": "10110",
"output": "NO"
},
{
"input": "110000",
"output": "YES"
},
{
"input": "2011",
"output": "NO"
},
{
"input": "10020001",
"output": "NO"
},
{
"input": "12505021",
"output": "NO"
},
{
"input": "12310",
"output": "NO"
},
{
"input": "100501",
"output": "NO"
},
{
"input": "11001",
"output": "NO"
},
{
"input": "20020002",
"output": "NO"
},
{
"input": "202002",
"output": "NO"
},
{
"input": "1001",
"output": "YES"
},
{
"input": "1020021",
"output": "NO"
},
{
"input": "60660",
"output": "NO"
},
{
"input": "98809",
"output": "NO"
},
{
"input": "11000000",
"output": "YES"
},
{
"input": "807008",
"output": "NO"
}
] | 1,511,584,217 | 1,517 | Python 3 | OK | TESTS | 44 | 62 | 5,529,600 | s = input()
ctr = 0
if s != s[::-1] :
for x in s[::-1] :
if x == '0' :
ctr += 1
else :
break
if ctr : sn = s[: -1 * ctr]
else : sn = s
if sn == sn[::-1] : print('YES')
else : print('NO')
else :
print('YES') | Title: Quasi-palindrome
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Let quasi-palindromic number be such number that adding some leading zeros (possible none) to it produces a palindromic string.
String *t* is called a palindrome, if it reads the same from left to right and from right to left.
For example, numbers 131 and 2010200 are quasi-palindromic, they can be transformed to strings "131" and "002010200", respectively, which are palindromes.
You are given some integer number *x*. Check if it's a quasi-palindromic number.
Input Specification:
The first line contains one integer number *x* (1<=≤<=*x*<=≤<=109). This number is given without any leading zeroes.
Output Specification:
Print "YES" if number *x* is quasi-palindromic. Otherwise, print "NO" (without quotes).
Demo Input:
['131\n', '320\n', '2010200\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n']
Note:
none | ```python
s = input()
ctr = 0
if s != s[::-1] :
for x in s[::-1] :
if x == '0' :
ctr += 1
else :
break
if ctr : sn = s[: -1 * ctr]
else : sn = s
if sn == sn[::-1] : print('YES')
else : print('NO')
else :
print('YES')
``` | 3 | |
0 | none | none | none | 0 | [
"none"
] | null | null | As a tradition, every year before IOI all the members of Natalia Fan Club are invited to Malek Dance Club to have a fun night together. Malek Dance Club has 2*n* members and coincidentally Natalia Fan Club also has 2*n* members. Each member of MDC is assigned a unique id *i* from 0 to 2*n*<=-<=1. The same holds for each member of NFC.
One of the parts of this tradition is one by one dance, where each member of MDC dances with a member of NFC. A dance pair is a pair of numbers (*a*,<=*b*) such that member *a* from MDC dances with member *b* from NFC.
The complexity of a pairs' assignment is the number of pairs of dancing pairs (*a*,<=*b*) and (*c*,<=*d*) such that *a*<=<<=*c* and *b*<=><=*d*.
You are given a binary number of length *n* named *x*. We know that member *i* from MDC dances with member from NFC. Your task is to calculate the complexity of this assignment modulo 1000000007 (109<=+<=7).
Expression denotes applying «XOR» to numbers *x* and *y*. This operation exists in all modern programming languages, for example, in C++ and Java it denotes as «^», in Pascal — «xor». | The first line of input contains a binary number *x* of lenght *n*, (1<=≤<=*n*<=≤<=100).
This number may contain leading zeros. | Print the complexity of the given dance assignent modulo 1000000007 (109<=+<=7). | [
"11\n",
"01\n",
"1\n"
] | [
"6\n",
"2\n",
"1\n"
] | none | 0 | [
{
"input": "11",
"output": "6"
},
{
"input": "01",
"output": "2"
},
{
"input": "1",
"output": "1"
},
{
"input": "1111111111111111111111111111111111",
"output": "68817500"
},
{
"input": "0000000000000000000000000000000000000",
"output": "0"
},
{
"input": "11111111111111111111111111111111111000000000000000000000000000",
"output": "774857564"
},
{
"input": "00000000000000000000111111111111111111111111111111111111111111",
"output": "738177230"
},
{
"input": "10100101000010011110101011011110001",
"output": "374541417"
},
{
"input": "01010100001010111111001111001000101010010101000111011011111000",
"output": "629793317"
},
{
"input": "10001010011010010101101010111001001001011110110101011000010100110",
"output": "276731670"
},
{
"input": "00001100100101000111111100110010001101001000011110110000",
"output": "526794740"
},
{
"input": "01100010011001101100001000000101001000101101000110011100101101111101010100000011101011100",
"output": "67141264"
},
{
"input": "100111100",
"output": "80896"
},
{
"input": "11110111000110101111100100111110000011",
"output": "448062885"
},
{
"input": "1000101010000101111110100110011110000011000110001111001001000110110011110110111110100",
"output": "532893377"
},
{
"input": "0110011110111000001101001010101000011011101001001101000000111101010101111101010011101001111010111001",
"output": "416862683"
},
{
"input": "0111001111110010000001111100110100111110001100100001111111110000010010111010010010010111000110001111",
"output": "777947548"
},
{
"input": "1000000001101010101011111001001101011100011000010000100101001111001000110100100001110001100001000001",
"output": "759144998"
},
{
"input": "1101010110001010100110011011101011010100010001110100010011011100011011000101110001010101110001101011",
"output": "383088952"
},
{
"input": "1000001010111011110011111110011001011111011001110011100101111110100110111001100001110000011101011011",
"output": "928069440"
},
{
"input": "10",
"output": "4"
},
{
"input": "01",
"output": "2"
},
{
"input": "00",
"output": "0"
},
{
"input": "11",
"output": "6"
},
{
"input": "0",
"output": "0"
},
{
"input": "0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000",
"output": "0"
},
{
"input": "1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111",
"output": "261536897"
},
{
"input": "10110",
"output": "352"
},
{
"input": "1100110010110011001011001100101100110010110011001111001100101100110010110011001011001100101100100010",
"output": "499547155"
}
] | 1,649,699,599 | 2,147,483,647 | PyPy 3-64 | WRONG_ANSWER | TESTS | 0 | 92 | 0 | s = input()[::-1]
ans = 0
for i in s:
if i == '0':
ans *= 2
else:
ans = ans * 2 + 2 ** (2 * len(s))
print(ans) | Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
As a tradition, every year before IOI all the members of Natalia Fan Club are invited to Malek Dance Club to have a fun night together. Malek Dance Club has 2*n* members and coincidentally Natalia Fan Club also has 2*n* members. Each member of MDC is assigned a unique id *i* from 0 to 2*n*<=-<=1. The same holds for each member of NFC.
One of the parts of this tradition is one by one dance, where each member of MDC dances with a member of NFC. A dance pair is a pair of numbers (*a*,<=*b*) such that member *a* from MDC dances with member *b* from NFC.
The complexity of a pairs' assignment is the number of pairs of dancing pairs (*a*,<=*b*) and (*c*,<=*d*) such that *a*<=<<=*c* and *b*<=><=*d*.
You are given a binary number of length *n* named *x*. We know that member *i* from MDC dances with member from NFC. Your task is to calculate the complexity of this assignment modulo 1000000007 (109<=+<=7).
Expression denotes applying «XOR» to numbers *x* and *y*. This operation exists in all modern programming languages, for example, in C++ and Java it denotes as «^», in Pascal — «xor».
Input Specification:
The first line of input contains a binary number *x* of lenght *n*, (1<=≤<=*n*<=≤<=100).
This number may contain leading zeros.
Output Specification:
Print the complexity of the given dance assignent modulo 1000000007 (109<=+<=7).
Demo Input:
['11\n', '01\n', '1\n']
Demo Output:
['6\n', '2\n', '1\n']
Note:
none | ```python
s = input()[::-1]
ans = 0
for i in s:
if i == '0':
ans *= 2
else:
ans = ans * 2 + 2 ** (2 * len(s))
print(ans)
``` | 0 | |
527 | B | Error Correct System | PROGRAMMING | 1,500 | [
"greedy"
] | null | null | Ford Prefect got a job as a web developer for a small company that makes towels. His current work task is to create a search engine for the website of the company. During the development process, he needs to write a subroutine for comparing strings *S* and *T* of equal length to be "similar". After a brief search on the Internet, he learned about the Hamming distance between two strings *S* and *T* of the same length, which is defined as the number of positions in which *S* and *T* have different characters. For example, the Hamming distance between words "permanent" and "pergament" is two, as these words differ in the fourth and sixth letters.
Moreover, as he was searching for information, he also noticed that modern search engines have powerful mechanisms to correct errors in the request to improve the quality of search. Ford doesn't know much about human beings, so he assumed that the most common mistake in a request is swapping two arbitrary letters of the string (not necessarily adjacent). Now he wants to write a function that determines which two letters should be swapped in string *S*, so that the Hamming distance between a new string *S* and string *T* would be as small as possible, or otherwise, determine that such a replacement cannot reduce the distance between the strings.
Help him do this! | The first line contains integer *n* (1<=≤<=*n*<=≤<=200<=000) — the length of strings *S* and *T*.
The second line contains string *S*.
The third line contains string *T*.
Each of the lines only contains lowercase Latin letters. | In the first line, print number *x* — the minimum possible Hamming distance between strings *S* and *T* if you swap at most one pair of letters in *S*.
In the second line, either print the indexes *i* and *j* (1<=≤<=*i*,<=*j*<=≤<=*n*, *i*<=≠<=*j*), if reaching the minimum possible distance is possible by swapping letters on positions *i* and *j*, or print "-1 -1", if it is not necessary to swap characters.
If there are multiple possible answers, print any of them. | [
"9\npergament\npermanent\n",
"6\nwookie\ncookie\n",
"4\npetr\negor\n",
"6\ndouble\nbundle\n"
] | [
"1\n4 6\n",
"1\n-1 -1\n",
"2\n1 2\n",
"2\n4 1\n"
] | In the second test it is acceptable to print *i* = 2, *j* = 3. | 1,000 | [
{
"input": "9\npergament\npermanent",
"output": "1\n4 6"
},
{
"input": "6\nwookie\ncookie",
"output": "1\n-1 -1"
},
{
"input": "4\npetr\negor",
"output": "2\n1 2"
},
{
"input": "6\ndouble\nbundle",
"output": "2\n4 1"
},
{
"input": "1\na\na",
"output": "0\n-1 -1"
},
{
"input": "1\na\nb",
"output": "1\n-1 -1"
},
{
"input": "2\naa\naa",
"output": "0\n-1 -1"
},
{
"input": "2\nzz\nzz",
"output": "0\n-1 -1"
},
{
"input": "2\nzx\nzz",
"output": "1\n-1 -1"
},
{
"input": "2\nzz\nzx",
"output": "1\n-1 -1"
},
{
"input": "2\nxy\nzz",
"output": "2\n-1 -1"
},
{
"input": "2\nzz\nxy",
"output": "2\n-1 -1"
},
{
"input": "2\nzx\nxz",
"output": "0\n2 1"
},
{
"input": "2\nab\nbc",
"output": "1\n1 2"
},
{
"input": "2\nab\ncb",
"output": "1\n-1 -1"
},
{
"input": "2\nxx\nyy",
"output": "2\n-1 -1"
},
{
"input": "10\ncdcddbacdb\naababacabc",
"output": "8\n7 8"
},
{
"input": "2\nab\ncd",
"output": "2\n-1 -1"
},
{
"input": "2\naa\nab",
"output": "1\n-1 -1"
},
{
"input": "3\nabc\nbca",
"output": "2\n1 2"
},
{
"input": "3\nxyx\nyxy",
"output": "1\n3 2"
},
{
"input": "4\nabba\nbbaa",
"output": "0\n1 3"
},
{
"input": "4\nabba\nabca",
"output": "1\n-1 -1"
},
{
"input": "4\nabba\ncaba",
"output": "1\n2 1"
},
{
"input": "4\nyydd\ndxyz",
"output": "2\n3 1"
}
] | 1,433,566,266 | 2,147,483,647 | Python 3 | OK | TESTS | 57 | 187 | 1,126,400 | n = int(input())
s = input()
t = input()
diff = {}
dis = 0
for i in range(len(s)):
if s[i]!=t[i]:
dis += 1
diff[s[i]+t[i]] = i+1
for d in diff.keys():
if diff.get(d[::-1],0) > 0:
print(dis-2)
print(diff[d], diff[d[::-1]])
exit()
for d in diff.keys():
for dd in diff.keys():
if d[0]==dd[1] or d[1]==dd[0]:
print(dis-1)
print(diff[d], diff[dd])
exit()
print(dis)
print(-1, -1)
| Title: Error Correct System
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Ford Prefect got a job as a web developer for a small company that makes towels. His current work task is to create a search engine for the website of the company. During the development process, he needs to write a subroutine for comparing strings *S* and *T* of equal length to be "similar". After a brief search on the Internet, he learned about the Hamming distance between two strings *S* and *T* of the same length, which is defined as the number of positions in which *S* and *T* have different characters. For example, the Hamming distance between words "permanent" and "pergament" is two, as these words differ in the fourth and sixth letters.
Moreover, as he was searching for information, he also noticed that modern search engines have powerful mechanisms to correct errors in the request to improve the quality of search. Ford doesn't know much about human beings, so he assumed that the most common mistake in a request is swapping two arbitrary letters of the string (not necessarily adjacent). Now he wants to write a function that determines which two letters should be swapped in string *S*, so that the Hamming distance between a new string *S* and string *T* would be as small as possible, or otherwise, determine that such a replacement cannot reduce the distance between the strings.
Help him do this!
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=200<=000) — the length of strings *S* and *T*.
The second line contains string *S*.
The third line contains string *T*.
Each of the lines only contains lowercase Latin letters.
Output Specification:
In the first line, print number *x* — the minimum possible Hamming distance between strings *S* and *T* if you swap at most one pair of letters in *S*.
In the second line, either print the indexes *i* and *j* (1<=≤<=*i*,<=*j*<=≤<=*n*, *i*<=≠<=*j*), if reaching the minimum possible distance is possible by swapping letters on positions *i* and *j*, or print "-1 -1", if it is not necessary to swap characters.
If there are multiple possible answers, print any of them.
Demo Input:
['9\npergament\npermanent\n', '6\nwookie\ncookie\n', '4\npetr\negor\n', '6\ndouble\nbundle\n']
Demo Output:
['1\n4 6\n', '1\n-1 -1\n', '2\n1 2\n', '2\n4 1\n']
Note:
In the second test it is acceptable to print *i* = 2, *j* = 3. | ```python
n = int(input())
s = input()
t = input()
diff = {}
dis = 0
for i in range(len(s)):
if s[i]!=t[i]:
dis += 1
diff[s[i]+t[i]] = i+1
for d in diff.keys():
if diff.get(d[::-1],0) > 0:
print(dis-2)
print(diff[d], diff[d[::-1]])
exit()
for d in diff.keys():
for dd in diff.keys():
if d[0]==dd[1] or d[1]==dd[0]:
print(dis-1)
print(diff[d], diff[dd])
exit()
print(dis)
print(-1, -1)
``` | 3 | |
320 | A | Magic Numbers | PROGRAMMING | 900 | [
"brute force",
"greedy"
] | null | null | A magic number is a number formed by concatenation of numbers 1, 14 and 144. We can use each of these numbers any number of times. Therefore 14144, 141414 and 1411 are magic numbers but 1444, 514 and 414 are not.
You're given a number. Determine if it is a magic number or not. | The first line of input contains an integer *n*, (1<=≤<=*n*<=≤<=109). This number doesn't contain leading zeros. | Print "YES" if *n* is a magic number or print "NO" if it's not. | [
"114114\n",
"1111\n",
"441231\n"
] | [
"YES\n",
"YES\n",
"NO\n"
] | none | 500 | [
{
"input": "114114",
"output": "YES"
},
{
"input": "1111",
"output": "YES"
},
{
"input": "441231",
"output": "NO"
},
{
"input": "1",
"output": "YES"
},
{
"input": "14",
"output": "YES"
},
{
"input": "114",
"output": "YES"
},
{
"input": "9",
"output": "NO"
},
{
"input": "414",
"output": "NO"
},
{
"input": "1000000000",
"output": "NO"
},
{
"input": "144144144",
"output": "YES"
},
{
"input": "1444",
"output": "NO"
},
{
"input": "11",
"output": "YES"
},
{
"input": "141414141",
"output": "YES"
},
{
"input": "11110111",
"output": "NO"
},
{
"input": "114114144",
"output": "YES"
},
{
"input": "444",
"output": "NO"
},
{
"input": "9999",
"output": "NO"
},
{
"input": "111444",
"output": "NO"
},
{
"input": "11114",
"output": "YES"
},
{
"input": "41111",
"output": "NO"
},
{
"input": "114414441",
"output": "NO"
},
{
"input": "144414441",
"output": "NO"
},
{
"input": "144244144",
"output": "NO"
},
{
"input": "111111111",
"output": "YES"
},
{
"input": "144444444",
"output": "NO"
},
{
"input": "444444444",
"output": "NO"
},
{
"input": "141441441",
"output": "YES"
},
{
"input": "441",
"output": "NO"
},
{
"input": "15",
"output": "NO"
},
{
"input": "14444",
"output": "NO"
},
{
"input": "11444",
"output": "NO"
},
{
"input": "144",
"output": "YES"
},
{
"input": "1414414",
"output": "YES"
},
{
"input": "141444",
"output": "NO"
},
{
"input": "14144",
"output": "YES"
},
{
"input": "4",
"output": "NO"
},
{
"input": "1144",
"output": "YES"
},
{
"input": "141111444",
"output": "NO"
},
{
"input": "14414414",
"output": "YES"
},
{
"input": "141414144",
"output": "YES"
},
{
"input": "1414",
"output": "YES"
},
{
"input": "1441",
"output": "YES"
},
{
"input": "12",
"output": "NO"
},
{
"input": "144144141",
"output": "YES"
},
{
"input": "144144",
"output": "YES"
},
{
"input": "14414411",
"output": "YES"
},
{
"input": "14414",
"output": "YES"
}
] | 1,652,295,459 | 2,147,483,647 | Python 3 | OK | TESTS | 47 | 92 | 0 |
i=input()
j=0
flag=True
while j<len(i):
if j+2<len(i) and i[j]=='1' and i[j+1]=='4' and i[j+2]=='4' :
j+=3
elif j+1<len(i) and i[j]=='1' and i[j+1]=='4':
j+=2
elif i[j]=='1':
j+=1
else:
flag=False
break
if flag:
print('YES')
else:
print('NO')
| Title: Magic Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A magic number is a number formed by concatenation of numbers 1, 14 and 144. We can use each of these numbers any number of times. Therefore 14144, 141414 and 1411 are magic numbers but 1444, 514 and 414 are not.
You're given a number. Determine if it is a magic number or not.
Input Specification:
The first line of input contains an integer *n*, (1<=≤<=*n*<=≤<=109). This number doesn't contain leading zeros.
Output Specification:
Print "YES" if *n* is a magic number or print "NO" if it's not.
Demo Input:
['114114\n', '1111\n', '441231\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n']
Note:
none | ```python
i=input()
j=0
flag=True
while j<len(i):
if j+2<len(i) and i[j]=='1' and i[j+1]=='4' and i[j+2]=='4' :
j+=3
elif j+1<len(i) and i[j]=='1' and i[j+1]=='4':
j+=2
elif i[j]=='1':
j+=1
else:
flag=False
break
if flag:
print('YES')
else:
print('NO')
``` | 3 | |
6 | A | Triangle | PROGRAMMING | 900 | [
"brute force",
"geometry"
] | A. Triangle | 2 | 64 | Johnny has a younger sister Anne, who is very clever and smart. As she came home from the kindergarten, she told his brother about the task that her kindergartener asked her to solve. The task was just to construct a triangle out of four sticks of different colours. Naturally, one of the sticks is extra. It is not allowed to break the sticks or use their partial length. Anne has perfectly solved this task, now she is asking Johnny to do the same.
The boy answered that he would cope with it without any difficulty. However, after a while he found out that different tricky things can occur. It can happen that it is impossible to construct a triangle of a positive area, but it is possible to construct a degenerate triangle. It can be so, that it is impossible to construct a degenerate triangle even. As Johnny is very lazy, he does not want to consider such a big amount of cases, he asks you to help him. | The first line of the input contains four space-separated positive integer numbers not exceeding 100 — lengthes of the sticks. | Output TRIANGLE if it is possible to construct a non-degenerate triangle. Output SEGMENT if the first case cannot take place and it is possible to construct a degenerate triangle. Output IMPOSSIBLE if it is impossible to construct any triangle. Remember that you are to use three sticks. It is not allowed to break the sticks or use their partial length. | [
"4 2 1 3\n",
"7 2 2 4\n",
"3 5 9 1\n"
] | [
"TRIANGLE\n",
"SEGMENT\n",
"IMPOSSIBLE\n"
] | none | 0 | [
{
"input": "4 2 1 3",
"output": "TRIANGLE"
},
{
"input": "7 2 2 4",
"output": "SEGMENT"
},
{
"input": "3 5 9 1",
"output": "IMPOSSIBLE"
},
{
"input": "3 1 5 1",
"output": "IMPOSSIBLE"
},
{
"input": "10 10 10 10",
"output": "TRIANGLE"
},
{
"input": "11 5 6 11",
"output": "TRIANGLE"
},
{
"input": "1 1 1 1",
"output": "TRIANGLE"
},
{
"input": "10 20 30 40",
"output": "TRIANGLE"
},
{
"input": "45 25 5 15",
"output": "IMPOSSIBLE"
},
{
"input": "20 5 8 13",
"output": "TRIANGLE"
},
{
"input": "10 30 7 20",
"output": "SEGMENT"
},
{
"input": "3 2 3 2",
"output": "TRIANGLE"
},
{
"input": "70 10 100 30",
"output": "SEGMENT"
},
{
"input": "4 8 16 2",
"output": "IMPOSSIBLE"
},
{
"input": "3 3 3 10",
"output": "TRIANGLE"
},
{
"input": "1 5 5 5",
"output": "TRIANGLE"
},
{
"input": "13 25 12 1",
"output": "SEGMENT"
},
{
"input": "10 100 7 3",
"output": "SEGMENT"
},
{
"input": "50 1 50 100",
"output": "TRIANGLE"
},
{
"input": "50 1 100 49",
"output": "SEGMENT"
},
{
"input": "49 51 100 1",
"output": "SEGMENT"
},
{
"input": "5 11 2 25",
"output": "IMPOSSIBLE"
},
{
"input": "91 50 9 40",
"output": "IMPOSSIBLE"
},
{
"input": "27 53 7 97",
"output": "IMPOSSIBLE"
},
{
"input": "51 90 24 8",
"output": "IMPOSSIBLE"
},
{
"input": "3 5 1 1",
"output": "IMPOSSIBLE"
},
{
"input": "13 49 69 15",
"output": "IMPOSSIBLE"
},
{
"input": "16 99 9 35",
"output": "IMPOSSIBLE"
},
{
"input": "27 6 18 53",
"output": "IMPOSSIBLE"
},
{
"input": "57 88 17 8",
"output": "IMPOSSIBLE"
},
{
"input": "95 20 21 43",
"output": "IMPOSSIBLE"
},
{
"input": "6 19 32 61",
"output": "IMPOSSIBLE"
},
{
"input": "100 21 30 65",
"output": "IMPOSSIBLE"
},
{
"input": "85 16 61 9",
"output": "IMPOSSIBLE"
},
{
"input": "5 6 19 82",
"output": "IMPOSSIBLE"
},
{
"input": "1 5 1 3",
"output": "IMPOSSIBLE"
},
{
"input": "65 10 36 17",
"output": "IMPOSSIBLE"
},
{
"input": "81 64 9 7",
"output": "IMPOSSIBLE"
},
{
"input": "11 30 79 43",
"output": "IMPOSSIBLE"
},
{
"input": "1 1 5 3",
"output": "IMPOSSIBLE"
},
{
"input": "21 94 61 31",
"output": "IMPOSSIBLE"
},
{
"input": "49 24 9 74",
"output": "IMPOSSIBLE"
},
{
"input": "11 19 5 77",
"output": "IMPOSSIBLE"
},
{
"input": "52 10 19 71",
"output": "SEGMENT"
},
{
"input": "2 3 7 10",
"output": "SEGMENT"
},
{
"input": "1 2 6 3",
"output": "SEGMENT"
},
{
"input": "2 6 1 8",
"output": "SEGMENT"
},
{
"input": "1 2 4 1",
"output": "SEGMENT"
},
{
"input": "4 10 6 2",
"output": "SEGMENT"
},
{
"input": "2 10 7 3",
"output": "SEGMENT"
},
{
"input": "5 2 3 9",
"output": "SEGMENT"
},
{
"input": "6 1 4 10",
"output": "SEGMENT"
},
{
"input": "10 6 4 1",
"output": "SEGMENT"
},
{
"input": "3 2 9 1",
"output": "SEGMENT"
},
{
"input": "22 80 29 7",
"output": "SEGMENT"
},
{
"input": "2 6 3 9",
"output": "SEGMENT"
},
{
"input": "3 1 2 1",
"output": "SEGMENT"
},
{
"input": "3 4 7 1",
"output": "SEGMENT"
},
{
"input": "8 4 3 1",
"output": "SEGMENT"
},
{
"input": "2 8 3 5",
"output": "SEGMENT"
},
{
"input": "4 1 2 1",
"output": "SEGMENT"
},
{
"input": "8 1 3 2",
"output": "SEGMENT"
},
{
"input": "6 2 1 8",
"output": "SEGMENT"
},
{
"input": "3 3 3 6",
"output": "TRIANGLE"
},
{
"input": "3 6 3 3",
"output": "TRIANGLE"
},
{
"input": "4 10 4 4",
"output": "TRIANGLE"
},
{
"input": "1 1 2 1",
"output": "TRIANGLE"
},
{
"input": "3 3 3 6",
"output": "TRIANGLE"
},
{
"input": "5 4 5 5",
"output": "TRIANGLE"
},
{
"input": "8 7 8 8",
"output": "TRIANGLE"
},
{
"input": "3 3 3 1",
"output": "TRIANGLE"
},
{
"input": "1 1 6 6",
"output": "TRIANGLE"
},
{
"input": "1 9 1 9",
"output": "TRIANGLE"
},
{
"input": "7 2 2 7",
"output": "TRIANGLE"
},
{
"input": "7 2 3 2",
"output": "TRIANGLE"
},
{
"input": "4 4 10 10",
"output": "TRIANGLE"
},
{
"input": "7 7 10 7",
"output": "TRIANGLE"
},
{
"input": "4 4 4 5",
"output": "TRIANGLE"
},
{
"input": "1 10 9 2",
"output": "TRIANGLE"
},
{
"input": "1 8 2 7",
"output": "TRIANGLE"
},
{
"input": "4 3 2 8",
"output": "TRIANGLE"
},
{
"input": "5 9 5 3",
"output": "TRIANGLE"
},
{
"input": "4 10 3 5",
"output": "TRIANGLE"
}
] | 1,641,694,364 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 92 | 0 | sides = list(map(int,input().split()))
minelement = min(sides)
sides.remove(minelement)
min2element = min(sides)
sides.remove(min2element)
if minelement + min2element > min(sides) or min2element + min(sides) > max(sides):
print("TRIANGE")
elif min2element + minelement == min(sides) or min2element + min(sides) == max(sides):
print("SEGMENT ")
else:
print("IMPOSSIBLE") | Title: Triangle
Time Limit: 2 seconds
Memory Limit: 64 megabytes
Problem Description:
Johnny has a younger sister Anne, who is very clever and smart. As she came home from the kindergarten, she told his brother about the task that her kindergartener asked her to solve. The task was just to construct a triangle out of four sticks of different colours. Naturally, one of the sticks is extra. It is not allowed to break the sticks or use their partial length. Anne has perfectly solved this task, now she is asking Johnny to do the same.
The boy answered that he would cope with it without any difficulty. However, after a while he found out that different tricky things can occur. It can happen that it is impossible to construct a triangle of a positive area, but it is possible to construct a degenerate triangle. It can be so, that it is impossible to construct a degenerate triangle even. As Johnny is very lazy, he does not want to consider such a big amount of cases, he asks you to help him.
Input Specification:
The first line of the input contains four space-separated positive integer numbers not exceeding 100 — lengthes of the sticks.
Output Specification:
Output TRIANGLE if it is possible to construct a non-degenerate triangle. Output SEGMENT if the first case cannot take place and it is possible to construct a degenerate triangle. Output IMPOSSIBLE if it is impossible to construct any triangle. Remember that you are to use three sticks. It is not allowed to break the sticks or use their partial length.
Demo Input:
['4 2 1 3\n', '7 2 2 4\n', '3 5 9 1\n']
Demo Output:
['TRIANGLE\n', 'SEGMENT\n', 'IMPOSSIBLE\n']
Note:
none | ```python
sides = list(map(int,input().split()))
minelement = min(sides)
sides.remove(minelement)
min2element = min(sides)
sides.remove(min2element)
if minelement + min2element > min(sides) or min2element + min(sides) > max(sides):
print("TRIANGE")
elif min2element + minelement == min(sides) or min2element + min(sides) == max(sides):
print("SEGMENT ")
else:
print("IMPOSSIBLE")
``` | 0 |
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"
}
] | 1,689,173,907 | 2,147,483,647 | Python 3 | OK | TESTS | 25 | 46 | 0 | def Vany_and_Cubes(n):
i=1
sums = 0
while (sums < n):
sums += ( i*(i+1)/2)
if sums > n:
break
i+=1
return i-1
n = int(input())
print(Vany_and_Cubes(n)) | 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
def Vany_and_Cubes(n):
i=1
sums = 0
while (sums < n):
sums += ( i*(i+1)/2)
if sums > n:
break
i+=1
return i-1
n = int(input())
print(Vany_and_Cubes(n))
``` | 3 | |
497 | E | Subsequences Return | PROGRAMMING | 2,900 | [
"dp",
"matrices"
] | null | null | Assume that *s**k*(*n*) equals the sum of digits of number *n* in the *k*-based notation. For example, *s*2(5)<==<=*s*2(1012)<==<=1<=+<=0<=+<=1<==<=2, *s*3(14)<==<=*s*3(1123)<==<=1<=+<=1<=+<=2<==<=4.
The sequence of integers *a*0,<=...,<=*a**n*<=-<=1 is defined as . Your task is to calculate the number of distinct subsequences of sequence *a*0,<=...,<=*a**n*<=-<=1. Calculate the answer modulo 109<=+<=7.
Sequence *a*1,<=...,<=*a**k* is called to be a subsequence of sequence *b*1,<=...,<=*b**l*, if there is a sequence of indices 1<=≤<=*i*1<=<<=...<=<<=*i**k*<=≤<=*l*, such that *a*1<==<=*b**i*1, ..., *a**k*<==<=*b**i**k*. In particular, an empty sequence (i.e. the sequence consisting of zero elements) is a subsequence of any sequence. | The first line contains two space-separated numbers *n* and *k* (1<=≤<=*n*<=≤<=1018, 2<=≤<=*k*<=≤<=30). | In a single line print the answer to the problem modulo 109<=+<=7. | [
"4 2\n",
"7 7\n"
] | [
"11\n",
"128\n"
] | In the first sample the sequence *a*<sub class="lower-index">*i*</sub> looks as follows: (0, 1, 1, 0). All the possible subsequences are:
In the second sample the sequence *a*<sub class="lower-index">*i*</sub> looks as follows: (0, 1, 2, 3, 4, 5, 6). The subsequences of this sequence are exactly all increasing sequences formed from numbers from 0 to 6. It is easy to see that there are 2<sup class="upper-index">7</sup> = 128 such sequences. | 2,500 | [] | 1,689,637,814 | 2,147,483,647 | PyPy 3-64 | WRONG_ANSWER | TESTS | 0 | 30 | 0 | print("_RANDOM_GUESS_1689637814.4355159")# 1689637814.435537 | Title: Subsequences Return
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Assume that *s**k*(*n*) equals the sum of digits of number *n* in the *k*-based notation. For example, *s*2(5)<==<=*s*2(1012)<==<=1<=+<=0<=+<=1<==<=2, *s*3(14)<==<=*s*3(1123)<==<=1<=+<=1<=+<=2<==<=4.
The sequence of integers *a*0,<=...,<=*a**n*<=-<=1 is defined as . Your task is to calculate the number of distinct subsequences of sequence *a*0,<=...,<=*a**n*<=-<=1. Calculate the answer modulo 109<=+<=7.
Sequence *a*1,<=...,<=*a**k* is called to be a subsequence of sequence *b*1,<=...,<=*b**l*, if there is a sequence of indices 1<=≤<=*i*1<=<<=...<=<<=*i**k*<=≤<=*l*, such that *a*1<==<=*b**i*1, ..., *a**k*<==<=*b**i**k*. In particular, an empty sequence (i.e. the sequence consisting of zero elements) is a subsequence of any sequence.
Input Specification:
The first line contains two space-separated numbers *n* and *k* (1<=≤<=*n*<=≤<=1018, 2<=≤<=*k*<=≤<=30).
Output Specification:
In a single line print the answer to the problem modulo 109<=+<=7.
Demo Input:
['4 2\n', '7 7\n']
Demo Output:
['11\n', '128\n']
Note:
In the first sample the sequence *a*<sub class="lower-index">*i*</sub> looks as follows: (0, 1, 1, 0). All the possible subsequences are:
In the second sample the sequence *a*<sub class="lower-index">*i*</sub> looks as follows: (0, 1, 2, 3, 4, 5, 6). The subsequences of this sequence are exactly all increasing sequences formed from numbers from 0 to 6. It is easy to see that there are 2<sup class="upper-index">7</sup> = 128 such sequences. | ```python
print("_RANDOM_GUESS_1689637814.4355159")# 1689637814.435537
``` | 0 | |
160 | A | Twins | PROGRAMMING | 900 | [
"greedy",
"sortings"
] | null | null | Imagine that you have a twin brother or sister. Having another person that looks exactly like you seems very unusual. It's hard to say if having something of an alter ego is good or bad. And if you do have a twin, then you very well know what it's like.
Now let's imagine a typical morning in your family. You haven't woken up yet, and Mom is already going to work. She has been so hasty that she has nearly forgotten to leave the two of her darling children some money to buy lunches in the school cafeteria. She fished in the purse and found some number of coins, or to be exact, *n* coins of arbitrary values *a*1,<=*a*2,<=...,<=*a**n*. But as Mom was running out of time, she didn't split the coins for you two. So she scribbled a note asking you to split the money equally.
As you woke up, you found Mom's coins and read her note. "But why split the money equally?" — you thought. After all, your twin is sleeping and he won't know anything. So you decided to act like that: pick for yourself some subset of coins so that the sum of values of your coins is strictly larger than the sum of values of the remaining coins that your twin will have. However, you correctly thought that if you take too many coins, the twin will suspect the deception. So, you've decided to stick to the following strategy to avoid suspicions: you take the minimum number of coins, whose sum of values is strictly more than the sum of values of the remaining coins. On this basis, determine what minimum number of coins you need to take to divide them in the described manner. | The first line contains integer *n* (1<=≤<=*n*<=≤<=100) — the number of coins. The second line contains a sequence of *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=100) — the coins' values. All numbers are separated with spaces. | In the single line print the single number — the minimum needed number of coins. | [
"2\n3 3\n",
"3\n2 1 2\n"
] | [
"2\n",
"2\n"
] | In the first sample you will have to take 2 coins (you and your twin have sums equal to 6, 0 correspondingly). If you take 1 coin, you get sums 3, 3. If you take 0 coins, you get sums 0, 6. Those variants do not satisfy you as your sum should be strictly more that your twins' sum.
In the second sample one coin isn't enough for us, too. You can pick coins with values 1, 2 or 2, 2. In any case, the minimum number of coins equals 2. | 500 | [
{
"input": "2\n3 3",
"output": "2"
},
{
"input": "3\n2 1 2",
"output": "2"
},
{
"input": "1\n5",
"output": "1"
},
{
"input": "5\n4 2 2 2 2",
"output": "3"
},
{
"input": "7\n1 10 1 2 1 1 1",
"output": "1"
},
{
"input": "5\n3 2 3 3 1",
"output": "3"
},
{
"input": "2\n2 1",
"output": "1"
},
{
"input": "3\n2 1 3",
"output": "2"
},
{
"input": "6\n1 1 1 1 1 1",
"output": "4"
},
{
"input": "7\n10 10 5 5 5 5 1",
"output": "3"
},
{
"input": "20\n2 1 2 2 2 1 1 2 1 2 2 1 1 1 1 2 1 1 1 1",
"output": "8"
},
{
"input": "20\n4 2 4 4 3 4 2 2 4 2 3 1 1 2 2 3 3 3 1 4",
"output": "8"
},
{
"input": "20\n35 26 41 40 45 46 22 26 39 23 11 15 47 42 18 15 27 10 45 40",
"output": "8"
},
{
"input": "20\n7 84 100 10 31 35 41 2 63 44 57 4 63 11 23 49 98 71 16 90",
"output": "6"
},
{
"input": "50\n19 2 12 26 17 27 10 26 17 17 5 24 11 15 3 9 16 18 19 1 25 23 18 6 2 7 25 7 21 25 13 29 16 9 25 3 14 30 18 4 10 28 6 10 8 2 2 4 8 28",
"output": "14"
},
{
"input": "70\n2 18 18 47 25 5 14 9 19 46 36 49 33 32 38 23 32 39 8 29 31 17 24 21 10 15 33 37 46 21 22 11 20 35 39 13 11 30 28 40 39 47 1 17 24 24 21 46 12 2 20 43 8 16 44 11 45 10 13 44 31 45 45 46 11 10 33 35 23 42",
"output": "22"
},
{
"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": "51"
},
{
"input": "100\n1 2 2 1 2 1 1 2 1 1 1 2 2 1 1 1 2 2 2 1 2 1 1 1 1 1 2 1 2 1 2 1 2 1 2 1 1 1 2 1 1 1 1 1 2 2 1 2 1 2 1 2 2 2 1 2 1 2 2 1 1 2 2 1 1 2 2 2 1 1 2 1 1 2 2 1 2 1 1 2 2 1 2 1 1 2 2 1 1 1 1 2 1 1 1 1 2 2 2 2",
"output": "37"
},
{
"input": "100\n1 2 3 2 1 2 2 3 1 3 3 2 2 1 1 2 2 1 1 1 1 2 3 3 2 1 1 2 2 2 3 3 3 2 1 3 1 3 3 2 3 1 2 2 2 3 2 1 1 3 3 3 3 2 1 1 2 3 2 2 3 2 3 2 2 3 2 2 2 2 3 3 3 1 3 3 1 1 2 3 2 2 2 2 3 3 3 2 1 2 3 1 1 2 3 3 1 3 3 2",
"output": "36"
},
{
"input": "100\n5 5 4 3 5 1 2 5 1 1 3 5 4 4 1 1 1 1 5 4 4 5 1 5 5 1 2 1 3 1 5 1 3 3 3 2 2 2 1 1 5 1 3 4 1 1 3 2 5 2 2 5 5 4 4 1 3 4 3 3 4 5 3 3 3 1 2 1 4 2 4 4 1 5 1 3 5 5 5 5 3 4 4 3 1 2 5 2 3 5 4 2 4 5 3 2 4 2 4 3",
"output": "33"
},
{
"input": "100\n3 4 8 10 8 6 4 3 7 7 6 2 3 1 3 10 1 7 9 3 5 5 2 6 2 9 1 7 4 2 4 1 6 1 7 10 2 5 3 7 6 4 6 2 8 8 8 6 6 10 3 7 4 3 4 1 7 9 3 6 3 6 1 4 9 3 8 1 10 1 4 10 7 7 9 5 3 8 10 2 1 10 8 7 10 8 5 3 1 2 1 10 6 1 5 3 3 5 7 2",
"output": "30"
},
{
"input": "100\n16 9 11 8 11 4 9 17 4 8 4 10 9 10 6 3 3 15 1 6 1 15 12 18 6 14 13 18 1 7 18 4 10 7 10 12 3 16 14 4 10 8 10 7 19 13 15 1 4 8 16 10 6 4 3 16 11 10 7 3 4 16 1 20 1 11 4 16 10 7 7 12 18 19 3 17 19 3 4 19 2 12 11 3 18 20 2 2 14 4 20 13 13 11 16 20 19 14 7 2",
"output": "29"
},
{
"input": "100\n2 46 4 6 38 19 15 34 10 35 37 30 3 25 5 45 40 45 33 31 6 20 10 44 11 9 2 14 35 5 9 23 20 2 48 22 25 35 38 31 24 33 35 16 4 30 27 10 12 22 6 24 12 30 23 21 14 12 32 21 7 12 25 43 18 34 34 28 47 13 28 43 18 39 44 42 35 26 35 14 8 29 32 20 29 3 20 6 20 9 9 27 8 42 10 37 42 27 8 1",
"output": "30"
},
{
"input": "100\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": "29"
},
{
"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": "30"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "4\n4 1 2 3",
"output": "2"
},
{
"input": "5\n2 2 2 4 4",
"output": "2"
},
{
"input": "4\n100 99 99 100",
"output": "2"
}
] | 1,692,696,431 | 2,147,483,647 | PyPy 3-64 | OK | TESTS | 29 | 154 | 1,638,400 | def summer(array, index):
a = 0
b = 0
j = 0
while j < index:
a = a + array[j]
j = j + 1
while j < len(array):
b = b + array[j]
j = j + 1
if b > a:
return True
else:
return False
n = int(input())
li = input().split()
i = 0
while i < n:
li[i] = int(li[i])
i = i + 1
li.sort()
i = n
while i > 0:
i = i - 1
if summer(li, i) == True:
print(n - i)
quit()
| Title: Twins
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Imagine that you have a twin brother or sister. Having another person that looks exactly like you seems very unusual. It's hard to say if having something of an alter ego is good or bad. And if you do have a twin, then you very well know what it's like.
Now let's imagine a typical morning in your family. You haven't woken up yet, and Mom is already going to work. She has been so hasty that she has nearly forgotten to leave the two of her darling children some money to buy lunches in the school cafeteria. She fished in the purse and found some number of coins, or to be exact, *n* coins of arbitrary values *a*1,<=*a*2,<=...,<=*a**n*. But as Mom was running out of time, she didn't split the coins for you two. So she scribbled a note asking you to split the money equally.
As you woke up, you found Mom's coins and read her note. "But why split the money equally?" — you thought. After all, your twin is sleeping and he won't know anything. So you decided to act like that: pick for yourself some subset of coins so that the sum of values of your coins is strictly larger than the sum of values of the remaining coins that your twin will have. However, you correctly thought that if you take too many coins, the twin will suspect the deception. So, you've decided to stick to the following strategy to avoid suspicions: you take the minimum number of coins, whose sum of values is strictly more than the sum of values of the remaining coins. On this basis, determine what minimum number of coins you need to take to divide them in the described manner.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=100) — the number of coins. The second line contains a sequence of *n* integers *a*1, *a*2, ..., *a**n* (1<=≤<=*a**i*<=≤<=100) — the coins' values. All numbers are separated with spaces.
Output Specification:
In the single line print the single number — the minimum needed number of coins.
Demo Input:
['2\n3 3\n', '3\n2 1 2\n']
Demo Output:
['2\n', '2\n']
Note:
In the first sample you will have to take 2 coins (you and your twin have sums equal to 6, 0 correspondingly). If you take 1 coin, you get sums 3, 3. If you take 0 coins, you get sums 0, 6. Those variants do not satisfy you as your sum should be strictly more that your twins' sum.
In the second sample one coin isn't enough for us, too. You can pick coins with values 1, 2 or 2, 2. In any case, the minimum number of coins equals 2. | ```python
def summer(array, index):
a = 0
b = 0
j = 0
while j < index:
a = a + array[j]
j = j + 1
while j < len(array):
b = b + array[j]
j = j + 1
if b > a:
return True
else:
return False
n = int(input())
li = input().split()
i = 0
while i < n:
li[i] = int(li[i])
i = i + 1
li.sort()
i = n
while i > 0:
i = i - 1
if summer(li, i) == True:
print(n - i)
quit()
``` | 3 | |
475 | D | CGCDSSQ | PROGRAMMING | 2,000 | [
"brute force",
"data structures",
"math"
] | null | null | Given a sequence of integers *a*1,<=...,<=*a**n* and *q* queries *x*1,<=...,<=*x**q* on it. For each query *x**i* you have to count the number of pairs (*l*,<=*r*) such that 1<=≤<=*l*<=≤<=*r*<=≤<=*n* and *gcd*(*a**l*,<=*a**l*<=+<=1,<=...,<=*a**r*)<==<=*x**i*.
is a greatest common divisor of *v*1,<=*v*2,<=...,<=*v**n*, that is equal to a largest positive integer that divides all *v**i*. | The first line of the input contains integer *n*, (1<=≤<=*n*<=≤<=105), denoting the length of the sequence. The next line contains *n* space separated integers *a*1,<=...,<=*a**n*, (1<=≤<=*a**i*<=≤<=109).
The third line of the input contains integer *q*, (1<=≤<=*q*<=≤<=3<=×<=105), denoting the number of queries. Then follows *q* lines, each contain an integer *x**i*, (1<=≤<=*x**i*<=≤<=109). | For each query print the result in a separate line. | [
"3\n2 6 3\n5\n1\n2\n3\n4\n6\n",
"7\n10 20 3 15 1000 60 16\n10\n1\n2\n3\n4\n5\n6\n10\n20\n60\n1000\n"
] | [
"1\n2\n2\n0\n1\n",
"14\n0\n2\n2\n2\n0\n2\n2\n1\n1\n"
] | none | 2,000 | [
{
"input": "3\n2 6 3\n5\n1\n2\n3\n4\n6",
"output": "1\n2\n2\n0\n1"
},
{
"input": "7\n10 20 3 15 1000 60 16\n10\n1\n2\n3\n4\n5\n6\n10\n20\n60\n1000",
"output": "14\n0\n2\n2\n2\n0\n2\n2\n1\n1"
},
{
"input": "10\n2 2 4 3 2 4 4 2 4 2\n104\n3\n3\n1\n4\n1\n1\n4\n1\n1\n3\n1\n1\n4\n1\n1\n1\n4\n3\n1\n1\n4\n1\n1\n1\n1\n1\n4\n1\n1\n1\n4\n1\n1\n4\n1\n1\n1\n1\n1\n4\n4\n1\n3\n1\n4\n1\n1\n1\n4\n1\n2\n4\n1\n4\n1\n4\n1\n4\n3\n1\n2\n2\n4\n2\n1\n1\n2\n4\n4\n1\n2\n3\n1\n1\n4\n4\n4\n4\n4\n2\n2\n4\n1\n1\n1\n1\n4\n2\n1\n1\n4\n1\n4\n3\n4\n4\n1\n2\n3\n1\n2\n1\n3\n1",
"output": "1\n1\n27\n5\n27\n27\n5\n27\n27\n1\n27\n27\n5\n27\n27\n27\n5\n1\n27\n27\n5\n27\n27\n27\n27\n27\n5\n27\n27\n27\n5\n27\n27\n5\n27\n27\n27\n27\n27\n5\n5\n27\n1\n27\n5\n27\n27\n27\n5\n27\n22\n5\n27\n5\n27\n5\n27\n5\n1\n27\n22\n22\n5\n22\n27\n27\n22\n5\n5\n27\n22\n1\n27\n27\n5\n5\n5\n5\n5\n22\n22\n5\n27\n27\n27\n27\n5\n22\n27\n27\n5\n27\n5\n1\n5\n5\n27\n22\n1\n27\n22\n27\n1\n27"
}
] | 1,601,620,010 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 8 | 2,000 | 238,182,400 | from math import gcd
N = int(input())
a = list(map(int, input().split()))
Q = int(input())
dic = {}
for i in range(N):
curGcd = a[i]
for j in range(i, N):
curGcd = gcd(curGcd, a[j])
if curGcd in dic:
dic[curGcd].append((i, j))
else:
dic[curGcd] = [(i, j)]
for q in range(Q):
x = int(input())
if x in dic:
print(len(dic[x]))
else:
print(0)
| Title: CGCDSSQ
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Given a sequence of integers *a*1,<=...,<=*a**n* and *q* queries *x*1,<=...,<=*x**q* on it. For each query *x**i* you have to count the number of pairs (*l*,<=*r*) such that 1<=≤<=*l*<=≤<=*r*<=≤<=*n* and *gcd*(*a**l*,<=*a**l*<=+<=1,<=...,<=*a**r*)<==<=*x**i*.
is a greatest common divisor of *v*1,<=*v*2,<=...,<=*v**n*, that is equal to a largest positive integer that divides all *v**i*.
Input Specification:
The first line of the input contains integer *n*, (1<=≤<=*n*<=≤<=105), denoting the length of the sequence. The next line contains *n* space separated integers *a*1,<=...,<=*a**n*, (1<=≤<=*a**i*<=≤<=109).
The third line of the input contains integer *q*, (1<=≤<=*q*<=≤<=3<=×<=105), denoting the number of queries. Then follows *q* lines, each contain an integer *x**i*, (1<=≤<=*x**i*<=≤<=109).
Output Specification:
For each query print the result in a separate line.
Demo Input:
['3\n2 6 3\n5\n1\n2\n3\n4\n6\n', '7\n10 20 3 15 1000 60 16\n10\n1\n2\n3\n4\n5\n6\n10\n20\n60\n1000\n']
Demo Output:
['1\n2\n2\n0\n1\n', '14\n0\n2\n2\n2\n0\n2\n2\n1\n1\n']
Note:
none | ```python
from math import gcd
N = int(input())
a = list(map(int, input().split()))
Q = int(input())
dic = {}
for i in range(N):
curGcd = a[i]
for j in range(i, N):
curGcd = gcd(curGcd, a[j])
if curGcd in dic:
dic[curGcd].append((i, j))
else:
dic[curGcd] = [(i, j)]
for q in range(Q):
x = int(input())
if x in dic:
print(len(dic[x]))
else:
print(0)
``` | 0 | |
678 | A | Johny Likes Numbers | PROGRAMMING | 800 | [
"implementation",
"math"
] | null | null | Johny likes numbers *n* and *k* very much. Now Johny wants to find the smallest integer *x* greater than *n*, so it is divisible by the number *k*. | The only line contains two integers *n* and *k* (1<=≤<=*n*,<=*k*<=≤<=109). | Print the smallest integer *x*<=><=*n*, so it is divisible by the number *k*. | [
"5 3\n",
"25 13\n",
"26 13\n"
] | [
"6\n",
"26\n",
"39\n"
] | none | 0 | [
{
"input": "5 3",
"output": "6"
},
{
"input": "25 13",
"output": "26"
},
{
"input": "26 13",
"output": "39"
},
{
"input": "1 1",
"output": "2"
},
{
"input": "8 8",
"output": "16"
},
{
"input": "14 15",
"output": "15"
},
{
"input": "197 894",
"output": "894"
},
{
"input": "6058 8581",
"output": "8581"
},
{
"input": "97259 41764",
"output": "125292"
},
{
"input": "453145 333625",
"output": "667250"
},
{
"input": "2233224 4394826",
"output": "4394826"
},
{
"input": "76770926 13350712",
"output": "80104272"
},
{
"input": "687355301 142098087",
"output": "710490435"
},
{
"input": "1000000000 999999999",
"output": "1999999998"
},
{
"input": "1000000000 1000000000",
"output": "2000000000"
},
{
"input": "999999999 1000000000",
"output": "1000000000"
},
{
"input": "1000000000 1",
"output": "1000000001"
},
{
"input": "1000000000 2",
"output": "1000000002"
},
{
"input": "999999999 1",
"output": "1000000000"
},
{
"input": "100000000 1",
"output": "100000001"
},
{
"input": "999999999 500000000",
"output": "1000000000"
},
{
"input": "999999990 10",
"output": "1000000000"
},
{
"input": "1000000000 999999997",
"output": "1999999994"
},
{
"input": "999999999 2",
"output": "1000000000"
},
{
"input": "999999984 1",
"output": "999999985"
},
{
"input": "999999983 1",
"output": "999999984"
},
{
"input": "666666666 1",
"output": "666666667"
},
{
"input": "1000000000 990000000",
"output": "1980000000"
},
{
"input": "41 48",
"output": "48"
},
{
"input": "123456 2",
"output": "123458"
},
{
"input": "111 111",
"output": "222"
},
{
"input": "878787 1",
"output": "878788"
},
{
"input": "121 1",
"output": "122"
},
{
"input": "114514 114514",
"output": "229028"
},
{
"input": "500000001 1000000000",
"output": "1000000000"
},
{
"input": "999999997 1",
"output": "999999998"
},
{
"input": "100000000 10",
"output": "100000010"
}
] | 1,658,139,014 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 17 | 500 | 0 | n=input()
n=n.split()
a=int(n[0])
b=int(n[1])
i=1
if b==1:
print(a+1)
else:
while True:
x=b*i
if x>a:
print(x)
break
else:
i+=1 | Title: Johny Likes Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Johny likes numbers *n* and *k* very much. Now Johny wants to find the smallest integer *x* greater than *n*, so it is divisible by the number *k*.
Input Specification:
The only line contains two integers *n* and *k* (1<=≤<=*n*,<=*k*<=≤<=109).
Output Specification:
Print the smallest integer *x*<=><=*n*, so it is divisible by the number *k*.
Demo Input:
['5 3\n', '25 13\n', '26 13\n']
Demo Output:
['6\n', '26\n', '39\n']
Note:
none | ```python
n=input()
n=n.split()
a=int(n[0])
b=int(n[1])
i=1
if b==1:
print(a+1)
else:
while True:
x=b*i
if x>a:
print(x)
break
else:
i+=1
``` | 0 | |
151 | A | Soft Drinking | PROGRAMMING | 800 | [
"implementation",
"math"
] | null | null | This winter is so cold in Nvodsk! A group of *n* friends decided to buy *k* bottles of a soft drink called "Take-It-Light" to warm up a bit. Each bottle has *l* milliliters of the drink. Also they bought *c* limes and cut each of them into *d* slices. After that they found *p* grams of salt.
To make a toast, each friend needs *nl* milliliters of the drink, a slice of lime and *np* grams of salt. The friends want to make as many toasts as they can, provided they all drink the same amount. How many toasts can each friend make? | The first and only line contains positive integers *n*, *k*, *l*, *c*, *d*, *p*, *nl*, *np*, not exceeding 1000 and no less than 1. The numbers are separated by exactly one space. | Print a single integer — the number of toasts each friend can make. | [
"3 4 5 10 8 100 3 1\n",
"5 100 10 1 19 90 4 3\n",
"10 1000 1000 25 23 1 50 1\n"
] | [
"2\n",
"3\n",
"0\n"
] | A comment to the first sample:
Overall the friends have 4 * 5 = 20 milliliters of the drink, it is enough to make 20 / 3 = 6 toasts. The limes are enough for 10 * 8 = 80 toasts and the salt is enough for 100 / 1 = 100 toasts. However, there are 3 friends in the group, so the answer is *min*(6, 80, 100) / 3 = 2. | 500 | [
{
"input": "3 4 5 10 8 100 3 1",
"output": "2"
},
{
"input": "5 100 10 1 19 90 4 3",
"output": "3"
},
{
"input": "10 1000 1000 25 23 1 50 1",
"output": "0"
},
{
"input": "1 7 4 5 5 8 3 2",
"output": "4"
},
{
"input": "2 3 3 5 5 10 1 3",
"output": "1"
},
{
"input": "2 6 4 5 6 5 1 3",
"output": "0"
},
{
"input": "1 7 3 5 3 6 2 1",
"output": "6"
},
{
"input": "2 4 5 4 5 7 3 2",
"output": "1"
},
{
"input": "2 3 6 5 7 8 2 1",
"output": "4"
},
{
"input": "1 4 5 5 3 10 3 1",
"output": "6"
},
{
"input": "1 4 6 7 3 5 1 3",
"output": "1"
},
{
"input": "1 6 5 5 5 8 3 1",
"output": "8"
},
{
"input": "1 7 5 3 3 9 2 1",
"output": "9"
},
{
"input": "3 5 3 7 6 10 3 1",
"output": "1"
},
{
"input": "3 6 3 5 3 6 3 1",
"output": "2"
},
{
"input": "1 7 5 5 5 5 2 2",
"output": "2"
},
{
"input": "2 5 3 5 6 9 2 1",
"output": "3"
},
{
"input": "3 4 3 5 3 6 2 1",
"output": "2"
},
{
"input": "1 5 5 4 7 6 3 1",
"output": "6"
},
{
"input": "2 3 7 6 5 9 3 1",
"output": "3"
},
{
"input": "2 6 5 3 3 8 1 1",
"output": "4"
},
{
"input": "2 4 7 3 4 10 2 1",
"output": "5"
},
{
"input": "1 1000 1000 1000 1000 1000 1 1",
"output": "1000"
},
{
"input": "17 1000 1000 1000 1000 1000 3 7",
"output": "8"
},
{
"input": "115 1000 1000 1000 1000 1000 17 15",
"output": "0"
},
{
"input": "1 587 981 1 2 1 1 1",
"output": "1"
},
{
"input": "1 1 2 1 2 2 1 1",
"output": "2"
}
] | 1,686,529,171 | 2,147,483,647 | Python 3 | OK | TESTS | 27 | 92 | 0 | l = list(map(int, input().split()))
drink = l[1]*l[2]
lime = l[3]*l[4]
salt = l[5]
min_drink = drink//l[6]
min_salt = salt//l[7]
toast = min(lime, min_drink, min_salt)
print(toast//l[0]) | Title: Soft Drinking
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
This winter is so cold in Nvodsk! A group of *n* friends decided to buy *k* bottles of a soft drink called "Take-It-Light" to warm up a bit. Each bottle has *l* milliliters of the drink. Also they bought *c* limes and cut each of them into *d* slices. After that they found *p* grams of salt.
To make a toast, each friend needs *nl* milliliters of the drink, a slice of lime and *np* grams of salt. The friends want to make as many toasts as they can, provided they all drink the same amount. How many toasts can each friend make?
Input Specification:
The first and only line contains positive integers *n*, *k*, *l*, *c*, *d*, *p*, *nl*, *np*, not exceeding 1000 and no less than 1. The numbers are separated by exactly one space.
Output Specification:
Print a single integer — the number of toasts each friend can make.
Demo Input:
['3 4 5 10 8 100 3 1\n', '5 100 10 1 19 90 4 3\n', '10 1000 1000 25 23 1 50 1\n']
Demo Output:
['2\n', '3\n', '0\n']
Note:
A comment to the first sample:
Overall the friends have 4 * 5 = 20 milliliters of the drink, it is enough to make 20 / 3 = 6 toasts. The limes are enough for 10 * 8 = 80 toasts and the salt is enough for 100 / 1 = 100 toasts. However, there are 3 friends in the group, so the answer is *min*(6, 80, 100) / 3 = 2. | ```python
l = list(map(int, input().split()))
drink = l[1]*l[2]
lime = l[3]*l[4]
salt = l[5]
min_drink = drink//l[6]
min_salt = salt//l[7]
toast = min(lime, min_drink, min_salt)
print(toast//l[0])
``` | 3 | |
964 | A | Splits | PROGRAMMING | 800 | [
"math"
] | null | null | Let's define a split of $n$ as a nonincreasing sequence of positive integers, the sum of which is $n$.
For example, the following sequences are splits of $8$: $[4, 4]$, $[3, 3, 2]$, $[2, 2, 1, 1, 1, 1]$, $[5, 2, 1]$.
The following sequences aren't splits of $8$: $[1, 7]$, $[5, 4]$, $[11, -3]$, $[1, 1, 4, 1, 1]$.
The weight of a split is the number of elements in the split that are equal to the first element. For example, the weight of the split $[1, 1, 1, 1, 1]$ is $5$, the weight of the split $[5, 5, 3, 3, 3]$ is $2$ and the weight of the split $[9]$ equals $1$.
For a given $n$, find out the number of different weights of its splits. | The first line contains one integer $n$ ($1 \leq n \leq 10^9$). | Output one integer — the answer to the problem. | [
"7\n",
"8\n",
"9\n"
] | [
"4\n",
"5\n",
"5\n"
] | In the first sample, there are following possible weights of splits of $7$:
Weight 1: [$\textbf 7$]
Weight 2: [$\textbf 3$, $\textbf 3$, 1]
Weight 3: [$\textbf 2$, $\textbf 2$, $\textbf 2$, 1]
Weight 7: [$\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$] | 500 | [
{
"input": "7",
"output": "4"
},
{
"input": "8",
"output": "5"
},
{
"input": "9",
"output": "5"
},
{
"input": "1",
"output": "1"
},
{
"input": "286",
"output": "144"
},
{
"input": "48",
"output": "25"
},
{
"input": "941",
"output": "471"
},
{
"input": "45154",
"output": "22578"
},
{
"input": "60324",
"output": "30163"
},
{
"input": "91840",
"output": "45921"
},
{
"input": "41909",
"output": "20955"
},
{
"input": "58288",
"output": "29145"
},
{
"input": "91641",
"output": "45821"
},
{
"input": "62258",
"output": "31130"
},
{
"input": "79811",
"output": "39906"
},
{
"input": "88740",
"output": "44371"
},
{
"input": "12351",
"output": "6176"
},
{
"input": "1960",
"output": "981"
},
{
"input": "29239",
"output": "14620"
},
{
"input": "85801",
"output": "42901"
},
{
"input": "43255",
"output": "21628"
},
{
"input": "13439",
"output": "6720"
},
{
"input": "35668",
"output": "17835"
},
{
"input": "19122",
"output": "9562"
},
{
"input": "60169",
"output": "30085"
},
{
"input": "50588",
"output": "25295"
},
{
"input": "2467",
"output": "1234"
},
{
"input": "39315",
"output": "19658"
},
{
"input": "29950",
"output": "14976"
},
{
"input": "17286",
"output": "8644"
},
{
"input": "7359066",
"output": "3679534"
},
{
"input": "1016391",
"output": "508196"
},
{
"input": "7928871",
"output": "3964436"
},
{
"input": "3968891",
"output": "1984446"
},
{
"input": "2636452",
"output": "1318227"
},
{
"input": "5076901",
"output": "2538451"
},
{
"input": "9870265",
"output": "4935133"
},
{
"input": "2453786",
"output": "1226894"
},
{
"input": "7263670",
"output": "3631836"
},
{
"input": "1890845",
"output": "945423"
},
{
"input": "574128507",
"output": "287064254"
},
{
"input": "648476655",
"output": "324238328"
},
{
"input": "97349542",
"output": "48674772"
},
{
"input": "716489761",
"output": "358244881"
},
{
"input": "858771038",
"output": "429385520"
},
{
"input": "520778784",
"output": "260389393"
},
{
"input": "439004204",
"output": "219502103"
},
{
"input": "589992198",
"output": "294996100"
},
{
"input": "371106544",
"output": "185553273"
},
{
"input": "894241590",
"output": "447120796"
},
{
"input": "123957268",
"output": "61978635"
},
{
"input": "234149297",
"output": "117074649"
},
{
"input": "789954052",
"output": "394977027"
},
{
"input": "667978920",
"output": "333989461"
},
{
"input": "154647261",
"output": "77323631"
},
{
"input": "751453521",
"output": "375726761"
},
{
"input": "848862308",
"output": "424431155"
},
{
"input": "323926781",
"output": "161963391"
},
{
"input": "576768825",
"output": "288384413"
},
{
"input": "31293802",
"output": "15646902"
},
{
"input": "2",
"output": "2"
},
{
"input": "1000000000",
"output": "500000001"
},
{
"input": "3",
"output": "2"
}
] | 1,609,163,422 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 30 | 1,000 | 0 | num=int(input())
k=num//2
l=num-k
total=0
while(k>0 and l<num):
if k+l==num:
k=k-1
l=l+1
total=total+1
print(total+1) | Title: Splits
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Let's define a split of $n$ as a nonincreasing sequence of positive integers, the sum of which is $n$.
For example, the following sequences are splits of $8$: $[4, 4]$, $[3, 3, 2]$, $[2, 2, 1, 1, 1, 1]$, $[5, 2, 1]$.
The following sequences aren't splits of $8$: $[1, 7]$, $[5, 4]$, $[11, -3]$, $[1, 1, 4, 1, 1]$.
The weight of a split is the number of elements in the split that are equal to the first element. For example, the weight of the split $[1, 1, 1, 1, 1]$ is $5$, the weight of the split $[5, 5, 3, 3, 3]$ is $2$ and the weight of the split $[9]$ equals $1$.
For a given $n$, find out the number of different weights of its splits.
Input Specification:
The first line contains one integer $n$ ($1 \leq n \leq 10^9$).
Output Specification:
Output one integer — the answer to the problem.
Demo Input:
['7\n', '8\n', '9\n']
Demo Output:
['4\n', '5\n', '5\n']
Note:
In the first sample, there are following possible weights of splits of $7$:
Weight 1: [$\textbf 7$]
Weight 2: [$\textbf 3$, $\textbf 3$, 1]
Weight 3: [$\textbf 2$, $\textbf 2$, $\textbf 2$, 1]
Weight 7: [$\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$, $\textbf 1$] | ```python
num=int(input())
k=num//2
l=num-k
total=0
while(k>0 and l<num):
if k+l==num:
k=k-1
l=l+1
total=total+1
print(total+1)
``` | 0 | |
16 | A | Flag | PROGRAMMING | 800 | [
"implementation"
] | A. Flag | 2 | 64 | According to a new ISO standard, a flag of every country should have a chequered field *n*<=×<=*m*, each square should be of one of 10 colours, and the flag should be «striped»: each horizontal row of the flag should contain squares of the same colour, and the colours of adjacent horizontal rows should be different. Berland's government asked you to find out whether their flag meets the new ISO standard. | The first line of the input contains numbers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), *n* — the amount of rows, *m* — the amount of columns on the flag of Berland. Then there follows the description of the flag: each of the following *n* lines contain *m* characters. Each character is a digit between 0 and 9, and stands for the colour of the corresponding square. | Output YES, if the flag meets the new ISO standard, and NO otherwise. | [
"3 3\n000\n111\n222\n",
"3 3\n000\n000\n111\n",
"3 3\n000\n111\n002\n"
] | [
"YES\n",
"NO\n",
"NO\n"
] | none | 0 | [
{
"input": "3 3\n000\n111\n222",
"output": "YES"
},
{
"input": "3 3\n000\n000\n111",
"output": "NO"
},
{
"input": "3 3\n000\n111\n002",
"output": "NO"
},
{
"input": "10 10\n2222222222\n5555555555\n0000000000\n4444444444\n1111111111\n3333333393\n3333333333\n5555555555\n0000000000\n8888888888",
"output": "NO"
},
{
"input": "10 13\n4442444444444\n8888888888888\n6666666666666\n0000000000000\n3333333333333\n4444444444444\n7777777777777\n8388888888888\n1111111111111\n5555555555555",
"output": "NO"
},
{
"input": "10 8\n33333333\n44444444\n11111115\n81888888\n44444444\n11111111\n66666666\n33330333\n33333333\n33333333",
"output": "NO"
},
{
"input": "5 5\n88888\n44444\n66666\n55555\n88888",
"output": "YES"
},
{
"input": "20 19\n1111111111111111111\n5555555555555555555\n0000000000000000000\n3333333333333333333\n1111111111111111111\n2222222222222222222\n4444444444444444444\n5555555555555555555\n0000000000000000000\n4444444444444444444\n0000000000000000000\n5555555555555555555\n7777777777777777777\n9999999999999999999\n2222222222222222222\n4444444444444444444\n1111111111111111111\n6666666666666666666\n7777777777777777777\n2222222222222222222",
"output": "YES"
},
{
"input": "1 100\n8888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888888",
"output": "YES"
},
{
"input": "100 1\n5\n7\n9\n4\n7\n2\n5\n1\n6\n7\n2\n7\n6\n8\n7\n4\n0\n2\n9\n8\n9\n1\n6\n4\n3\n4\n7\n1\n9\n3\n0\n8\n3\n1\n7\n5\n3\n9\n5\n1\n3\n5\n8\n1\n9\n3\n9\n0\n6\n0\n7\n6\n5\n2\n8\n3\n7\n6\n5\n1\n8\n3\n6\n9\n6\n0\n5\n8\n5\n2\n9\n1\n0\n1\n8\n3\n2\n1\n0\n3\n9\n0\n5\n1\n0\n4\n9\n3\n0\n4\n8\n4\n8\n6\n3\n0\n4\n6\n8\n4",
"output": "YES"
},
{
"input": "1 1\n2",
"output": "YES"
},
{
"input": "1 100\n1111111111111111111111111111111111111111111111111111111111111111111111111111181111111111111111111111",
"output": "NO"
},
{
"input": "100 1\n3\n6\n4\n3\n0\n2\n8\n7\n3\n2\n1\n7\n1\n3\n2\n3\n6\n9\n0\n8\n5\n9\n7\n9\n2\n1\n4\n5\n1\n9\n2\n5\n1\n4\n6\n4\n9\n1\n0\n2\n1\n4\n7\n1\n4\n8\n0\n9\n2\n1\n6\n2\n8\n6\n9\n5\n8\n6\n4\n5\n9\n2\n7\n4\n1\n5\n8\n0\n9\n5\n4\n6\n5\n0\n6\n3\n6\n9\n7\n2\n0\n9\n7\n3\n2\n4\n9\n4\n7\n1\n2\n3\n1\n7\n9\n1\n9\n0\n4\n0",
"output": "YES"
}
] | 1,668,087,192 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 1 | 62 | 0 | a = input().split(" ")
n, m = int(a[0]), int(a[1])
for i in range(n):
line = input()
past = ""
if(len(set(line)) == 1 and line[0] != past):
past = line[0]
else:
print("NO")
exit()
print("YES")
| Title: Flag
Time Limit: 2 seconds
Memory Limit: 64 megabytes
Problem Description:
According to a new ISO standard, a flag of every country should have a chequered field *n*<=×<=*m*, each square should be of one of 10 colours, and the flag should be «striped»: each horizontal row of the flag should contain squares of the same colour, and the colours of adjacent horizontal rows should be different. Berland's government asked you to find out whether their flag meets the new ISO standard.
Input Specification:
The first line of the input contains numbers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100), *n* — the amount of rows, *m* — the amount of columns on the flag of Berland. Then there follows the description of the flag: each of the following *n* lines contain *m* characters. Each character is a digit between 0 and 9, and stands for the colour of the corresponding square.
Output Specification:
Output YES, if the flag meets the new ISO standard, and NO otherwise.
Demo Input:
['3 3\n000\n111\n222\n', '3 3\n000\n000\n111\n', '3 3\n000\n111\n002\n']
Demo Output:
['YES\n', 'NO\n', 'NO\n']
Note:
none | ```python
a = input().split(" ")
n, m = int(a[0]), int(a[1])
for i in range(n):
line = input()
past = ""
if(len(set(line)) == 1 and line[0] != past):
past = line[0]
else:
print("NO")
exit()
print("YES")
``` | 0 |
926 | A | 2-3-numbers | PROGRAMMING | 1,300 | [
"implementation",
"math"
] | null | null | A positive integer is called a 2-3-integer, if it is equal to 2*x*·3*y* for some non-negative integers *x* and *y*. In other words, these integers are such integers that only have 2 and 3 among their prime divisors. For example, integers 1, 6, 9, 16 and 108 — are 2-3 integers, while 5, 10, 21 and 120 are not.
Print the number of 2-3-integers on the given segment [*l*,<=*r*], i. e. the number of sich 2-3-integers *t* that *l*<=≤<=*t*<=≤<=*r*. | The only line contains two integers *l* and *r* (1<=≤<=*l*<=≤<=*r*<=≤<=2·109). | Print a single integer the number of 2-3-integers on the segment [*l*,<=*r*]. | [
"1 10\n",
"100 200\n",
"1 2000000000\n"
] | [
"7\n",
"5\n",
"326\n"
] | In the first example the 2-3-integers are 1, 2, 3, 4, 6, 8 and 9.
In the second example the 2-3-integers are 108, 128, 144, 162 and 192. | 0 | [
{
"input": "1 10",
"output": "7"
},
{
"input": "100 200",
"output": "5"
},
{
"input": "1 2000000000",
"output": "326"
},
{
"input": "1088391168 1934917632",
"output": "17"
},
{
"input": "1088391167 1934917632",
"output": "17"
},
{
"input": "1088391169 1934917632",
"output": "16"
},
{
"input": "1088391168 1934917631",
"output": "16"
},
{
"input": "1088391168 1934917633",
"output": "17"
},
{
"input": "4 134217728",
"output": "250"
},
{
"input": "209952 43046722",
"output": "112"
},
{
"input": "25165825 43046719",
"output": "13"
},
{
"input": "5183 25165825",
"output": "153"
},
{
"input": "388645 455910",
"output": "3"
},
{
"input": "472069 972050",
"output": "14"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "2 2",
"output": "1"
},
{
"input": "12 1999999931",
"output": "319"
},
{
"input": "1999999999 1999999999",
"output": "0"
},
{
"input": "2000000000 2000000000",
"output": "0"
},
{
"input": "1934917632 1934917632",
"output": "1"
},
{
"input": "1836660096 1836660096",
"output": "1"
},
{
"input": "1811939328 1811939328",
"output": "1"
},
{
"input": "1719926784 1719926784",
"output": "1"
},
{
"input": "1632586752 1632586752",
"output": "1"
},
{
"input": "1610612736 1610612736",
"output": "1"
},
{
"input": "1207959552 1207959552",
"output": "1"
},
{
"input": "129140163 129140163",
"output": "1"
},
{
"input": "12345 54321",
"output": "21"
},
{
"input": "1889569 25165826",
"output": "56"
},
{
"input": "73 7077888",
"output": "165"
},
{
"input": "7077888 45349631",
"output": "43"
},
{
"input": "6144 7077886",
"output": "122"
},
{
"input": "3779135 4194302",
"output": "2"
},
{
"input": "214 161243134",
"output": "232"
},
{
"input": "214 18874369",
"output": "180"
},
{
"input": "28 863",
"output": "26"
},
{
"input": "1417174 172186886",
"output": "112"
},
{
"input": "27 102036671",
"output": "234"
},
{
"input": "147458 102036672",
"output": "138"
},
{
"input": "33554431 102036671",
"output": "28"
},
{
"input": "1572863 33554433",
"output": "68"
},
{
"input": "33554434 181398528",
"output": "43"
},
{
"input": "373247 17915905",
"output": "81"
},
{
"input": "4251526 68024450",
"output": "65"
},
{
"input": "553599 555493",
"output": "0"
},
{
"input": "69739 671621",
"output": "40"
},
{
"input": "618583 755045",
"output": "4"
},
{
"input": "838469 943236",
"output": "2"
},
{
"input": "509607936 1836660096",
"output": "38"
},
{
"input": "509607935 1836660096",
"output": "38"
},
{
"input": "509607937 1836660096",
"output": "37"
},
{
"input": "509607936 1836660095",
"output": "37"
},
{
"input": "509607936 1836660097",
"output": "38"
}
] | 1,615,176,545 | 2,147,483,647 | Python 3 | OK | TESTS | 53 | 93 | 0 | import math
l,r = map(int, input().strip().split(' '))
#lst = list(map(int, input().strip().split(' ')))
c=0
for i in range(32):
for j in range(21):
p=(2**i)*(3**j)
if p>=l and p<=r:
c+=1
print(c)
| Title: 2-3-numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
A positive integer is called a 2-3-integer, if it is equal to 2*x*·3*y* for some non-negative integers *x* and *y*. In other words, these integers are such integers that only have 2 and 3 among their prime divisors. For example, integers 1, 6, 9, 16 and 108 — are 2-3 integers, while 5, 10, 21 and 120 are not.
Print the number of 2-3-integers on the given segment [*l*,<=*r*], i. e. the number of sich 2-3-integers *t* that *l*<=≤<=*t*<=≤<=*r*.
Input Specification:
The only line contains two integers *l* and *r* (1<=≤<=*l*<=≤<=*r*<=≤<=2·109).
Output Specification:
Print a single integer the number of 2-3-integers on the segment [*l*,<=*r*].
Demo Input:
['1 10\n', '100 200\n', '1 2000000000\n']
Demo Output:
['7\n', '5\n', '326\n']
Note:
In the first example the 2-3-integers are 1, 2, 3, 4, 6, 8 and 9.
In the second example the 2-3-integers are 108, 128, 144, 162 and 192. | ```python
import math
l,r = map(int, input().strip().split(' '))
#lst = list(map(int, input().strip().split(' ')))
c=0
for i in range(32):
for j in range(21):
p=(2**i)*(3**j)
if p>=l and p<=r:
c+=1
print(c)
``` | 3 | |
112 | A | Petya and Strings | PROGRAMMING | 800 | [
"implementation",
"strings"
] | A. Petya and Strings | 2 | 256 | Little Petya loves presents. His mum bought him two strings of the same size for his birthday. The strings consist of uppercase and lowercase Latin letters. Now Petya wants to compare those two strings lexicographically. The letters' case does not matter, that is an uppercase letter is considered equivalent to the corresponding lowercase letter. Help Petya perform the comparison. | Each of the first two lines contains a bought string. The strings' lengths range from 1 to 100 inclusive. It is guaranteed that the strings are of the same length and also consist of uppercase and lowercase Latin letters. | If the first string is less than the second one, print "-1". If the second string is less than the first one, print "1". If the strings are equal, print "0". Note that the letters' case is not taken into consideration when the strings are compared. | [
"aaaa\naaaA\n",
"abs\nAbz\n",
"abcdefg\nAbCdEfF\n"
] | [
"0\n",
"-1\n",
"1\n"
] | If you want more formal information about the lexicographical order (also known as the "dictionary order" or "alphabetical order"), you can visit the following site:
- http://en.wikipedia.org/wiki/Lexicographical_order | 500 | [
{
"input": "aaaa\naaaA",
"output": "0"
},
{
"input": "abs\nAbz",
"output": "-1"
},
{
"input": "abcdefg\nAbCdEfF",
"output": "1"
},
{
"input": "asadasdasd\nasdwasdawd",
"output": "-1"
},
{
"input": "aslkjlkasdd\nasdlkjdajwi",
"output": "1"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "0"
},
{
"input": "aAaaaAAaAaaAzZsssSsdDfeEaeqZlpP\nAaaaAaaAaaAaZzSSSSsDdFeeAeQZLpp",
"output": "0"
},
{
"input": "bwuEhEveouaTECagLZiqmUdxEmhRSOzMauJRWLQMppZOumxhAmwuGeDIkvkBLvMXwUoFmpAfDprBcFtEwOULcZWRQhcTbTbX\nHhoDWbcxwiMnCNexOsKsujLiSGcLllXOkRSbnOzThAjnnliLYFFmsYkOfpTxRNEfBsoUHfoLTiqAINRPxWRqrTJhgfkKcDOH",
"output": "-1"
},
{
"input": "kGWUuguKzcvxqKTNpxeDWXpXkrXDvGMFGoXKDfPBZvWSDUyIYBynbKOUonHvmZaKeirUhfmVRKtGhAdBfKMWXDUoqvbfpfHYcg\ncvOULleuIIiYVVxcLZmHVpNGXuEpzcWZZWyMOwIwbpkKPwCfkVbKkUuosvxYCKjqfVmHfJKbdrsAcatPYgrCABaFcoBuOmMfFt",
"output": "1"
},
{
"input": "nCeNVIzHqPceNhjHeHvJvgBsNFiXBATRrjSTXJzhLMDMxiJztphxBRlDlqwDFImWeEPkggZCXSRwelOdpNrYnTepiOqpvkr\nHJbjJFtlvNxIbkKlxQUwmZHJFVNMwPAPDRslIoXISBYHHfymyIaQHLgECPxAmqnOCizwXnIUBRmpYUBVPenoUKhCobKdOjL",
"output": "1"
},
{
"input": "ttXjenUAlfixytHEOrPkgXmkKTSGYuyVXGIHYmWWYGlBYpHkujueqBSgjLguSgiMGJWATIGEUjjAjKXdMiVbHozZUmqQtFrT\nJziDBFBDmDJCcGqFsQwDFBYdOidLxxhBCtScznnDgnsiStlWFnEXQrJxqTXKPxZyIGfLIToETKWZBPUIBmLeImrlSBWCkTNo",
"output": "1"
},
{
"input": "AjQhPqSVhwQQjcgCycjKorWBgFCRuQBwgdVuAPSMJAvTyxGVuFHjfJzkKfsmfhFbKqFrFIohSZBbpjgEHebezmVlGLTPSCTMf\nXhxWuSnMmKFrCUOwkTUmvKAfbTbHWzzOTzxJatLLCdlGnHVaBUnxDlsqpvjLHMThOPAFBggVKDyKBrZAmjnjrhHlrnSkyzBja",
"output": "-1"
},
{
"input": "HCIgYtnqcMyjVngziNflxKHtdTmcRJhzMAjFAsNdWXFJYEhiTzsQUtFNkAbdrFBRmvLirkuirqTDvIpEfyiIqkrwsjvpPWTEdI\nErqiiWKsmIjyZuzgTlTqxYZwlrpvRyaVhRTOYUqtPMVGGtWOkDCOOQRKrkkRzPftyQCkYkzKkzTPqqXmeZhvvEEiEhkdOmoMvy",
"output": "1"
},
{
"input": "mtBeJYILXcECGyEVSyzLFdQJbiVnnfkbsYYsdUJSIRmyzLfTTtFwIBmRLVnwcewIqcuydkcLpflHAFyDaToLiFMgeHvQorTVbI\nClLvyejznjbRfCDcrCzkLvqQaGzTjwmWONBdCctJAPJBcQrcYvHaSLQgPIJbmkFBhFzuQLBiRzAdNHulCjIAkBvZxxlkdzUWLR",
"output": "1"
},
{
"input": "tjucSbGESVmVridTBjTmpVBCwwdWKBPeBvmgdxgIVLwQxveETnSdxkTVJpXoperWSgdpPMKNmwDiGeHfxnuqaDissgXPlMuNZIr\nHfjOOJhomqNIKHvqSgfySjlsWJQBuWYwhLQhlZYlpZwboMpoLoluGsBmhhlYgeIouwdkPfiaAIrkYRlxtiFazOPOllPsNZHcIZd",
"output": "1"
},
{
"input": "AanbDfbZNlUodtBQlvPMyomStKNhgvSGhSbTdabxGFGGXCdpsJDimsAykKjfBDPMulkhBMsqLmVKLDoesHZsRAEEdEzqigueXInY\ncwfyjoppiJNrjrOLNZkqcGimrpTsiyFBVgMWEPXsMrxLJDDbtYzerXiFGuLBcQYitLdqhGHBpdjRnkUegmnwhGHAKXGyFtscWDSI",
"output": "-1"
},
{
"input": "HRfxniwuJCaHOcaOVgjOGHXKrwxrDQxJpppeGDXnTAowyKbCsCQPbchCKeTWOcKbySSYnoaTJDnmRcyGPbfXJyZoPcARHBu\nxkLXvwkvGIWSQaFTznLOctUXNuzzBBOlqvzmVfTSejekTAlwidRrsxkbZTsGGeEWxCXHzqWVuLGoCyrGjKkQoHqduXwYQKC",
"output": "-1"
},
{
"input": "OjYwwNuPESIazoyLFREpObIaMKhCaKAMWMfRGgucEuyNYRantwdwQkmflzfqbcFRaXBnZoIUGsFqXZHGKwlaBUXABBcQEWWPvkjW\nRxLqGcTTpBwHrHltCOllnTpRKLDofBUqqHxnOtVWPgvGaeHIevgUSOeeDOJubfqonFpVNGVbHFcAhjnyFvrrqnRgKhkYqQZmRfUl",
"output": "-1"
},
{
"input": "tatuhQPIzjptlzzJpCAPXSRTKZRlwgfoCIsFjJquRoIDyZZYRSPdFUTjjUPhLBBfeEIfLQpygKXRcyQFiQsEtRtLnZErBqW\ntkHUjllbafLUWhVCnvblKjgYIEoHhsjVmrDBmAWbvtkHxDbRFvsXAjHIrujaDbYwOZmacknhZPeCcorbRgHjjgAgoJdjvLo",
"output": "-1"
},
{
"input": "cymCPGqdXKUdADEWDdUaLEEMHiXHsdAZuDnJDMUvxvrLRBrPSDpXPAgMRoGplLtniFRTomDTAHXWAdgUveTxaqKVSvnOyhOwiRN\nuhmyEWzapiRNPFDisvHTbenXMfeZaHqOFlKjrfQjUBwdFktNpeiRoDWuBftZLcCZZAVfioOihZVNqiNCNDIsUdIhvbcaxpTRWoV",
"output": "-1"
},
{
"input": "sSvpcITJAwghVfJaLKBmyjOkhltTGjYJVLWCYMFUomiJaKQYhXTajvZVHIMHbyckYROGQZzjWyWCcnmDmrkvTKfHSSzCIhsXgEZa\nvhCXkCwAmErGVBPBAnkSYEYvseFKbWSktoqaHYXUmYkHfOkRwuEyBRoGoBrOXBKVxXycjZGStuvDarnXMbZLWrbjrisDoJBdSvWJ",
"output": "-1"
},
{
"input": "hJDANKUNBisOOINDsTixJmYgHNogtpwswwcvVMptfGwIjvqgwTYFcqTdyAqaqlnhOCMtsnWXQqtjFwQlEcBtMFAtSqnqthVb\nrNquIcjNWESjpPVWmzUJFrelpUZeGDmSvCurCqVmKHKVAAPkaHksniOlzjiKYIJtvbuQWZRufMebpTFPqyxIWWjfPaWYiNlK",
"output": "-1"
},
{
"input": "ycLoapxsfsDTHMSfAAPIUpiEhQKUIXUcXEiopMBuuZLHtfPpLmCHwNMNQUwsEXxCEmKHTBSnKhtQhGWUvppUFZUgSpbeChX\ndCZhgVXofkGousCzObxZSJwXcHIaqUDSCPKzXntcVmPxtNcXmVcjsetZYxedmgQzXTZHMvzjoaXCMKsncGciSDqQWIIRlys",
"output": "1"
},
{
"input": "nvUbnrywIePXcoukIhwTfUVcHUEgXcsMyNQhmMlTltZiCooyZiIKRIGVHMCnTKgzXXIuvoNDEZswKoACOBGSyVNqTNQqMhAG\nplxuGSsyyJjdvpddrSebOARSAYcZKEaKjqbCwvjhNykuaECoQVHTVFMKXwvrQXRaqXsHsBaGVhCxGRxNyGUbMlxOarMZNXxy",
"output": "-1"
},
{
"input": "EncmXtAblQzcVRzMQqdDqXfAhXbtJKQwZVWyHoWUckohnZqfoCmNJDzexFgFJYrwNHGgzCJTzQQFnxGlhmvQTpicTkEeVICKac\nNIUNZoMLFMyAjVgQLITELJSodIXcGSDWfhFypRoGYuogJpnqGTotWxVqpvBHjFOWcDRDtARsaHarHaOkeNWEHGTaGOFCOFEwvK",
"output": "-1"
},
{
"input": "UG\nak",
"output": "1"
},
{
"input": "JZR\nVae",
"output": "-1"
},
{
"input": "a\nZ",
"output": "-1"
},
{
"input": "rk\nkv",
"output": "1"
},
{
"input": "RvuT\nbJzE",
"output": "1"
},
{
"input": "PPS\nydq",
"output": "-1"
},
{
"input": "q\nq",
"output": "0"
},
{
"input": "peOw\nIgSJ",
"output": "1"
},
{
"input": "PyK\noKN",
"output": "1"
},
{
"input": "O\ni",
"output": "1"
},
{
"input": "NmGY\npDlP",
"output": "-1"
},
{
"input": "nG\nZf",
"output": "-1"
},
{
"input": "m\na",
"output": "1"
},
{
"input": "MWyB\nWZEV",
"output": "-1"
},
{
"input": "Gre\nfxc",
"output": "1"
},
{
"input": "Ooq\nwap",
"output": "-1"
},
{
"input": "XId\nlbB",
"output": "1"
},
{
"input": "lfFpECEqUMEOJhipvkZjDPcpDNJedOVXiSMgBvBZbtfzIKekcvpWPCazKAhJyHircRtgcBIJwwstpHaLAgxFOngAWUZRgCef\nLfFPEcequmeojHIpVkzjDPcpdNJEDOVXiSmGBVBZBtfZikEKcvPwpCAzKAHJyHIrCRTgCbIJWwSTphALagXfOnGAwUzRGcEF",
"output": "0"
},
{
"input": "DQBdtSEDtFGiNRUeJNbOIfDZnsryUlzJHGTXGFXnwsVyxNtLgmklmFvRCzYETBVdmkpJJIvIOkMDgCFHZOTODiYrkwXd\nDQbDtsEdTFginRUEJNBOIfdZnsryulZJHGtxGFxnwSvYxnTLgmKlmFVRCzyEtBVdmKpJjiVioKMDgCFhzoTODiYrKwXD",
"output": "0"
},
{
"input": "tYWRijFQSzHBpCjUzqBtNvBKyzZRnIdWEuyqnORBQTLyOQglIGfYJIRjuxnbLvkqZakNqPiGDvgpWYkfxYNXsdoKXZtRkSasfa\nTYwRiJfqsZHBPcJuZQBTnVbkyZZRnidwEuYQnorbQTLYOqGligFyjirJUxnblVKqZaknQpigDVGPwyKfxyNXSDoKxztRKSaSFA",
"output": "0"
},
{
"input": "KhScXYiErQIUtmVhNTCXSLAviefIeHIIdiGhsYnPkSBaDTvMkyanfMLBOvDWgRybLtDqvXVdVjccNunDyijhhZEAKBrdz\nkHsCXyiErqIuTMVHNTCxSLaViEFIEhIIDiGHsYNpKsBAdTvMKyANFMLBovdwGRYbLtdQVxvDVJCcNUndYiJHhzeakBrdZ",
"output": "0"
},
{
"input": "cpPQMpjRQJKQVXjWDYECXbagSmNcVfOuBWNZxihdERraVuiOpSVDCPgTGuSQALNoVjySceHcKXwOEpSzXrEqWwwrYeppNiWhDVg\nCPPqmPjRqJkQvxJwdyECXBAGsMNcVfOuBWNzxIhderRavUiOpSvDCpGTgusqAlNovjyScEhCKXwoePSZxrEQwWwryEPPniWHDvG",
"output": "0"
},
{
"input": "SajcCGMepaLjZIWLRBGFcrZRCRvvoCsIyKsQerbrwsIamxxpRmQSZSalasJLVFbCHCuXJlubciQAvLxXYBazLsMKLHLdDQ\nsaJcCgmEpaLJziWlrBgFcRzrCrVVOcSIykSQerBrwSIamxxPrMqSzSalASjLVFbChCUxjLUbCIQAVlxxybAZLsmkLhLDdQ",
"output": "0"
},
{
"input": "kigPrWNTOUNDBskAfefjhHYZNYdnfZWuXWzHiBxFQryBbAkPtenFwWvCSTYGpzOntUNzNUhxRWjKmicTwLwJAnbAxj\nkigpRWntOUNdBsKaFEFjhhYZnYDNfzWuXwZhibxFQRybbakPteNfwwvcStyGPzoNTunznuHXrWjKMIctWLWJANBAxJ",
"output": "0"
},
{
"input": "nTomZZuTTRTAAPoUsySVFGElrpQRNLjqvFmcYytiheQnjUhPLnqNBiYtQkljbcvmjuNAVKbvQOWpqqFlQhAhULIhquoCnjUI\nntOmzZuttrtAAPOUSySVFgeLRPQrNLjQvfmCyYTiHEQnjuHPlNQNbIYtqKLJBCVmjunavkbvQOWPQQFlqHaHULIHQuOcnJUi",
"output": "0"
},
{
"input": "abac\nadaa",
"output": "-1"
},
{
"input": "Bbc\nabc",
"output": "1"
},
{
"input": "aaaba\naaaab",
"output": "1"
}
] | 1,698,868,515 | 2,147,483,647 | Python 3 | COMPILATION_ERROR | TESTS | 0 | 0 | 0 | //progcode week 5 - 3
string1 = input().lower()
string2 = input().lower()
if string1 < string2:
print(-1)
elif string1 > string2:
print(1)
else:
print(0)
| Title: Petya and Strings
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Little Petya loves presents. His mum bought him two strings of the same size for his birthday. The strings consist of uppercase and lowercase Latin letters. Now Petya wants to compare those two strings lexicographically. The letters' case does not matter, that is an uppercase letter is considered equivalent to the corresponding lowercase letter. Help Petya perform the comparison.
Input Specification:
Each of the first two lines contains a bought string. The strings' lengths range from 1 to 100 inclusive. It is guaranteed that the strings are of the same length and also consist of uppercase and lowercase Latin letters.
Output Specification:
If the first string is less than the second one, print "-1". If the second string is less than the first one, print "1". If the strings are equal, print "0". Note that the letters' case is not taken into consideration when the strings are compared.
Demo Input:
['aaaa\naaaA\n', 'abs\nAbz\n', 'abcdefg\nAbCdEfF\n']
Demo Output:
['0\n', '-1\n', '1\n']
Note:
If you want more formal information about the lexicographical order (also known as the "dictionary order" or "alphabetical order"), you can visit the following site:
- http://en.wikipedia.org/wiki/Lexicographical_order | ```python
//progcode week 5 - 3
string1 = input().lower()
string2 = input().lower()
if string1 < string2:
print(-1)
elif string1 > string2:
print(1)
else:
print(0)
``` | -1 |
821 | A | Okabe and Future Gadget Laboratory | PROGRAMMING | 800 | [
"implementation"
] | null | null | Okabe needs to renovate the Future Gadget Laboratory after he tried doing some crazy experiments! The lab is represented as an *n* by *n* square grid of integers. A good lab is defined as a lab in which every number not equal to 1 can be expressed as the sum of a number in the same row and a number in the same column. In other words, for every *x*,<=*y* such that 1<=≤<=*x*,<=*y*<=≤<=*n* and *a**x*,<=*y*<=≠<=1, there should exist two indices *s* and *t* so that *a**x*,<=*y*<==<=*a**x*,<=*s*<=+<=*a**t*,<=*y*, where *a**i*,<=*j* denotes the integer in *i*-th row and *j*-th column.
Help Okabe determine whether a given lab is good! | The first line of input contains the integer *n* (1<=≤<=*n*<=≤<=50) — the size of the lab.
The next *n* lines contain *n* space-separated integers denoting a row of the grid. The *j*-th integer in the *i*-th row is *a**i*,<=*j* (1<=≤<=*a**i*,<=*j*<=≤<=105). | Print "Yes" if the given lab is good and "No" otherwise.
You can output each letter in upper or lower case. | [
"3\n1 1 2\n2 3 1\n6 4 1\n",
"3\n1 5 2\n1 1 1\n1 2 3\n"
] | [
"Yes\n",
"No\n"
] | In the first sample test, the 6 in the bottom left corner is valid because it is the sum of the 2 above it and the 4 on the right. The same holds for every number not equal to 1 in this table, so the answer is "Yes".
In the second sample test, the 5 cannot be formed as the sum of an integer in the same row and an integer in the same column. Thus the answer is "No". | 500 | [
{
"input": "3\n1 1 2\n2 3 1\n6 4 1",
"output": "Yes"
},
{
"input": "3\n1 5 2\n1 1 1\n1 2 3",
"output": "No"
},
{
"input": "1\n1",
"output": "Yes"
},
{
"input": "4\n1 1 1 1\n1 11 1 2\n2 5 1 4\n3 9 4 1",
"output": "Yes"
},
{
"input": "4\n1 1 1 1\n1 7 1 1\n1 3 1 2\n2 6 3 1",
"output": "Yes"
},
{
"input": "4\n1 1 1 1\n1 12 1 2\n4 4 1 3\n5 10 6 1",
"output": "Yes"
},
{
"input": "4\n1 1 1 1\n1 13 1 2\n4 5 1 3\n5 11 6 1",
"output": "Yes"
},
{
"input": "4\n1 1 1 1\n1 13 1 2\n4 5 1 3\n7 11 6 1",
"output": "No"
},
{
"input": "4\n1 1 1 1\n1 14 1 6\n4 5 1 5\n3 8 2 1",
"output": "Yes"
},
{
"input": "10\n3 2 6 5 1 2 1 1 2 1\n1 2 2 3 1 4 1 1 1 1\n1 1 3 1 2 2 2 1 1 1\n1 3 1 2 1 2 1 1 1 1\n12 1 4 3 3 1 1 1 2 1\n8 1 1 1 1 3 6 5 1 3\n1 1 1 2 4 1 3 2 1 1\n1 1 1 1 1 1 1 2 1 1\n1 2 1 1 1 1 1 1 1 1\n2 1 1 1 1 1 1 1 1 2",
"output": "Yes"
},
{
"input": "4\n1 2 3 5\n1 1 1 1\n1 1 1 1\n1 1 1 1",
"output": "No"
},
{
"input": "1\n2",
"output": "No"
},
{
"input": "3\n1 1 4\n1 1 2\n1 1 2",
"output": "No"
},
{
"input": "1\n5",
"output": "No"
},
{
"input": "3\n1 2 1\n2 2 3\n1 3 1",
"output": "No"
},
{
"input": "3\n2 1 1\n2 1 1\n2 1 1",
"output": "No"
},
{
"input": "1\n60000",
"output": "No"
}
] | 1,498,404,332 | 3,032 | Python 3 | OK | TESTS | 31 | 77 | 5,734,400 | #!/bin/python3
import sys
import time
import heapq
import collections
from io import StringIO
test_cases = [
("""
3
1 1 2
2 3 1
6 4 1
""", """
Yes
"""),
("""
3
1 5 2
1 1 1
1 2 3
""", """
No
"""),
]
def solve():
return "TEST"
def debug(*args, **kwargs):
print(*args, **kwargs, file=sys.stderr)
def check(rows, cols):
for i, row in enumerate(rows):
for j, el in enumerate(row):
if el != 1:
found = False
for k, add_in_row in enumerate(row):
add_in_col = el - add_in_row
n = cols[j].get(add_in_col, 0)
if k != j and (n > 0 and add_in_col != el or n > 1 and add_in_col == el):
found = True
break
if not found:
return False
return True
def main():
n = int(input())
rows = []
cols = []
for i in range(n):
rows.append([int(el) for el in input().split()])
for i in range(n):
# cols.append([row[i] for row in rows])
d = {}
for row in rows:
d[row[i]] = d.get(row[i], 0) + 1
cols.append(d)
result = check(rows, cols)
print('Yes' if result else 'No')
def test(s, check):
s = s.strip()
check = check.strip()
sys.stdin = StringIO(s)
sys.stdout = out = StringIO()
start_time = time.time()
try:
main()
finally:
exec_time = time.time() - start_time
sys.stdin = sys.__stdin__
sys.stdout = sys.__stdout__
out.seek(0)
result = out.read().strip()
status = "SUCCESS" if result == check else "FAILURE"
message = "status: {}, exec_time: {:.3f}".format(status, exec_time)
debug(message)
def test_all():
for s, check in test_cases:
test(s, check)
if __name__ == '__main__':
if len(sys.argv) > 1 and sys.argv[1] == '-t':
test_all()
else:
main()
| Title: Okabe and Future Gadget Laboratory
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Okabe needs to renovate the Future Gadget Laboratory after he tried doing some crazy experiments! The lab is represented as an *n* by *n* square grid of integers. A good lab is defined as a lab in which every number not equal to 1 can be expressed as the sum of a number in the same row and a number in the same column. In other words, for every *x*,<=*y* such that 1<=≤<=*x*,<=*y*<=≤<=*n* and *a**x*,<=*y*<=≠<=1, there should exist two indices *s* and *t* so that *a**x*,<=*y*<==<=*a**x*,<=*s*<=+<=*a**t*,<=*y*, where *a**i*,<=*j* denotes the integer in *i*-th row and *j*-th column.
Help Okabe determine whether a given lab is good!
Input Specification:
The first line of input contains the integer *n* (1<=≤<=*n*<=≤<=50) — the size of the lab.
The next *n* lines contain *n* space-separated integers denoting a row of the grid. The *j*-th integer in the *i*-th row is *a**i*,<=*j* (1<=≤<=*a**i*,<=*j*<=≤<=105).
Output Specification:
Print "Yes" if the given lab is good and "No" otherwise.
You can output each letter in upper or lower case.
Demo Input:
['3\n1 1 2\n2 3 1\n6 4 1\n', '3\n1 5 2\n1 1 1\n1 2 3\n']
Demo Output:
['Yes\n', 'No\n']
Note:
In the first sample test, the 6 in the bottom left corner is valid because it is the sum of the 2 above it and the 4 on the right. The same holds for every number not equal to 1 in this table, so the answer is "Yes".
In the second sample test, the 5 cannot be formed as the sum of an integer in the same row and an integer in the same column. Thus the answer is "No". | ```python
#!/bin/python3
import sys
import time
import heapq
import collections
from io import StringIO
test_cases = [
("""
3
1 1 2
2 3 1
6 4 1
""", """
Yes
"""),
("""
3
1 5 2
1 1 1
1 2 3
""", """
No
"""),
]
def solve():
return "TEST"
def debug(*args, **kwargs):
print(*args, **kwargs, file=sys.stderr)
def check(rows, cols):
for i, row in enumerate(rows):
for j, el in enumerate(row):
if el != 1:
found = False
for k, add_in_row in enumerate(row):
add_in_col = el - add_in_row
n = cols[j].get(add_in_col, 0)
if k != j and (n > 0 and add_in_col != el or n > 1 and add_in_col == el):
found = True
break
if not found:
return False
return True
def main():
n = int(input())
rows = []
cols = []
for i in range(n):
rows.append([int(el) for el in input().split()])
for i in range(n):
# cols.append([row[i] for row in rows])
d = {}
for row in rows:
d[row[i]] = d.get(row[i], 0) + 1
cols.append(d)
result = check(rows, cols)
print('Yes' if result else 'No')
def test(s, check):
s = s.strip()
check = check.strip()
sys.stdin = StringIO(s)
sys.stdout = out = StringIO()
start_time = time.time()
try:
main()
finally:
exec_time = time.time() - start_time
sys.stdin = sys.__stdin__
sys.stdout = sys.__stdout__
out.seek(0)
result = out.read().strip()
status = "SUCCESS" if result == check else "FAILURE"
message = "status: {}, exec_time: {:.3f}".format(status, exec_time)
debug(message)
def test_all():
for s, check in test_cases:
test(s, check)
if __name__ == '__main__':
if len(sys.argv) > 1 and sys.argv[1] == '-t':
test_all()
else:
main()
``` | 3 | |
789 | B | Masha and geometric depression | PROGRAMMING | 1,700 | [
"brute force",
"implementation",
"math"
] | null | null | Masha really loves algebra. On the last lesson, her strict teacher Dvastan gave she new exercise.
You are given geometric progression *b* defined by two integers *b*1 and *q*. Remind that a geometric progression is a sequence of integers *b*1,<=*b*2,<=*b*3,<=..., where for each *i*<=><=1 the respective term satisfies the condition *b**i*<==<=*b**i*<=-<=1·*q*, where *q* is called the common ratio of the progression. Progressions in Uzhlyandia are unusual: both *b*1 and *q* can equal 0. Also, Dvastan gave Masha *m* "bad" integers *a*1,<=*a*2,<=...,<=*a**m*, and an integer *l*.
Masha writes all progression terms one by one onto the board (including repetitive) while condition |*b**i*|<=≤<=*l* is satisfied (|*x*| means absolute value of *x*). There is an exception: if a term equals one of the "bad" integers, Masha skips it (doesn't write onto the board) and moves forward to the next term.
But the lesson is going to end soon, so Masha has to calculate how many integers will be written on the board. In order not to get into depression, Masha asked you for help: help her calculate how many numbers she will write, or print "inf" in case she needs to write infinitely many integers. | The first line of input contains four integers *b*1, *q*, *l*, *m* (-109<=≤<=*b*1,<=*q*<=≤<=109, 1<=≤<=*l*<=≤<=109, 1<=≤<=*m*<=≤<=105) — the initial term and the common ratio of progression, absolute value of maximal number that can be written on the board and the number of "bad" integers, respectively.
The second line contains *m* distinct integers *a*1,<=*a*2,<=...,<=*a**m* (-109<=≤<=*a**i*<=≤<=109) — numbers that will never be written on the board. | Print the only integer, meaning the number of progression terms that will be written on the board if it is finite, or "inf" (without quotes) otherwise. | [
"3 2 30 4\n6 14 25 48\n",
"123 1 2143435 4\n123 11 -5453 141245\n",
"123 1 2143435 4\n54343 -13 6 124\n"
] | [
"3",
"0",
"inf"
] | In the first sample case, Masha will write integers 3, 12, 24. Progression term 6 will be skipped because it is a "bad" integer. Terms bigger than 24 won't be written because they exceed *l* by absolute value.
In the second case, Masha won't write any number because all terms are equal 123 and this is a "bad" integer.
In the third case, Masha will write infinitely integers 123. | 1,000 | [
{
"input": "3 2 30 4\n6 14 25 48",
"output": "3"
},
{
"input": "123 1 2143435 4\n123 11 -5453 141245",
"output": "0"
},
{
"input": "123 1 2143435 4\n54343 -13 6 124",
"output": "inf"
},
{
"input": "3 2 25 2\n379195692 -69874783",
"output": "4"
},
{
"input": "3 2 30 3\n-691070108 -934106649 -220744807",
"output": "4"
},
{
"input": "3 3 104 17\n9 -73896485 -290898562 5254410 409659728 -916522518 -435516126 94354167 262981034 -375897180 -80186684 -173062070 -288705544 -699097793 -11447747 320434295 503414250",
"output": "3"
},
{
"input": "-1000000000 -1000000000 1 1\n232512888",
"output": "0"
},
{
"input": "11 0 228 5\n-1 0 1 5 -11245",
"output": "1"
},
{
"input": "11 0 228 5\n-1 -17 1 5 -11245",
"output": "inf"
},
{
"input": "0 0 2143435 5\n-1 -153 1 5 -11245",
"output": "inf"
},
{
"input": "123 0 2143435 4\n5433 0 123 -645",
"output": "0"
},
{
"input": "123 -1 2143435 5\n-123 0 12 5 -11245",
"output": "inf"
},
{
"input": "123 0 21 4\n543453 -123 6 1424",
"output": "0"
},
{
"input": "3 2 115 16\n24 48 12 96 3 720031148 -367712651 -838596957 558177735 -963046495 -313322487 -465018432 -618984128 -607173835 144854086 178041956",
"output": "1"
},
{
"input": "-3 0 92055 36\n-92974174 -486557474 -663622151 695596393 177960746 -563227474 -364263320 -676254242 -614140218 71456762 -764104225 705056581 -106398436 332755134 -199942822 -732751692 658942664 677739866 886535704 183687802 -784248291 -22550621 -938674499 637055091 -704750213 780395802 778342470 -999059668 -794361783 796469192 215667969 354336794 -60195289 -885080928 -290279020 201221317",
"output": "inf"
},
{
"input": "0 -3 2143435 5\n-1 0 1 5 -11245",
"output": "0"
},
{
"input": "123 -1 2143435 5\n-123 0 123 -5453 141245",
"output": "0"
},
{
"input": "123 0 2143435 4\n5433 0 -123 -645",
"output": "1"
},
{
"input": "11 0 2 5\n-1 0 1 5 -11245",
"output": "0"
},
{
"input": "2 2 4 1\n2",
"output": "1"
},
{
"input": "1 -2 1000000000 1\n0",
"output": "30"
},
{
"input": "0 8 10 1\n5",
"output": "inf"
},
{
"input": "-1000 0 10 1\n5",
"output": "0"
},
{
"input": "0 2 2143435 4\n54343 -13 6 124",
"output": "inf"
},
{
"input": "0 8 5 1\n9",
"output": "inf"
},
{
"input": "-10 1 5 1\n100",
"output": "0"
},
{
"input": "123 -1 2143435 4\n54343 -13 6 123",
"output": "inf"
},
{
"input": "-5 -1 10 1\n-5",
"output": "inf"
},
{
"input": "2 0 1 1\n2",
"output": "0"
},
{
"input": "0 5 8 1\n10",
"output": "inf"
},
{
"input": "0 5 100 2\n34 56",
"output": "inf"
},
{
"input": "15 -1 15 4\n15 -15 1 2",
"output": "0"
},
{
"input": "10 -1 2 1\n1",
"output": "0"
},
{
"input": "2 0 2 1\n2",
"output": "inf"
},
{
"input": "4 0 4 1\n0",
"output": "1"
},
{
"input": "10 10 10 1\n123",
"output": "1"
},
{
"input": "2 2 4 1\n3",
"output": "2"
},
{
"input": "0 1 1 1\n0",
"output": "0"
},
{
"input": "3 2 30 1\n3",
"output": "3"
},
{
"input": "1000000000 100000 1000000000 4\n5433 13 6 0",
"output": "1"
},
{
"input": "-2 0 1 1\n1",
"output": "0"
},
{
"input": "2 -1 10 1\n2",
"output": "inf"
},
{
"input": "1 -1 2 1\n1",
"output": "inf"
},
{
"input": "0 10 10 1\n2",
"output": "inf"
},
{
"input": "0 35 2 1\n3",
"output": "inf"
},
{
"input": "3 1 3 1\n5",
"output": "inf"
},
{
"input": "3 2 3 4\n6 14 25 48",
"output": "1"
},
{
"input": "0 69 12 1\n1",
"output": "inf"
},
{
"input": "100 0 100000 1\n100",
"output": "inf"
},
{
"input": "0 4 1000 3\n5 6 7",
"output": "inf"
},
{
"input": "0 2 100 1\n5",
"output": "inf"
},
{
"input": "3 2 24 4\n6 14 25 48",
"output": "3"
},
{
"input": "0 4 1 1\n2",
"output": "inf"
},
{
"input": "1 5 10000 1\n125",
"output": "5"
},
{
"input": "2 -1 1 1\n1",
"output": "0"
},
{
"input": "0 3 100 1\n5",
"output": "inf"
},
{
"input": "0 3 3 1\n1",
"output": "inf"
},
{
"input": "0 2 5 1\n1",
"output": "inf"
},
{
"input": "5 -1 100 1\n5",
"output": "inf"
},
{
"input": "-20 0 10 1\n0",
"output": "0"
},
{
"input": "3 0 1 1\n3",
"output": "0"
},
{
"input": "2 -1 3 1\n2",
"output": "inf"
},
{
"input": "1 1 1000000000 1\n100",
"output": "inf"
},
{
"input": "5 -1 3 1\n0",
"output": "0"
},
{
"input": "0 5 10 1\n2",
"output": "inf"
},
{
"input": "123 0 125 1\n123",
"output": "inf"
},
{
"input": "2 -1 100 1\n2",
"output": "inf"
},
{
"input": "5 2 100 1\n5",
"output": "4"
},
{
"input": "-5 0 1 1\n1",
"output": "0"
},
{
"input": "-3 0 1 1\n-3",
"output": "0"
},
{
"input": "2 -2 10 1\n1",
"output": "3"
},
{
"input": "0 2 30 4\n6 14 25 48",
"output": "inf"
},
{
"input": "1 -1 1 1\n1",
"output": "inf"
},
{
"input": "2 -1 6 1\n2",
"output": "inf"
},
{
"input": "-3 1 100 1\n-3",
"output": "0"
},
{
"input": "1 0 2 1\n1",
"output": "inf"
},
{
"input": "1000000000 999999998 1000000000 1\n0",
"output": "1"
},
{
"input": "1 0 2143435 4\n1 -123 -5453 141245",
"output": "inf"
},
{
"input": "-1000 0 100 1\n-1000",
"output": "0"
},
{
"input": "100 10 2 1\n100",
"output": "0"
},
{
"input": "-3 1 100 1\n3",
"output": "inf"
},
{
"input": "123 -1 10000 1\n123",
"output": "inf"
},
{
"input": "1 -1 2143435 4\n1 -123 -5453 141245",
"output": "inf"
},
{
"input": "5 1 5 5\n1 2 3 4 0",
"output": "inf"
},
{
"input": "-100 -1 1 1\n1",
"output": "0"
},
{
"input": "10 -1 3 2\n10 8",
"output": "0"
},
{
"input": "-10 0 5 1\n0",
"output": "0"
},
{
"input": "3 0 3 1\n0",
"output": "1"
},
{
"input": "2 0 2 1\n-1",
"output": "inf"
},
{
"input": "5 0 20 1\n5",
"output": "inf"
},
{
"input": "-4 1 1 1\n0",
"output": "0"
},
{
"input": "11 0 1111 1\n11",
"output": "inf"
},
{
"input": "2 0 3 1\n2",
"output": "inf"
},
{
"input": "-1 -1 2143435 4\n-1 -123 -5453 141245",
"output": "inf"
},
{
"input": "-100 0 50 1\n0",
"output": "0"
},
{
"input": "5 1 2 1\n2",
"output": "0"
},
{
"input": "3 0 3 1\n4",
"output": "inf"
},
{
"input": "0 23 3 1\n3",
"output": "inf"
},
{
"input": "-1000 0 100 1\n2",
"output": "0"
},
{
"input": "1 -1 10 1\n1",
"output": "inf"
}
] | 1,598,094,232 | 2,147,483,647 | PyPy 3 | OK | TESTS | 116 | 202 | 32,972,800 | import math,sys,bisect,heapq
from collections import defaultdict,Counter,deque
from itertools import groupby,accumulate
#sys.setrecursionlimit(200000000)
input = iter(sys.stdin.buffer.read().decode().splitlines()).__next__
ilele = lambda: map(int,input().split())
alele = lambda: list(map(int, input().split()))
def list2d(a, b, c): return [[c] * b for i in range(a)]
def list3d(a, b, c, d): return [[[d] * c for j in range(b)] for i in range(a)]
#MOD = 1000000000 + 7
def Y(c): print(["NO","YES"][c])
def y(c): print(["no","yes"][c])
def Yy(c): print(["No","Yes"][c])
b,q,l,m = ilele()
A = alele()
C = Counter(A)
Ans = [b]
if abs(b) > l:
print(0)
exit(0)
for i in range(100000):
b*= q
if abs(b) > l:
break
Ans.append(b)
#print(Ans)
count = 0
G = set()
for i in Ans:
if C.get(i,-1) == -1 and abs(i) <= l:
count += 1
G.add(i)
if count >= 10000 or (count > 1000 and len(G) <= 3) :
print("inf")
else:
print(count)
| Title: Masha and geometric depression
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Masha really loves algebra. On the last lesson, her strict teacher Dvastan gave she new exercise.
You are given geometric progression *b* defined by two integers *b*1 and *q*. Remind that a geometric progression is a sequence of integers *b*1,<=*b*2,<=*b*3,<=..., where for each *i*<=><=1 the respective term satisfies the condition *b**i*<==<=*b**i*<=-<=1·*q*, where *q* is called the common ratio of the progression. Progressions in Uzhlyandia are unusual: both *b*1 and *q* can equal 0. Also, Dvastan gave Masha *m* "bad" integers *a*1,<=*a*2,<=...,<=*a**m*, and an integer *l*.
Masha writes all progression terms one by one onto the board (including repetitive) while condition |*b**i*|<=≤<=*l* is satisfied (|*x*| means absolute value of *x*). There is an exception: if a term equals one of the "bad" integers, Masha skips it (doesn't write onto the board) and moves forward to the next term.
But the lesson is going to end soon, so Masha has to calculate how many integers will be written on the board. In order not to get into depression, Masha asked you for help: help her calculate how many numbers she will write, or print "inf" in case she needs to write infinitely many integers.
Input Specification:
The first line of input contains four integers *b*1, *q*, *l*, *m* (-109<=≤<=*b*1,<=*q*<=≤<=109, 1<=≤<=*l*<=≤<=109, 1<=≤<=*m*<=≤<=105) — the initial term and the common ratio of progression, absolute value of maximal number that can be written on the board and the number of "bad" integers, respectively.
The second line contains *m* distinct integers *a*1,<=*a*2,<=...,<=*a**m* (-109<=≤<=*a**i*<=≤<=109) — numbers that will never be written on the board.
Output Specification:
Print the only integer, meaning the number of progression terms that will be written on the board if it is finite, or "inf" (without quotes) otherwise.
Demo Input:
['3 2 30 4\n6 14 25 48\n', '123 1 2143435 4\n123 11 -5453 141245\n', '123 1 2143435 4\n54343 -13 6 124\n']
Demo Output:
['3', '0', 'inf']
Note:
In the first sample case, Masha will write integers 3, 12, 24. Progression term 6 will be skipped because it is a "bad" integer. Terms bigger than 24 won't be written because they exceed *l* by absolute value.
In the second case, Masha won't write any number because all terms are equal 123 and this is a "bad" integer.
In the third case, Masha will write infinitely integers 123. | ```python
import math,sys,bisect,heapq
from collections import defaultdict,Counter,deque
from itertools import groupby,accumulate
#sys.setrecursionlimit(200000000)
input = iter(sys.stdin.buffer.read().decode().splitlines()).__next__
ilele = lambda: map(int,input().split())
alele = lambda: list(map(int, input().split()))
def list2d(a, b, c): return [[c] * b for i in range(a)]
def list3d(a, b, c, d): return [[[d] * c for j in range(b)] for i in range(a)]
#MOD = 1000000000 + 7
def Y(c): print(["NO","YES"][c])
def y(c): print(["no","yes"][c])
def Yy(c): print(["No","Yes"][c])
b,q,l,m = ilele()
A = alele()
C = Counter(A)
Ans = [b]
if abs(b) > l:
print(0)
exit(0)
for i in range(100000):
b*= q
if abs(b) > l:
break
Ans.append(b)
#print(Ans)
count = 0
G = set()
for i in Ans:
if C.get(i,-1) == -1 and abs(i) <= l:
count += 1
G.add(i)
if count >= 10000 or (count > 1000 and len(G) <= 3) :
print("inf")
else:
print(count)
``` | 3 | |
451 | A | Game With Sticks | PROGRAMMING | 900 | [
"implementation"
] | null | null | After winning gold and silver in IOI 2014, Akshat and Malvika want to have some fun. Now they are playing a game on a grid made of *n* horizontal and *m* vertical sticks.
An intersection point is any point on the grid which is formed by the intersection of one horizontal stick and one vertical stick.
In the grid shown below, *n*<==<=3 and *m*<==<=3. There are *n*<=+<=*m*<==<=6 sticks in total (horizontal sticks are shown in red and vertical sticks are shown in green). There are *n*·*m*<==<=9 intersection points, numbered from 1 to 9.
The rules of the game are very simple. The players move in turns. Akshat won gold, so he makes the first move. During his/her move, a player must choose any remaining intersection point and remove from the grid all sticks which pass through this point. A player will lose the game if he/she cannot make a move (i.e. there are no intersection points remaining on the grid at his/her move).
Assume that both players play optimally. Who will win the game? | The first line of input contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100). | Print a single line containing "Akshat" or "Malvika" (without the quotes), depending on the winner of the game. | [
"2 2\n",
"2 3\n",
"3 3\n"
] | [
"Malvika\n",
"Malvika\n",
"Akshat\n"
] | Explanation of the first sample:
The grid has four intersection points, numbered from 1 to 4.
If Akshat chooses intersection point 1, then he will remove two sticks (1 - 2 and 1 - 3). The resulting grid will look like this.
Now there is only one remaining intersection point (i.e. 4). Malvika must choose it and remove both remaining sticks. After her move the grid will be empty.
In the empty grid, Akshat cannot make any move, hence he will lose.
Since all 4 intersection points of the grid are equivalent, Akshat will lose no matter which one he picks. | 500 | [
{
"input": "2 2",
"output": "Malvika"
},
{
"input": "2 3",
"output": "Malvika"
},
{
"input": "3 3",
"output": "Akshat"
},
{
"input": "20 68",
"output": "Malvika"
},
{
"input": "1 1",
"output": "Akshat"
},
{
"input": "1 2",
"output": "Akshat"
},
{
"input": "1 3",
"output": "Akshat"
},
{
"input": "2 1",
"output": "Akshat"
},
{
"input": "2 2",
"output": "Malvika"
},
{
"input": "3 1",
"output": "Akshat"
},
{
"input": "3 2",
"output": "Malvika"
},
{
"input": "68 42",
"output": "Malvika"
},
{
"input": "1 35",
"output": "Akshat"
},
{
"input": "25 70",
"output": "Akshat"
},
{
"input": "59 79",
"output": "Akshat"
},
{
"input": "65 63",
"output": "Akshat"
},
{
"input": "46 6",
"output": "Malvika"
},
{
"input": "28 82",
"output": "Malvika"
},
{
"input": "98 98",
"output": "Malvika"
},
{
"input": "98 99",
"output": "Malvika"
},
{
"input": "98 100",
"output": "Malvika"
},
{
"input": "99 98",
"output": "Malvika"
},
{
"input": "99 99",
"output": "Akshat"
},
{
"input": "99 100",
"output": "Akshat"
},
{
"input": "100 98",
"output": "Malvika"
},
{
"input": "100 99",
"output": "Akshat"
},
{
"input": "100 100",
"output": "Malvika"
},
{
"input": "3 4",
"output": "Akshat"
}
] | 1,686,343,034 | 2,147,483,647 | Python 3 | OK | TESTS | 28 | 46 | 0 | n, m = map(int, input().split())
min_sticks = min(n, m)
if min_sticks % 2 == 0:
print("Malvika")
else:
print("Akshat")
| Title: Game With Sticks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
After winning gold and silver in IOI 2014, Akshat and Malvika want to have some fun. Now they are playing a game on a grid made of *n* horizontal and *m* vertical sticks.
An intersection point is any point on the grid which is formed by the intersection of one horizontal stick and one vertical stick.
In the grid shown below, *n*<==<=3 and *m*<==<=3. There are *n*<=+<=*m*<==<=6 sticks in total (horizontal sticks are shown in red and vertical sticks are shown in green). There are *n*·*m*<==<=9 intersection points, numbered from 1 to 9.
The rules of the game are very simple. The players move in turns. Akshat won gold, so he makes the first move. During his/her move, a player must choose any remaining intersection point and remove from the grid all sticks which pass through this point. A player will lose the game if he/she cannot make a move (i.e. there are no intersection points remaining on the grid at his/her move).
Assume that both players play optimally. Who will win the game?
Input Specification:
The first line of input contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100).
Output Specification:
Print a single line containing "Akshat" or "Malvika" (without the quotes), depending on the winner of the game.
Demo Input:
['2 2\n', '2 3\n', '3 3\n']
Demo Output:
['Malvika\n', 'Malvika\n', 'Akshat\n']
Note:
Explanation of the first sample:
The grid has four intersection points, numbered from 1 to 4.
If Akshat chooses intersection point 1, then he will remove two sticks (1 - 2 and 1 - 3). The resulting grid will look like this.
Now there is only one remaining intersection point (i.e. 4). Malvika must choose it and remove both remaining sticks. After her move the grid will be empty.
In the empty grid, Akshat cannot make any move, hence he will lose.
Since all 4 intersection points of the grid are equivalent, Akshat will lose no matter which one he picks. | ```python
n, m = map(int, input().split())
min_sticks = min(n, m)
if min_sticks % 2 == 0:
print("Malvika")
else:
print("Akshat")
``` | 3 | |
994 | B | Knights of a Polygonal Table | PROGRAMMING | 1,400 | [
"greedy",
"implementation",
"sortings"
] | null | null | Unlike Knights of a Round Table, Knights of a Polygonal Table deprived of nobility and happy to kill each other. But each knight has some power and a knight can kill another knight if and only if his power is greater than the power of victim. However, even such a knight will torment his conscience, so he can kill no more than $k$ other knights. Also, each knight has some number of coins. After a kill, a knight can pick up all victim's coins.
Now each knight ponders: how many coins he can have if only he kills other knights?
You should answer this question for each knight. | The first line contains two integers $n$ and $k$ $(1 \le n \le 10^5, 0 \le k \le \min(n-1,10))$ — the number of knights and the number $k$ from the statement.
The second line contains $n$ integers $p_1, p_2 ,\ldots,p_n$ $(1 \le p_i \le 10^9)$ — powers of the knights. All $p_i$ are distinct.
The third line contains $n$ integers $c_1, c_2 ,\ldots,c_n$ $(0 \le c_i \le 10^9)$ — the number of coins each knight has. | Print $n$ integers — the maximum number of coins each knight can have it only he kills other knights. | [
"4 2\n4 5 9 7\n1 2 11 33\n",
"5 1\n1 2 3 4 5\n1 2 3 4 5\n",
"1 0\n2\n3\n"
] | [
"1 3 46 36 ",
"1 3 5 7 9 ",
"3 "
] | Consider the first example.
- The first knight is the weakest, so he can't kill anyone. That leaves him with the only coin he initially has. - The second knight can kill the first knight and add his coin to his own two. - The third knight is the strongest, but he can't kill more than $k = 2$ other knights. It is optimal to kill the second and the fourth knights: $2+11+33 = 46$. - The fourth knight should kill the first and the second knights: $33+1+2 = 36$.
In the second example the first knight can't kill anyone, while all the others should kill the one with the index less by one than their own.
In the third example there is only one knight, so he can't kill anyone. | 1,000 | [
{
"input": "4 2\n4 5 9 7\n1 2 11 33",
"output": "1 3 46 36 "
},
{
"input": "5 1\n1 2 3 4 5\n1 2 3 4 5",
"output": "1 3 5 7 9 "
},
{
"input": "1 0\n2\n3",
"output": "3 "
},
{
"input": "7 1\n2 3 4 5 7 8 9\n0 3 7 9 5 8 9",
"output": "0 3 10 16 14 17 18 "
},
{
"input": "7 2\n2 4 6 7 8 9 10\n10 8 4 8 4 5 9",
"output": "10 18 22 26 22 23 27 "
},
{
"input": "11 10\n1 2 3 4 5 6 7 8 9 10 11\n1000000000 1000000000 1000000000 1000000000 1000000000 1000000000 1000000000 1000000000 1000000000 1000000000 1000000000",
"output": "1000000000 2000000000 3000000000 4000000000 5000000000 6000000000 7000000000 8000000000 9000000000 10000000000 11000000000 "
},
{
"input": "2 0\n2 3\n3 3",
"output": "3 3 "
},
{
"input": "7 3\n1 2 3 4 5 6 7\n3 3 3 4 5 6 7",
"output": "3 6 9 13 15 18 22 "
},
{
"input": "3 0\n3 2 1\n1 2 3",
"output": "1 2 3 "
},
{
"input": "5 3\n4 5 7 9 11\n10 10 10 10 10",
"output": "10 20 30 40 40 "
},
{
"input": "4 0\n4 5 9 7\n1 2 11 33",
"output": "1 2 11 33 "
},
{
"input": "7 3\n1 2 3 4 5 6 7\n3 3 3 8 8 8 8",
"output": "3 6 9 17 22 27 32 "
},
{
"input": "3 0\n1 2 3\n5 5 5",
"output": "5 5 5 "
},
{
"input": "4 2\n4 5 9 7\n2 2 11 33",
"output": "2 4 46 37 "
},
{
"input": "6 3\n1 2 3 4 5 6\n1 1 1 1 1 1",
"output": "1 2 3 4 4 4 "
},
{
"input": "10 5\n1 2 3 4 5 6 7 8 9 10\n1 1 1 1 1 1 1 1 1 1",
"output": "1 2 3 4 5 6 6 6 6 6 "
},
{
"input": "3 2\n1 2 3\n1 1 1",
"output": "1 2 3 "
},
{
"input": "3 0\n1 2 3\n10 20 30",
"output": "10 20 30 "
},
{
"input": "4 0\n4 5 9 7\n1 2 3 4",
"output": "1 2 3 4 "
},
{
"input": "5 4\n1 2 3 4 5\n1 1 1 1 1",
"output": "1 2 3 4 5 "
},
{
"input": "4 3\n1 2 3 4\n5 5 5 5",
"output": "5 10 15 20 "
},
{
"input": "5 3\n1 2 3 4 5\n7 7 7 7 7",
"output": "7 14 21 28 28 "
}
] | 1,529,344,005 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 7 | 1,000 | 9,420,800 | def inputInts ():
inp = input ().split ()
ints = list ( map ( lambda i: int ( i ), inp ) )
return ints
n, k = inputInts ()
p = inputInts ()
c = inputInts ()
def get_weaker_knights ( power ):
weaker_knights = []
for i in range ( n ):
current_power = p [ i ]
if ( current_power < power ):
weaker_knights.append ( i )
return weaker_knights
def sort_knights_by_coins ( knights ):
return sorted (
knights,
key = lambda knight: c [ knight ],
reverse = True
)
def calcMaxCoins ( i ):
knight_power = p [ i ]
coins_sum = c [ i ]
weaker_knights = get_weaker_knights ( knight_power )
sorted_weaker_knights = sort_knights_by_coins ( weaker_knights )
for i in range ( min ( len ( sorted_weaker_knights ), k ) ):
victim = sorted_weaker_knights [ i ]
victim_coins = c [ victim ]
coins_sum += victim_coins
return coins_sum
output = ''
for i in range ( n ):
maxCoins = calcMaxCoins ( i )
output += str ( maxCoins ) + ' '
print ( output )
| Title: Knights of a Polygonal Table
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Unlike Knights of a Round Table, Knights of a Polygonal Table deprived of nobility and happy to kill each other. But each knight has some power and a knight can kill another knight if and only if his power is greater than the power of victim. However, even such a knight will torment his conscience, so he can kill no more than $k$ other knights. Also, each knight has some number of coins. After a kill, a knight can pick up all victim's coins.
Now each knight ponders: how many coins he can have if only he kills other knights?
You should answer this question for each knight.
Input Specification:
The first line contains two integers $n$ and $k$ $(1 \le n \le 10^5, 0 \le k \le \min(n-1,10))$ — the number of knights and the number $k$ from the statement.
The second line contains $n$ integers $p_1, p_2 ,\ldots,p_n$ $(1 \le p_i \le 10^9)$ — powers of the knights. All $p_i$ are distinct.
The third line contains $n$ integers $c_1, c_2 ,\ldots,c_n$ $(0 \le c_i \le 10^9)$ — the number of coins each knight has.
Output Specification:
Print $n$ integers — the maximum number of coins each knight can have it only he kills other knights.
Demo Input:
['4 2\n4 5 9 7\n1 2 11 33\n', '5 1\n1 2 3 4 5\n1 2 3 4 5\n', '1 0\n2\n3\n']
Demo Output:
['1 3 46 36 ', '1 3 5 7 9 ', '3 ']
Note:
Consider the first example.
- The first knight is the weakest, so he can't kill anyone. That leaves him with the only coin he initially has. - The second knight can kill the first knight and add his coin to his own two. - The third knight is the strongest, but he can't kill more than $k = 2$ other knights. It is optimal to kill the second and the fourth knights: $2+11+33 = 46$. - The fourth knight should kill the first and the second knights: $33+1+2 = 36$.
In the second example the first knight can't kill anyone, while all the others should kill the one with the index less by one than their own.
In the third example there is only one knight, so he can't kill anyone. | ```python
def inputInts ():
inp = input ().split ()
ints = list ( map ( lambda i: int ( i ), inp ) )
return ints
n, k = inputInts ()
p = inputInts ()
c = inputInts ()
def get_weaker_knights ( power ):
weaker_knights = []
for i in range ( n ):
current_power = p [ i ]
if ( current_power < power ):
weaker_knights.append ( i )
return weaker_knights
def sort_knights_by_coins ( knights ):
return sorted (
knights,
key = lambda knight: c [ knight ],
reverse = True
)
def calcMaxCoins ( i ):
knight_power = p [ i ]
coins_sum = c [ i ]
weaker_knights = get_weaker_knights ( knight_power )
sorted_weaker_knights = sort_knights_by_coins ( weaker_knights )
for i in range ( min ( len ( sorted_weaker_knights ), k ) ):
victim = sorted_weaker_knights [ i ]
victim_coins = c [ victim ]
coins_sum += victim_coins
return coins_sum
output = ''
for i in range ( n ):
maxCoins = calcMaxCoins ( i )
output += str ( maxCoins ) + ' '
print ( output )
``` | 0 | |
935 | A | Fafa and his Company | PROGRAMMING | 800 | [
"brute force",
"implementation"
] | null | null | Fafa owns a company that works on huge projects. There are *n* employees in Fafa's company. Whenever the company has a new project to start working on, Fafa has to divide the tasks of this project among all the employees.
Fafa finds doing this every time is very tiring for him. So, he decided to choose the best *l* employees in his company as team leaders. Whenever there is a new project, Fafa will divide the tasks among only the team leaders and each team leader will be responsible of some positive number of employees to give them the tasks. To make this process fair for the team leaders, each one of them should be responsible for the same number of employees. Moreover, every employee, who is not a team leader, has to be under the responsibility of exactly one team leader, and no team leader is responsible for another team leader.
Given the number of employees *n*, find in how many ways Fafa could choose the number of team leaders *l* in such a way that it is possible to divide employees between them evenly. | The input consists of a single line containing a positive integer *n* (2<=≤<=*n*<=≤<=105) — the number of employees in Fafa's company. | Print a single integer representing the answer to the problem. | [
"2\n",
"10\n"
] | [
"1\n",
"3\n"
] | In the second sample Fafa has 3 ways:
- choose only 1 employee as a team leader with 9 employees under his responsibility. - choose 2 employees as team leaders with 4 employees under the responsibility of each of them. - choose 5 employees as team leaders with 1 employee under the responsibility of each of them. | 500 | [
{
"input": "2",
"output": "1"
},
{
"input": "10",
"output": "3"
},
{
"input": "3",
"output": "1"
},
{
"input": "4",
"output": "2"
},
{
"input": "6",
"output": "3"
},
{
"input": "13",
"output": "1"
},
{
"input": "100000",
"output": "35"
},
{
"input": "1024",
"output": "10"
},
{
"input": "99999",
"output": "11"
},
{
"input": "10007",
"output": "1"
},
{
"input": "4096",
"output": "12"
},
{
"input": "65536",
"output": "16"
},
{
"input": "40320",
"output": "95"
},
{
"input": "30030",
"output": "63"
},
{
"input": "161",
"output": "3"
},
{
"input": "1000",
"output": "15"
},
{
"input": "10000",
"output": "24"
},
{
"input": "777",
"output": "7"
},
{
"input": "121",
"output": "2"
},
{
"input": "25",
"output": "2"
},
{
"input": "40000",
"output": "34"
},
{
"input": "99990",
"output": "47"
},
{
"input": "98765",
"output": "3"
},
{
"input": "56789",
"output": "3"
},
{
"input": "13579",
"output": "3"
},
{
"input": "97531",
"output": "3"
},
{
"input": "12345",
"output": "7"
},
{
"input": "54321",
"output": "7"
},
{
"input": "83160",
"output": "127"
},
{
"input": "9",
"output": "2"
},
{
"input": "21",
"output": "3"
},
{
"input": "11",
"output": "1"
},
{
"input": "15",
"output": "3"
}
] | 1,691,586,047 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 6 | 46 | 0 | n = int(input())
i = 1
nums = 0
for i in range(1, 10):
if n % i== 0 and i != n:
nums+=1
print(nums)
| Title: Fafa and his Company
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Fafa owns a company that works on huge projects. There are *n* employees in Fafa's company. Whenever the company has a new project to start working on, Fafa has to divide the tasks of this project among all the employees.
Fafa finds doing this every time is very tiring for him. So, he decided to choose the best *l* employees in his company as team leaders. Whenever there is a new project, Fafa will divide the tasks among only the team leaders and each team leader will be responsible of some positive number of employees to give them the tasks. To make this process fair for the team leaders, each one of them should be responsible for the same number of employees. Moreover, every employee, who is not a team leader, has to be under the responsibility of exactly one team leader, and no team leader is responsible for another team leader.
Given the number of employees *n*, find in how many ways Fafa could choose the number of team leaders *l* in such a way that it is possible to divide employees between them evenly.
Input Specification:
The input consists of a single line containing a positive integer *n* (2<=≤<=*n*<=≤<=105) — the number of employees in Fafa's company.
Output Specification:
Print a single integer representing the answer to the problem.
Demo Input:
['2\n', '10\n']
Demo Output:
['1\n', '3\n']
Note:
In the second sample Fafa has 3 ways:
- choose only 1 employee as a team leader with 9 employees under his responsibility. - choose 2 employees as team leaders with 4 employees under the responsibility of each of them. - choose 5 employees as team leaders with 1 employee under the responsibility of each of them. | ```python
n = int(input())
i = 1
nums = 0
for i in range(1, 10):
if n % i== 0 and i != n:
nums+=1
print(nums)
``` | 0 | |
868 | B | Race Against Time | PROGRAMMING | 1,400 | [
"implementation"
] | null | null | Have you ever tried to explain to the coordinator, why it is eight hours to the contest and not a single problem has been prepared yet? Misha had. And this time he has a really strong excuse: he faced a space-time paradox! Space and time replaced each other.
The entire universe turned into an enormous clock face with three hands — hour, minute, and second. Time froze, and clocks now show the time *h* hours, *m* minutes, *s* seconds.
Last time Misha talked with the coordinator at *t*1 o'clock, so now he stands on the number *t*1 on the clock face. The contest should be ready by *t*2 o'clock. In the terms of paradox it means that Misha has to go to number *t*2 somehow. Note that he doesn't have to move forward only: in these circumstances time has no direction.
Clock hands are very long, and Misha cannot get round them. He also cannot step over as it leads to the collapse of space-time. That is, if hour clock points 12 and Misha stands at 11 then he cannot move to 1 along the top arc. He has to follow all the way round the clock center (of course, if there are no other hands on his way).
Given the hands' positions, *t*1, and *t*2, find if Misha can prepare the contest on time (or should we say on space?). That is, find if he can move from *t*1 to *t*2 by the clock face. | Five integers *h*, *m*, *s*, *t*1, *t*2 (1<=≤<=*h*<=≤<=12, 0<=≤<=*m*,<=*s*<=≤<=59, 1<=≤<=*t*1,<=*t*2<=≤<=12, *t*1<=≠<=*t*2).
Misha's position and the target time do not coincide with the position of any hand. | Print "YES" (quotes for clarity), if Misha can prepare the contest on time, and "NO" otherwise.
You can print each character either upper- or lowercase ("YeS" and "yes" are valid when the answer is "YES"). | [
"12 30 45 3 11\n",
"12 0 1 12 1\n",
"3 47 0 4 9\n"
] | [
"NO\n",
"YES\n",
"YES\n"
] | The three examples are shown on the pictures below from left to right. The starting position of Misha is shown with green, the ending position is shown with pink. Note that the positions of the hands on the pictures are not exact, but are close to the exact and the answer is the same. | 500 | [
{
"input": "12 30 45 3 11",
"output": "NO"
},
{
"input": "12 0 1 12 1",
"output": "YES"
},
{
"input": "3 47 0 4 9",
"output": "YES"
},
{
"input": "10 22 59 6 10",
"output": "YES"
},
{
"input": "3 1 13 12 3",
"output": "NO"
},
{
"input": "11 19 28 9 10",
"output": "YES"
},
{
"input": "9 38 22 6 1",
"output": "NO"
},
{
"input": "5 41 11 5 8",
"output": "NO"
},
{
"input": "11 2 53 10 4",
"output": "YES"
},
{
"input": "9 41 17 10 1",
"output": "YES"
},
{
"input": "6 54 48 12 6",
"output": "YES"
},
{
"input": "12 55 9 5 1",
"output": "NO"
},
{
"input": "8 55 35 9 3",
"output": "NO"
},
{
"input": "3 21 34 3 10",
"output": "YES"
},
{
"input": "2 52 1 12 3",
"output": "NO"
},
{
"input": "7 17 11 1 7",
"output": "NO"
},
{
"input": "11 6 37 6 4",
"output": "YES"
},
{
"input": "9 6 22 8 1",
"output": "NO"
},
{
"input": "3 10 5 5 9",
"output": "YES"
},
{
"input": "7 12 22 11 2",
"output": "YES"
},
{
"input": "7 19 4 7 3",
"output": "NO"
},
{
"input": "11 36 21 4 6",
"output": "NO"
},
{
"input": "10 32 49 1 3",
"output": "YES"
},
{
"input": "1 9 43 11 3",
"output": "NO"
},
{
"input": "1 8 33 4 8",
"output": "NO"
},
{
"input": "3 0 33 9 4",
"output": "NO"
},
{
"input": "7 15 9 10 3",
"output": "NO"
},
{
"input": "8 3 57 11 1",
"output": "NO"
},
{
"input": "1 33 49 5 9",
"output": "NO"
},
{
"input": "3 40 0 5 7",
"output": "YES"
},
{
"input": "5 50 9 2 7",
"output": "NO"
},
{
"input": "10 0 52 6 1",
"output": "YES"
},
{
"input": "3 10 4 1 11",
"output": "NO"
},
{
"input": "2 41 53 4 6",
"output": "YES"
},
{
"input": "10 29 30 4 7",
"output": "NO"
},
{
"input": "5 13 54 9 11",
"output": "NO"
},
{
"input": "1 0 23 3 9",
"output": "NO"
},
{
"input": "1 0 41 12 1",
"output": "NO"
},
{
"input": "6 30 30 3 9",
"output": "YES"
},
{
"input": "3 7 32 11 10",
"output": "YES"
},
{
"input": "1 0 25 12 4",
"output": "NO"
},
{
"input": "12 0 0 5 6",
"output": "YES"
},
{
"input": "1 5 4 3 2",
"output": "YES"
},
{
"input": "6 30 30 9 10",
"output": "YES"
},
{
"input": "6 0 0 2 8",
"output": "NO"
},
{
"input": "10 50 59 9 10",
"output": "YES"
},
{
"input": "12 59 59 12 6",
"output": "NO"
},
{
"input": "3 0 30 3 4",
"output": "NO"
},
{
"input": "2 10 10 1 11",
"output": "YES"
},
{
"input": "10 5 30 1 12",
"output": "YES"
},
{
"input": "5 29 31 5 10",
"output": "YES"
},
{
"input": "5 2 2 11 2",
"output": "NO"
},
{
"input": "5 15 46 3 10",
"output": "YES"
},
{
"input": "1 30 50 1 2",
"output": "NO"
},
{
"input": "5 26 14 1 12",
"output": "YES"
},
{
"input": "1 58 43 12 1",
"output": "YES"
},
{
"input": "12 0 12 11 1",
"output": "NO"
},
{
"input": "6 52 41 6 5",
"output": "YES"
},
{
"input": "5 8 2 1 3",
"output": "NO"
},
{
"input": "2 0 0 1 3",
"output": "NO"
},
{
"input": "1 5 6 2 1",
"output": "YES"
},
{
"input": "9 5 5 11 12",
"output": "YES"
},
{
"input": "12 5 19 3 4",
"output": "NO"
},
{
"input": "6 14 59 1 3",
"output": "NO"
},
{
"input": "10 38 34 4 12",
"output": "YES"
},
{
"input": "2 54 14 2 12",
"output": "YES"
},
{
"input": "5 31 0 6 7",
"output": "NO"
},
{
"input": "6 15 30 3 9",
"output": "YES"
},
{
"input": "3 54 41 8 10",
"output": "NO"
},
{
"input": "3 39 10 10 12",
"output": "YES"
},
{
"input": "1 11 50 1 2",
"output": "NO"
},
{
"input": "5 40 24 8 1",
"output": "NO"
},
{
"input": "9 5 59 1 3",
"output": "NO"
},
{
"input": "5 0 0 6 7",
"output": "YES"
},
{
"input": "4 40 59 6 8",
"output": "YES"
},
{
"input": "10 13 55 12 1",
"output": "YES"
},
{
"input": "6 50 0 5 6",
"output": "YES"
},
{
"input": "7 59 3 7 4",
"output": "YES"
},
{
"input": "6 0 1 6 7",
"output": "NO"
},
{
"input": "6 15 55 3 5",
"output": "NO"
},
{
"input": "12 9 55 10 2",
"output": "YES"
},
{
"input": "2 0 1 11 2",
"output": "NO"
},
{
"input": "8 45 17 12 9",
"output": "NO"
},
{
"input": "5 30 31 11 3",
"output": "YES"
},
{
"input": "6 43 0 10 6",
"output": "NO"
},
{
"input": "6 30 30 1 11",
"output": "YES"
},
{
"input": "11 59 59 11 12",
"output": "YES"
},
{
"input": "5 45 35 9 5",
"output": "NO"
},
{
"input": "2 43 4 9 7",
"output": "NO"
},
{
"input": "12 30 50 6 9",
"output": "NO"
},
{
"input": "1 10 1 2 3",
"output": "NO"
},
{
"input": "10 5 55 9 1",
"output": "NO"
},
{
"input": "1 59 59 2 3",
"output": "YES"
},
{
"input": "1 49 14 10 3",
"output": "NO"
},
{
"input": "3 15 15 2 4",
"output": "YES"
},
{
"input": "10 5 55 1 5",
"output": "NO"
},
{
"input": "6 33 45 12 6",
"output": "YES"
},
{
"input": "1 20 20 11 1",
"output": "YES"
},
{
"input": "2 30 45 1 11",
"output": "YES"
},
{
"input": "1 55 1 11 10",
"output": "YES"
},
{
"input": "3 0 1 11 1",
"output": "NO"
},
{
"input": "1 5 6 1 12",
"output": "YES"
},
{
"input": "12 10 5 11 4",
"output": "YES"
},
{
"input": "6 5 59 12 1",
"output": "YES"
},
{
"input": "12 0 20 11 12",
"output": "YES"
},
{
"input": "3 25 30 4 5",
"output": "YES"
},
{
"input": "2 15 18 11 1",
"output": "YES"
},
{
"input": "12 5 48 11 9",
"output": "NO"
},
{
"input": "6 30 30 10 2",
"output": "YES"
},
{
"input": "1 0 11 1 2",
"output": "NO"
},
{
"input": "10 0 1 10 11",
"output": "NO"
},
{
"input": "3 30 45 10 1",
"output": "YES"
},
{
"input": "11 21 56 3 12",
"output": "YES"
},
{
"input": "3 16 16 3 4",
"output": "YES"
},
{
"input": "11 55 55 1 12",
"output": "YES"
},
{
"input": "12 12 12 11 12",
"output": "YES"
},
{
"input": "3 5 1 1 2",
"output": "NO"
},
{
"input": "3 30 45 10 11",
"output": "YES"
},
{
"input": "10 0 1 9 10",
"output": "YES"
},
{
"input": "3 0 5 3 6",
"output": "NO"
},
{
"input": "1 1 49 1 10",
"output": "NO"
},
{
"input": "9 45 15 11 12",
"output": "YES"
},
{
"input": "12 15 59 3 8",
"output": "NO"
},
{
"input": "5 0 5 3 6",
"output": "NO"
},
{
"input": "3 30 45 1 2",
"output": "YES"
},
{
"input": "2 10 11 2 4",
"output": "YES"
},
{
"input": "2 10 10 4 3",
"output": "YES"
},
{
"input": "3 30 59 1 2",
"output": "YES"
},
{
"input": "11 59 59 12 11",
"output": "YES"
},
{
"input": "10 25 50 5 6",
"output": "NO"
},
{
"input": "6 30 30 9 3",
"output": "YES"
},
{
"input": "8 14 40 12 3",
"output": "NO"
},
{
"input": "2 10 10 1 6",
"output": "YES"
}
] | 1,507,188,069 | 969 | Python 3 | WRONG_ANSWER | PRETESTS | 3 | 46 | 0 | h, m, s, t1, t2 = map(int, input().split())
h = (h * 5) % 60
t1 = (t1 * 5) % 60
t2 = (t2 * 5) % 60
count = 0
for val in [h, m, s]:
if val >= t1 and val <= t2:
count += 1
if count == 0 or count == 3:
print("YES")
else:
print("NO")
| Title: Race Against Time
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Have you ever tried to explain to the coordinator, why it is eight hours to the contest and not a single problem has been prepared yet? Misha had. And this time he has a really strong excuse: he faced a space-time paradox! Space and time replaced each other.
The entire universe turned into an enormous clock face with three hands — hour, minute, and second. Time froze, and clocks now show the time *h* hours, *m* minutes, *s* seconds.
Last time Misha talked with the coordinator at *t*1 o'clock, so now he stands on the number *t*1 on the clock face. The contest should be ready by *t*2 o'clock. In the terms of paradox it means that Misha has to go to number *t*2 somehow. Note that he doesn't have to move forward only: in these circumstances time has no direction.
Clock hands are very long, and Misha cannot get round them. He also cannot step over as it leads to the collapse of space-time. That is, if hour clock points 12 and Misha stands at 11 then he cannot move to 1 along the top arc. He has to follow all the way round the clock center (of course, if there are no other hands on his way).
Given the hands' positions, *t*1, and *t*2, find if Misha can prepare the contest on time (or should we say on space?). That is, find if he can move from *t*1 to *t*2 by the clock face.
Input Specification:
Five integers *h*, *m*, *s*, *t*1, *t*2 (1<=≤<=*h*<=≤<=12, 0<=≤<=*m*,<=*s*<=≤<=59, 1<=≤<=*t*1,<=*t*2<=≤<=12, *t*1<=≠<=*t*2).
Misha's position and the target time do not coincide with the position of any hand.
Output Specification:
Print "YES" (quotes for clarity), if Misha can prepare the contest on time, and "NO" otherwise.
You can print each character either upper- or lowercase ("YeS" and "yes" are valid when the answer is "YES").
Demo Input:
['12 30 45 3 11\n', '12 0 1 12 1\n', '3 47 0 4 9\n']
Demo Output:
['NO\n', 'YES\n', 'YES\n']
Note:
The three examples are shown on the pictures below from left to right. The starting position of Misha is shown with green, the ending position is shown with pink. Note that the positions of the hands on the pictures are not exact, but are close to the exact and the answer is the same. | ```python
h, m, s, t1, t2 = map(int, input().split())
h = (h * 5) % 60
t1 = (t1 * 5) % 60
t2 = (t2 * 5) % 60
count = 0
for val in [h, m, s]:
if val >= t1 and val <= t2:
count += 1
if count == 0 or count == 3:
print("YES")
else:
print("NO")
``` | 0 | |
549 | A | Face Detection | PROGRAMMING | 900 | [
"implementation",
"strings"
] | null | null | The developers of Looksery have to write an efficient algorithm that detects faces on a picture. Unfortunately, they are currently busy preparing a contest for you, so you will have to do it for them.
In this problem an image is a rectangular table that consists of lowercase Latin letters. A face on the image is a 2<=×<=2 square, such that from the four letters of this square you can make word "face".
You need to write a program that determines the number of faces on the image. The squares that correspond to the faces can overlap. | The first line contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=50) — the height and the width of the image, respectively.
Next *n* lines define the image. Each line contains *m* lowercase Latin letters. | In the single line print the number of faces on the image. | [
"4 4\nxxxx\nxfax\nxcex\nxxxx\n",
"4 2\nxx\ncf\nae\nxx\n",
"2 3\nfac\ncef\n",
"1 4\nface\n"
] | [
"1\n",
"1\n",
"2\n",
"0\n"
] | In the first sample the image contains a single face, located in a square with the upper left corner at the second line and the second column:
In the second sample the image also contains exactly one face, its upper left corner is at the second row and the first column.
In the third sample two faces are shown:
In the fourth sample the image has no faces on it. | 250 | [
{
"input": "4 4\nxxxx\nxfax\nxcex\nxxxx",
"output": "1"
},
{
"input": "4 2\nxx\ncf\nae\nxx",
"output": "1"
},
{
"input": "2 3\nfac\ncef",
"output": "2"
},
{
"input": "1 4\nface",
"output": "0"
},
{
"input": "5 5\nwmmwn\nlurcm\nkeetd\nfokon\ncxxgx",
"output": "0"
},
{
"input": "5 5\nkjxbw\neacra\nxefhx\nucmcz\npgtjk",
"output": "1"
},
{
"input": "1 1\np",
"output": "0"
},
{
"input": "2 5\nacdmw\nefazb",
"output": "1"
},
{
"input": "5 2\ndz\nda\nsx\nyu\nzz",
"output": "0"
},
{
"input": "5 5\nxeljd\nwriac\nveief\nlcacf\nbqefn",
"output": "2"
},
{
"input": "5 5\nacnbx\nefacp\nlrefa\norqce\nzvbay",
"output": "3"
},
{
"input": "5 5\nbyjvu\nkmaca\nalefe\nwcacg\nrefez",
"output": "5"
},
{
"input": "5 5\npuxac\nbbaef\naccfa\nefaec\nligsr",
"output": "5"
},
{
"input": "37 4\nacjo\nefac\nacef\nefac\nwpef\nicac\naefe\ncfac\naece\ncfaf\nyqce\nmiaf\nirce\nycaf\naefc\ncfae\nrsnc\nbacz\nqefb\npdhs\nffac\nfaef\nacfd\nacmi\nefvm\nacaz\nefpn\nacao\nefer\nacap\nefec\nacaf\nefef\nacbj\nefac\nacef\nefoz",
"output": "49"
},
{
"input": "7 3\njac\naef\ncfa\naec\ncfq\ndig\nxyq",
"output": "5"
},
{
"input": "35 1\ny\na\nk\ng\ni\nd\nv\nn\nl\nx\nu\nx\nu\no\nd\nf\nk\nj\nr\nm\nq\ns\nc\nd\nc\nm\nv\nh\nn\ne\nl\nt\nz\ny\no",
"output": "0"
},
{
"input": "9 46\nuuexbaacesjclggslacermcbkxlcxhdgqtacdwfryxzuxc\naclrsaefakndbnzlkefenuphgcgoedhkaxefjtnkgfeaca\nefuqunpmfxdyyffyhvracozzrxlpekhtsrfhlilfmyhefg\numyacfzffvicqtdpiulefnwcojuwtfbvlxkfsiapdnzpqo\nactefvuxqptremlqjhdbdwacjxdxitxjktecvefacamjcz\neflarseklqrkayhosverpfefzirqigzlxezabhzeferkwm\nztpypwxyohtacsnnvoigqwcachtaceyxlkhfhgwbnfmklb\nfzpqeymhljiefctvqtbgcdjefkxefarbciyosmktmoziac\nbssxizyrzyhacszttwhrzspbfkgfcejybdjcpuczhrkqef",
"output": "20"
},
{
"input": "7 30\nmjfracgaacacctacrreyrlkacuacay\nrlacefacefeftaeftkacacaefcefev\nacefacefacraccfaeaefefecaeacaf\nefacefacefaefaecfcfacacaecfefa\nncefacefacecacfaeaecefefcaeace\nfafaceacuafaefadcfcafacaefcfea\nzsvefafukcecfarkaeaecefecailgu",
"output": "95"
},
{
"input": "2 2\nff\nee",
"output": "0"
},
{
"input": "2 2\nfa\ncc",
"output": "0"
},
{
"input": "2 2\nfa\naa",
"output": "0"
},
{
"input": "2 2\nfa\nea",
"output": "0"
},
{
"input": "2 2\nfa\ndd",
"output": "0"
},
{
"input": "2 2\nee\nff",
"output": "0"
},
{
"input": "2 2\ncc\ncf",
"output": "0"
},
{
"input": "2 2\naa\nae",
"output": "0"
},
{
"input": "2 2\nef\nac",
"output": "1"
},
{
"input": "2 2\nfe\nca",
"output": "1"
}
] | 1,620,428,973 | 2,147,483,647 | Python 3 | OK | TESTS | 37 | 77 | 6,963,200 | n, m = map(int, input().split())
matrix = [input() for i in range(n)]
word_to_search = {'a','e','f', 'c'}
res = 0
for i in range(n - 1):
for j in range(m - 1):
set_to_match = {matrix[i][j],
matrix[i+1][j],
matrix[i][j+1],
matrix[i+1][j+1]}
if set_to_match == word_to_search:
res += 1
print(res)
| Title: Face Detection
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The developers of Looksery have to write an efficient algorithm that detects faces on a picture. Unfortunately, they are currently busy preparing a contest for you, so you will have to do it for them.
In this problem an image is a rectangular table that consists of lowercase Latin letters. A face on the image is a 2<=×<=2 square, such that from the four letters of this square you can make word "face".
You need to write a program that determines the number of faces on the image. The squares that correspond to the faces can overlap.
Input Specification:
The first line contains two space-separated integers, *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=50) — the height and the width of the image, respectively.
Next *n* lines define the image. Each line contains *m* lowercase Latin letters.
Output Specification:
In the single line print the number of faces on the image.
Demo Input:
['4 4\nxxxx\nxfax\nxcex\nxxxx\n', '4 2\nxx\ncf\nae\nxx\n', '2 3\nfac\ncef\n', '1 4\nface\n']
Demo Output:
['1\n', '1\n', '2\n', '0\n']
Note:
In the first sample the image contains a single face, located in a square with the upper left corner at the second line and the second column:
In the second sample the image also contains exactly one face, its upper left corner is at the second row and the first column.
In the third sample two faces are shown:
In the fourth sample the image has no faces on it. | ```python
n, m = map(int, input().split())
matrix = [input() for i in range(n)]
word_to_search = {'a','e','f', 'c'}
res = 0
for i in range(n - 1):
for j in range(m - 1):
set_to_match = {matrix[i][j],
matrix[i+1][j],
matrix[i][j+1],
matrix[i+1][j+1]}
if set_to_match == word_to_search:
res += 1
print(res)
``` | 3 | |
192 | B | Walking in the Rain | PROGRAMMING | 1,100 | [
"brute force",
"implementation"
] | null | null | In Berland the opposition is going to arrange mass walking on the boulevard. The boulevard consists of *n* tiles that are lain in a row and are numbered from 1 to *n* from right to left. The opposition should start walking on the tile number 1 and the finish on the tile number *n*. During the walk it is allowed to move from right to left between adjacent tiles in a row, and jump over a tile. More formally, if you are standing on the tile number *i* (*i*<=<<=*n*<=-<=1), you can reach the tiles number *i*<=+<=1 or the tile number *i*<=+<=2 from it (if you stand on the tile number *n*<=-<=1, you can only reach tile number *n*). We can assume that all the opposition movements occur instantaneously.
In order to thwart an opposition rally, the Berland bloody regime organized the rain. The tiles on the boulevard are of poor quality and they are rapidly destroyed in the rain. We know that the *i*-th tile is destroyed after *a**i* days of rain (on day *a**i* tile isn't destroyed yet, and on day *a**i*<=+<=1 it is already destroyed). Of course, no one is allowed to walk on the destroyed tiles! So the walk of the opposition is considered thwarted, if either the tile number 1 is broken, or the tile number *n* is broken, or it is impossible to reach the tile number *n* from the tile number 1 if we can walk on undestroyed tiles.
The opposition wants to gather more supporters for their walk. Therefore, the more time they have to pack, the better. Help the opposition to calculate how much time they still have and tell us for how many days the walk from the tile number 1 to the tile number *n* will be possible. | The first line contains integer *n* (1<=≤<=*n*<=≤<=103) — the boulevard's length in tiles.
The second line contains *n* space-separated integers *a**i* — the number of days after which the *i*-th tile gets destroyed (1<=≤<=*a**i*<=≤<=103). | Print a single number — the sought number of days. | [
"4\n10 3 5 10\n",
"5\n10 2 8 3 5\n"
] | [
"5\n",
"5\n"
] | In the first sample the second tile gets destroyed after day three, and the only path left is 1 → 3 → 4. After day five there is a two-tile gap between the first and the last tile, you can't jump over it.
In the second sample path 1 → 3 → 5 is available up to day five, inclusive. On day six the last tile is destroyed and the walk is thwarted. | 1,000 | [
{
"input": "4\n10 3 5 10",
"output": "5"
},
{
"input": "5\n10 2 8 3 5",
"output": "5"
},
{
"input": "10\n10 3 1 6 7 1 3 3 8 1",
"output": "1"
},
{
"input": "10\n26 72 10 52 2 5 61 2 39 64",
"output": "5"
},
{
"input": "100\n8 2 1 2 8 3 5 8 5 1 9 3 4 1 5 6 4 2 9 10 6 10 10 3 9 4 10 5 3 1 5 10 7 6 8 10 2 6 4 4 2 2 10 7 2 7 3 2 6 3 6 4 7 6 2 5 5 8 6 9 5 2 7 5 8 6 5 8 10 6 10 8 5 3 1 10 6 1 7 5 1 8 10 5 1 3 10 7 10 5 7 1 4 3 8 6 3 4 9 6",
"output": "2"
},
{
"input": "100\n10 2 8 7 5 1 5 4 9 2 7 9 3 5 6 2 3 6 10 1 2 7 1 4 8 8 6 1 7 8 8 1 5 8 1 2 7 4 10 7 3 1 2 5 8 1 1 4 9 7 7 4 7 3 8 8 7 1 5 1 6 9 8 8 1 10 4 4 7 7 10 9 5 1 1 3 6 2 6 3 6 4 9 8 2 9 6 2 7 8 10 9 9 6 3 5 3 1 4 8",
"output": "1"
},
{
"input": "100\n21 57 14 6 58 61 37 54 43 22 90 90 90 14 10 97 47 43 19 66 96 58 88 92 22 62 99 97 15 36 58 93 44 42 45 38 41 21 16 30 66 92 39 70 1 73 83 27 63 21 20 84 30 30 30 77 93 30 62 96 33 34 28 59 48 89 68 62 50 16 18 19 42 42 80 58 31 59 40 81 92 26 28 47 26 8 8 74 86 80 88 82 98 27 41 97 11 91 42 67",
"output": "8"
},
{
"input": "100\n37 75 11 81 60 33 17 80 37 77 26 86 31 78 59 23 92 38 8 15 30 91 99 75 79 34 78 80 19 51 48 48 61 74 59 30 26 2 71 74 48 42 42 81 20 55 49 69 60 10 53 2 21 44 10 18 45 64 21 18 5 62 3 34 52 72 16 28 70 31 93 5 21 69 21 90 31 90 91 79 54 94 77 27 97 4 74 9 29 29 81 5 33 81 75 37 61 73 57 75",
"output": "15"
},
{
"input": "100\n190 544 642 723 577 689 757 509 165 193 396 972 742 367 83 294 404 308 683 399 551 770 564 721 465 839 379 68 687 554 821 719 304 533 146 180 596 713 546 743 949 100 458 735 17 525 568 907 957 670 914 374 347 801 227 884 284 444 686 410 127 508 504 273 624 213 873 658 336 79 819 938 3 722 649 368 733 747 577 746 940 308 970 963 145 487 102 559 790 243 609 77 552 565 151 492 726 448 393 837",
"output": "180"
},
{
"input": "100\n606 358 399 589 724 454 741 183 571 244 984 867 828 232 189 821 642 855 220 839 585 203 135 305 970 503 362 658 491 562 706 62 721 465 560 880 833 646 365 23 679 549 317 834 583 947 134 253 250 768 343 996 541 163 355 925 336 874 997 632 498 529 932 487 415 391 766 224 364 790 486 512 183 458 343 751 633 126 688 536 845 380 423 447 904 779 520 843 977 392 406 147 888 520 886 179 176 129 8 750",
"output": "129"
},
{
"input": "5\n3 2 3 4 2",
"output": "2"
},
{
"input": "5\n4 8 9 10 6",
"output": "4"
},
{
"input": "5\n2 21 6 5 9",
"output": "2"
},
{
"input": "5\n34 39 30 37 35",
"output": "34"
},
{
"input": "5\n14 67 15 28 21",
"output": "14"
},
{
"input": "5\n243 238 138 146 140",
"output": "140"
},
{
"input": "5\n46 123 210 119 195",
"output": "46"
},
{
"input": "5\n725 444 477 661 761",
"output": "477"
},
{
"input": "10\n2 2 3 4 4 1 5 3 1 2",
"output": "2"
},
{
"input": "10\n1 10 1 10 1 1 7 8 6 7",
"output": "1"
},
{
"input": "10\n5 17 8 1 10 20 9 18 12 20",
"output": "5"
},
{
"input": "10\n18 11 23 7 9 10 28 29 46 21",
"output": "9"
},
{
"input": "10\n2 17 53 94 95 57 36 47 68 48",
"output": "2"
},
{
"input": "10\n93 231 176 168 177 222 22 137 110 4",
"output": "4"
},
{
"input": "10\n499 173 45 141 425 276 96 290 428 95",
"output": "95"
},
{
"input": "10\n201 186 897 279 703 376 238 93 253 316",
"output": "201"
},
{
"input": "25\n3 2 3 2 2 2 3 4 5 1 1 4 1 2 1 3 5 5 3 5 1 2 4 1 3",
"output": "1"
},
{
"input": "25\n9 9 1 9 10 5 6 4 6 1 5 2 2 1 2 8 4 6 5 7 1 10 5 4 9",
"output": "2"
},
{
"input": "25\n2 17 21 4 13 6 14 18 17 1 16 13 24 4 12 7 8 16 9 25 25 9 11 20 18",
"output": "2"
},
{
"input": "25\n38 30 9 35 33 48 8 4 49 2 39 19 34 35 47 49 33 4 23 5 42 35 49 11 30",
"output": "8"
},
{
"input": "25\n75 34 77 68 60 38 76 89 35 68 28 36 96 63 43 12 9 4 37 75 88 30 11 58 35",
"output": "9"
},
{
"input": "25\n108 3 144 140 239 105 59 126 224 181 147 102 94 201 68 121 167 94 60 130 64 162 45 95 235",
"output": "94"
},
{
"input": "25\n220 93 216 467 134 408 132 220 292 11 363 404 282 253 141 313 310 356 214 256 380 81 42 128 363",
"output": "81"
},
{
"input": "25\n371 884 75 465 891 510 471 52 382 829 514 610 660 642 179 108 41 818 346 106 738 993 706 574 623",
"output": "108"
},
{
"input": "50\n1 2 1 3 2 5 2 2 2 3 4 4 4 3 3 4 1 2 3 1 5 4 1 2 2 1 5 3 2 2 1 5 4 5 2 5 4 1 1 3 5 2 1 4 5 5 1 5 5 5",
"output": "1"
},
{
"input": "50\n2 4 9 8 1 3 7 1 2 3 8 9 8 8 5 2 10 5 8 1 3 1 8 2 3 7 9 10 2 9 9 7 3 8 6 10 6 5 4 8 1 1 5 6 8 9 5 9 5 3",
"output": "1"
},
{
"input": "50\n22 9 5 3 24 21 25 13 17 21 14 8 22 18 2 3 22 9 10 11 25 22 5 10 16 7 15 3 2 13 2 12 9 24 3 14 2 18 3 22 8 2 19 6 16 4 5 20 10 12",
"output": "3"
},
{
"input": "50\n14 4 20 37 50 46 19 20 25 47 10 6 34 12 41 47 9 22 28 41 34 47 40 12 42 9 4 15 15 27 8 38 9 4 17 8 13 47 7 9 38 30 48 50 7 41 34 23 11 16",
"output": "9"
},
{
"input": "50\n69 9 97 15 22 69 27 7 23 84 73 74 60 94 43 98 13 4 63 49 7 31 93 23 6 75 32 63 49 32 99 43 68 48 16 54 20 38 40 65 34 28 21 55 79 50 2 18 22 95",
"output": "13"
},
{
"input": "50\n50 122 117 195 42 178 153 194 7 89 142 40 158 230 213 104 179 56 244 196 85 159 167 19 157 20 230 201 152 98 250 242 10 52 96 242 139 181 90 107 178 52 196 79 23 61 212 47 97 97",
"output": "50"
},
{
"input": "50\n354 268 292 215 187 232 35 38 179 79 108 491 346 384 345 103 14 260 148 322 459 238 220 493 374 237 474 148 21 221 88 377 289 121 201 198 490 117 382 454 359 390 346 456 294 325 130 306 484 83",
"output": "38"
},
{
"input": "50\n94 634 27 328 629 967 728 177 379 908 801 715 787 192 427 48 559 923 841 6 759 335 251 172 193 593 456 780 647 638 750 881 206 129 278 744 91 49 523 248 286 549 593 451 216 753 471 325 870 16",
"output": "16"
},
{
"input": "100\n5 5 4 3 5 1 2 5 1 1 3 5 4 4 1 1 1 1 5 4 4 5 1 5 5 1 2 1 3 1 5 1 3 3 3 2 2 2 1 1 5 1 3 4 1 1 3 2 5 2 2 5 5 4 4 1 3 4 3 3 4 5 3 3 3 1 2 1 4 2 4 4 1 5 1 3 5 5 5 5 3 4 4 3 1 2 5 2 3 5 4 2 4 5 3 2 4 2 4 3",
"output": "1"
},
{
"input": "100\n3 4 8 10 8 6 4 3 7 7 6 2 3 1 3 10 1 7 9 3 5 5 2 6 2 9 1 7 4 2 4 1 6 1 7 10 2 5 3 7 6 4 6 2 8 8 8 6 6 10 3 7 4 3 4 1 7 9 3 6 3 6 1 4 9 3 8 1 10 1 4 10 7 7 9 5 3 8 10 2 1 10 8 7 10 8 5 3 1 2 1 10 6 1 5 3 3 5 7 2",
"output": "2"
},
{
"input": "100\n14 7 6 21 12 5 22 23 2 9 8 1 9 2 20 2 24 7 14 24 8 19 15 19 10 24 9 4 21 12 3 21 9 16 9 22 18 4 17 19 19 9 6 1 13 15 23 3 14 3 7 15 17 10 7 24 4 18 21 14 25 20 19 19 14 25 24 21 16 10 2 16 1 21 1 24 13 7 13 20 12 20 2 16 3 6 6 2 19 9 16 4 1 2 7 18 15 14 10 22",
"output": "2"
},
{
"input": "100\n2 46 4 6 38 19 15 34 10 35 37 30 3 25 5 45 40 45 33 31 6 20 10 44 11 9 2 14 35 5 9 23 20 2 48 22 25 35 38 31 24 33 35 16 4 30 27 10 12 22 6 24 12 30 23 21 14 12 32 21 7 12 25 43 18 34 34 28 47 13 28 43 18 39 44 42 35 26 35 14 8 29 32 20 29 3 20 6 20 9 9 27 8 42 10 37 42 27 8 1",
"output": "1"
},
{
"input": "100\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": "5"
},
{
"input": "100\n26 171 37 63 189 202 180 210 179 131 43 33 227 5 211 130 105 23 229 48 174 48 182 68 174 146 200 166 246 116 106 86 72 206 216 207 70 148 83 149 94 64 142 8 241 211 27 190 58 116 113 96 210 237 73 240 180 110 34 115 167 4 42 30 162 114 74 131 34 206 174 168 216 101 216 149 212 172 180 220 123 201 25 116 42 143 105 40 30 123 174 220 57 238 145 222 105 184 131 162",
"output": "26"
},
{
"input": "100\n182 9 8 332 494 108 117 203 43 473 451 426 119 408 342 84 88 35 383 84 48 69 31 54 347 363 342 69 422 489 194 16 55 171 71 355 116 142 181 246 275 402 155 282 160 179 240 448 49 101 42 499 434 258 21 327 95 376 38 422 68 381 170 372 427 149 38 48 400 224 246 438 62 43 280 40 108 385 351 379 224 311 66 125 300 41 372 358 5 221 223 341 201 261 455 165 74 379 214 10",
"output": "9"
},
{
"input": "100\n836 969 196 706 812 64 743 262 667 27 227 730 50 510 374 915 124 527 778 528 175 151 439 994 835 87 197 91 121 243 534 634 4 410 936 6 979 227 745 734 492 792 209 95 602 446 299 533 376 595 971 879 36 126 528 759 116 499 571 664 787 820 870 838 604 240 334 872 477 415 57 689 870 690 304 122 487 191 253 610 301 348 358 806 828 911 8 320 414 172 268 867 978 205 812 60 845 395 406 155",
"output": "121"
},
{
"input": "250\n5 3 5 1 3 5 3 4 4 3 1 5 2 2 1 1 5 2 3 3 2 5 4 3 2 4 2 3 5 4 1 2 3 5 2 2 5 4 1 3 3 5 4 4 4 4 4 2 4 2 3 5 1 4 3 3 2 3 5 3 3 4 4 2 3 1 3 4 1 4 5 4 1 2 3 4 1 5 3 3 2 3 5 4 2 5 2 2 3 5 4 3 5 4 2 1 4 1 4 1 1 3 5 1 1 2 1 3 4 5 4 3 2 5 1 3 5 1 1 3 3 5 1 4 5 1 2 1 1 5 5 3 5 1 4 1 4 4 4 4 4 1 4 3 4 5 4 1 2 2 5 2 2 4 2 3 5 3 5 5 3 3 2 2 2 1 1 4 4 4 2 1 4 5 3 1 5 4 4 5 5 5 3 3 5 2 1 4 5 4 1 1 1 5 3 5 2 3 3 2 1 3 4 1 4 1 5 3 1 2 5 5 2 1 4 4 2 3 5 2 4 1 3 4 5 5 4 3 2 2 3 2 4 2 5 3 5 5 1 5 3 2 2 4 2 5 5 5 2 5",
"output": "1"
},
{
"input": "1\n987",
"output": "987"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "2\n1 2",
"output": "1"
},
{
"input": "5\n2 5 5 5 5",
"output": "2"
},
{
"input": "1\n500",
"output": "500"
}
] | 1,663,786,421 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 3 | 62 | 0 |
n=int(input())
a=list(map(int,input().split()))
day_0=a[0]
day_n=a[n-1]
mini_i=0
mini_s=2**31
mini=0
for i in range(1,n-2):
if mini_s>a[i]+a[i+1]:
mini_s=a[i]+a[i+1]
mini=max(mini,a[i],a[i+1])
mini_i=i
mini=min(a[0],mini,a[n-1])
print(mini) | Title: Walking in the Rain
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
In Berland the opposition is going to arrange mass walking on the boulevard. The boulevard consists of *n* tiles that are lain in a row and are numbered from 1 to *n* from right to left. The opposition should start walking on the tile number 1 and the finish on the tile number *n*. During the walk it is allowed to move from right to left between adjacent tiles in a row, and jump over a tile. More formally, if you are standing on the tile number *i* (*i*<=<<=*n*<=-<=1), you can reach the tiles number *i*<=+<=1 or the tile number *i*<=+<=2 from it (if you stand on the tile number *n*<=-<=1, you can only reach tile number *n*). We can assume that all the opposition movements occur instantaneously.
In order to thwart an opposition rally, the Berland bloody regime organized the rain. The tiles on the boulevard are of poor quality and they are rapidly destroyed in the rain. We know that the *i*-th tile is destroyed after *a**i* days of rain (on day *a**i* tile isn't destroyed yet, and on day *a**i*<=+<=1 it is already destroyed). Of course, no one is allowed to walk on the destroyed tiles! So the walk of the opposition is considered thwarted, if either the tile number 1 is broken, or the tile number *n* is broken, or it is impossible to reach the tile number *n* from the tile number 1 if we can walk on undestroyed tiles.
The opposition wants to gather more supporters for their walk. Therefore, the more time they have to pack, the better. Help the opposition to calculate how much time they still have and tell us for how many days the walk from the tile number 1 to the tile number *n* will be possible.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=103) — the boulevard's length in tiles.
The second line contains *n* space-separated integers *a**i* — the number of days after which the *i*-th tile gets destroyed (1<=≤<=*a**i*<=≤<=103).
Output Specification:
Print a single number — the sought number of days.
Demo Input:
['4\n10 3 5 10\n', '5\n10 2 8 3 5\n']
Demo Output:
['5\n', '5\n']
Note:
In the first sample the second tile gets destroyed after day three, and the only path left is 1 → 3 → 4. After day five there is a two-tile gap between the first and the last tile, you can't jump over it.
In the second sample path 1 → 3 → 5 is available up to day five, inclusive. On day six the last tile is destroyed and the walk is thwarted. | ```python
n=int(input())
a=list(map(int,input().split()))
day_0=a[0]
day_n=a[n-1]
mini_i=0
mini_s=2**31
mini=0
for i in range(1,n-2):
if mini_s>a[i]+a[i+1]:
mini_s=a[i]+a[i+1]
mini=max(mini,a[i],a[i+1])
mini_i=i
mini=min(a[0],mini,a[n-1])
print(mini)
``` | 0 | |
300 | A | Array | PROGRAMMING | 1,100 | [
"brute force",
"constructive algorithms",
"implementation"
] | null | null | Vitaly has an array of *n* distinct integers. Vitaly wants to divide this array into three non-empty sets so as the following conditions hold:
1. The product of all numbers in the first set is less than zero (<=<<=0). 1. The product of all numbers in the second set is greater than zero (<=><=0). 1. The product of all numbers in the third set is equal to zero. 1. Each number from the initial array must occur in exactly one set.
Help Vitaly. Divide the given array. | The first line of the input contains integer *n* (3<=≤<=*n*<=≤<=100). The second line contains *n* space-separated distinct integers *a*1,<=*a*2,<=...,<=*a**n* (|*a**i*|<=≤<=103) — the array elements. | In the first line print integer *n*1 (*n*1<=><=0) — the number of elements in the first set. Then print *n*1 numbers — the elements that got to the first set.
In the next line print integer *n*2 (*n*2<=><=0) — the number of elements in the second set. Then print *n*2 numbers — the elements that got to the second set.
In the next line print integer *n*3 (*n*3<=><=0) — the number of elements in the third set. Then print *n*3 numbers — the elements that got to the third set.
The printed sets must meet the described conditions. It is guaranteed that the solution exists. If there are several solutions, you are allowed to print any of them. | [
"3\n-1 2 0\n",
"4\n-1 -2 -3 0\n"
] | [
"1 -1\n1 2\n1 0\n",
"1 -1\n2 -3 -2\n1 0\n"
] | none | 500 | [
{
"input": "3\n-1 2 0",
"output": "1 -1\n1 2\n1 0"
},
{
"input": "4\n-1 -2 -3 0",
"output": "1 -1\n2 -3 -2\n1 0"
},
{
"input": "5\n-1 -2 1 2 0",
"output": "1 -1\n2 1 2\n2 0 -2"
},
{
"input": "100\n-64 -51 -75 -98 74 -26 -1 -8 -99 -76 -53 -80 -43 -22 -100 -62 -34 -5 -65 -81 -18 -91 -92 -16 -23 -95 -9 -19 -44 -46 -79 52 -35 4 -87 -7 -90 -20 -71 -61 -67 -50 -66 -68 -49 -27 -32 -57 -85 -59 -30 -36 -3 -77 86 -25 -94 -56 60 -24 -37 -72 -41 -31 11 -48 28 -38 -42 -39 -33 -70 -84 0 -93 -73 -14 -69 -40 -97 -6 -55 -45 -54 -10 -29 -96 -12 -83 -15 -21 -47 17 -2 -63 -89 88 13 -58 -82",
"output": "89 -64 -51 -75 -98 -26 -1 -8 -99 -76 -53 -80 -43 -22 -100 -62 -34 -5 -65 -81 -18 -91 -92 -16 -23 -95 -9 -19 -44 -46 -79 -35 -87 -7 -90 -20 -71 -61 -67 -50 -66 -68 -49 -27 -32 -57 -85 -59 -30 -36 -3 -77 -25 -94 -56 -24 -37 -72 -41 -31 -48 -38 -42 -39 -33 -70 -84 -93 -73 -14 -69 -40 -97 -6 -55 -45 -54 -10 -29 -96 -12 -83 -15 -21 -47 -2 -63 -89 -58 -82\n10 74 52 4 86 60 11 28 17 88 13\n1 0"
},
{
"input": "100\n3 -66 -17 54 24 -29 76 89 32 -37 93 -16 99 -25 51 78 23 68 -95 59 18 34 -45 77 9 39 -10 19 8 73 -5 60 12 31 0 2 26 40 48 30 52 49 27 4 87 57 85 58 -61 50 83 80 69 67 91 97 -96 11 100 56 82 53 13 -92 -72 70 1 -94 -63 47 21 14 74 7 6 33 55 65 64 -41 81 42 36 28 38 20 43 71 90 -88 22 84 -86 15 75 62 44 35 98 46",
"output": "19 -66 -17 -29 -37 -16 -25 -95 -45 -10 -5 -61 -96 -92 -72 -94 -63 -41 -88 -86\n80 3 54 24 76 89 32 93 99 51 78 23 68 59 18 34 77 9 39 19 8 73 60 12 31 2 26 40 48 30 52 49 27 4 87 57 85 58 50 83 80 69 67 91 97 11 100 56 82 53 13 70 1 47 21 14 74 7 6 33 55 65 64 81 42 36 28 38 20 43 71 90 22 84 15 75 62 44 35 98 46\n1 0"
},
{
"input": "100\n-17 16 -70 32 -60 75 -100 -9 -68 -30 -42 86 -88 -98 -47 -5 58 -14 -94 -73 -80 -51 -66 -85 -53 49 -25 -3 -45 -69 -11 -64 83 74 -65 67 13 -91 81 6 -90 -54 -12 -39 0 -24 -71 -41 -44 57 -93 -20 -92 18 -43 -52 -55 -84 -89 -19 40 -4 -99 -26 -87 -36 -56 -61 -62 37 -95 -28 63 23 35 -82 1 -2 -78 -96 -21 -77 -76 -27 -10 -97 -8 46 -15 -48 -34 -59 -7 -29 50 -33 -72 -79 22 38",
"output": "75 -17 -70 -60 -100 -9 -68 -30 -42 -88 -98 -47 -5 -14 -94 -73 -80 -51 -66 -85 -53 -25 -3 -45 -69 -11 -64 -65 -91 -90 -54 -12 -39 -24 -71 -41 -44 -93 -20 -92 -43 -52 -55 -84 -89 -19 -4 -99 -26 -87 -36 -56 -61 -62 -95 -28 -82 -2 -78 -96 -21 -77 -76 -27 -10 -97 -8 -15 -48 -34 -59 -7 -29 -33 -72 -79\n24 16 32 75 86 58 49 83 74 67 13 81 6 57 18 40 37 63 23 35 1 46 50 22 38\n1 0"
},
{
"input": "100\n-97 -90 61 78 87 -52 -3 65 83 38 30 -60 35 -50 -73 -77 44 -32 -81 17 -67 58 -6 -34 47 -28 71 -45 69 -80 -4 -7 -57 -79 43 -27 -31 29 16 -89 -21 -93 95 -82 74 -5 -70 -20 -18 36 -64 -66 72 53 62 -68 26 15 76 -40 -99 8 59 88 49 -23 9 10 56 -48 -98 0 100 -54 25 94 13 -63 42 39 -1 55 24 -12 75 51 41 84 -96 -85 -2 -92 14 -46 -91 -19 -11 -86 22 -37",
"output": "51 -97 -90 -52 -3 -60 -50 -73 -77 -32 -81 -67 -6 -34 -28 -45 -80 -4 -7 -57 -79 -27 -31 -89 -21 -93 -82 -5 -70 -20 -18 -64 -66 -68 -40 -99 -23 -48 -98 -54 -63 -1 -12 -96 -85 -2 -92 -46 -91 -19 -11 -86\n47 61 78 87 65 83 38 30 35 44 17 58 47 71 69 43 29 16 95 74 36 72 53 62 26 15 76 8 59 88 49 9 10 56 100 25 94 13 42 39 55 24 75 51 41 84 14 22\n2 0 -37"
},
{
"input": "100\n-75 -60 -18 -92 -71 -9 -37 -34 -82 28 -54 93 -83 -76 -58 -88 -17 -97 64 -39 -96 -81 -10 -98 -47 -100 -22 27 14 -33 -19 -99 87 -66 57 -21 -90 -70 -32 -26 24 -77 -74 13 -44 16 -5 -55 -2 -6 -7 -73 -1 -68 -30 -95 -42 69 0 -20 -79 59 -48 -4 -72 -67 -46 62 51 -52 -86 -40 56 -53 85 -35 -8 49 50 65 29 11 -43 -15 -41 -12 -3 -80 -31 -38 -91 -45 -25 78 94 -23 -63 84 89 -61",
"output": "73 -75 -60 -18 -92 -71 -9 -37 -34 -82 -54 -83 -76 -58 -88 -17 -97 -39 -96 -81 -10 -98 -47 -100 -22 -33 -19 -99 -66 -21 -90 -70 -32 -26 -77 -74 -44 -5 -55 -2 -6 -7 -73 -1 -68 -30 -95 -42 -20 -79 -48 -4 -72 -67 -46 -52 -86 -40 -53 -35 -8 -43 -15 -41 -12 -3 -80 -31 -38 -91 -45 -25 -23 -63\n25 28 93 64 27 14 87 57 24 13 16 69 59 62 51 56 85 49 50 65 29 11 78 94 84 89\n2 0 -61"
},
{
"input": "100\n-87 -48 -76 -1 -10 -17 -22 -19 -27 -99 -43 49 38 -20 -45 -64 44 -96 -35 -74 -65 -41 -21 -75 37 -12 -67 0 -3 5 -80 -93 -81 -97 -47 -63 53 -100 95 -79 -83 -90 -32 88 -77 -16 -23 -54 -28 -4 -73 -98 -25 -39 60 -56 -34 -2 -11 -55 -52 -69 -68 -29 -82 -62 -36 -13 -6 -89 8 -72 18 -15 -50 -71 -70 -92 -42 -78 -61 -9 -30 -85 -91 -94 84 -86 -7 -57 -14 40 -33 51 -26 46 59 -31 -58 -66",
"output": "83 -87 -48 -76 -1 -10 -17 -22 -19 -27 -99 -43 -20 -45 -64 -96 -35 -74 -65 -41 -21 -75 -12 -67 -3 -80 -93 -81 -97 -47 -63 -100 -79 -83 -90 -32 -77 -16 -23 -54 -28 -4 -73 -98 -25 -39 -56 -34 -2 -11 -55 -52 -69 -68 -29 -82 -62 -36 -13 -6 -89 -72 -15 -50 -71 -70 -92 -42 -78 -61 -9 -30 -85 -91 -94 -86 -7 -57 -14 -33 -26 -31 -58 -66\n16 49 38 44 37 5 53 95 88 60 8 18 84 40 51 46 59\n1 0"
},
{
"input": "100\n-95 -28 -43 -72 -11 -24 -37 -35 -44 -66 -45 -62 -96 -51 -55 -23 -31 -26 -59 -17 77 -69 -10 -12 -78 -14 -52 -57 -40 -75 4 -98 -6 7 -53 -3 -90 -63 -8 -20 88 -91 -32 -76 -80 -97 -34 -27 -19 0 70 -38 -9 -49 -67 73 -36 2 81 -39 -65 -83 -64 -18 -94 -79 -58 -16 87 -22 -74 -25 -13 -46 -89 -47 5 -15 -54 -99 56 -30 -60 -21 -86 33 -1 -50 -68 -100 -85 -29 92 -48 -61 42 -84 -93 -41 -82",
"output": "85 -95 -28 -43 -72 -11 -24 -37 -35 -44 -66 -45 -62 -96 -51 -55 -23 -31 -26 -59 -17 -69 -10 -12 -78 -14 -52 -57 -40 -75 -98 -6 -53 -3 -90 -63 -8 -20 -91 -32 -76 -80 -97 -34 -27 -19 -38 -9 -49 -67 -36 -39 -65 -83 -64 -18 -94 -79 -58 -16 -22 -74 -25 -13 -46 -89 -47 -15 -54 -99 -30 -60 -21 -86 -1 -50 -68 -100 -85 -29 -48 -61 -84 -93 -41 -82\n14 77 4 7 88 70 73 2 81 87 5 56 33 92 42\n1 0"
},
{
"input": "100\n-12 -41 57 13 83 -36 53 69 -6 86 -75 87 11 -5 -4 -14 -37 -84 70 2 -73 16 31 34 -45 94 -9 26 27 52 -42 46 96 21 32 7 -18 61 66 -51 95 -48 -76 90 80 -40 89 77 78 54 -30 8 88 33 -24 82 -15 19 1 59 44 64 -97 -60 43 56 35 47 39 50 29 28 -17 -67 74 23 85 -68 79 0 65 55 -3 92 -99 72 93 -71 38 -10 -100 -98 81 62 91 -63 -58 49 -20 22",
"output": "35 -12 -41 -36 -6 -75 -5 -4 -14 -37 -84 -73 -45 -9 -42 -18 -51 -48 -76 -40 -30 -24 -15 -97 -60 -17 -67 -68 -3 -99 -71 -10 -100 -98 -63 -58\n63 57 13 83 53 69 86 87 11 70 2 16 31 34 94 26 27 52 46 96 21 32 7 61 66 95 90 80 89 77 78 54 8 88 33 82 19 1 59 44 64 43 56 35 47 39 50 29 28 74 23 85 79 65 55 92 72 93 38 81 62 91 49 22\n2 0 -20"
},
{
"input": "100\n-34 81 85 -96 50 20 54 86 22 10 -19 52 65 44 30 53 63 71 17 98 -92 4 5 -99 89 -23 48 9 7 33 75 2 47 -56 42 70 -68 57 51 83 82 94 91 45 46 25 95 11 -12 62 -31 -87 58 38 67 97 -60 66 73 -28 13 93 29 59 -49 77 37 -43 -27 0 -16 72 15 79 61 78 35 21 3 8 84 1 -32 36 74 -88 26 100 6 14 40 76 18 90 24 69 80 64 55 41",
"output": "19 -34 -96 -19 -92 -99 -23 -56 -68 -12 -31 -87 -60 -28 -49 -43 -27 -16 -32 -88\n80 81 85 50 20 54 86 22 10 52 65 44 30 53 63 71 17 98 4 5 89 48 9 7 33 75 2 47 42 70 57 51 83 82 94 91 45 46 25 95 11 62 58 38 67 97 66 73 13 93 29 59 77 37 72 15 79 61 78 35 21 3 8 84 1 36 74 26 100 6 14 40 76 18 90 24 69 80 64 55 41\n1 0"
},
{
"input": "100\n-1000 -986 -979 -955 -966 -963 -973 -959 -972 -906 -924 -927 -929 -918 -977 -967 -921 -989 -911 -995 -945 -919 -971 -913 -912 -933 -969 -975 -920 -988 -997 -994 -953 -962 -940 -905 -978 -948 -957 -996 0 -976 -949 -931 -903 -985 -923 -993 -944 -909 -938 -946 -934 -992 -904 -980 -954 -943 -917 -968 -991 -956 -902 -942 -999 -998 -908 -928 -930 -914 -922 -936 -960 -937 -939 -926 -965 -925 -951 -910 -907 -970 -990 -984 -964 -987 -916 -947 -982 -950 -974 -915 -932 -958 -981 -941 -961 -983 -952 -935",
"output": "97 -1000 -986 -979 -955 -966 -963 -973 -959 -972 -906 -924 -927 -929 -918 -977 -967 -921 -989 -911 -995 -945 -919 -971 -913 -912 -933 -969 -975 -920 -988 -997 -994 -953 -962 -940 -905 -978 -948 -957 -996 -976 -949 -931 -903 -985 -923 -993 -944 -909 -938 -946 -934 -992 -904 -980 -954 -943 -917 -968 -991 -956 -902 -942 -999 -998 -908 -928 -930 -914 -922 -936 -960 -937 -939 -926 -965 -925 -951 -910 -907 -970 -990 -984 -964 -987 -916 -947 -982 -950 -974 -915 -932 -958 -981 -941 -961 -983\n2 -935 -952\n1 0"
},
{
"input": "99\n-1000 -986 -979 -955 -966 -963 -973 -959 -972 -906 -924 -927 -929 -918 -977 -967 -921 -989 -911 -995 -945 -919 -971 -913 -912 -933 -969 -975 -920 -988 -997 -994 -953 -962 -940 -905 -978 -948 -957 -996 0 -976 -949 -931 -903 -985 -923 -993 -944 -909 -938 -946 -934 -992 -904 -980 -954 -943 -917 -968 -991 -956 -902 -942 -999 -998 -908 -928 -930 -914 -922 -936 -960 -937 -939 -926 -965 -925 -951 -910 -907 -970 -990 -984 -964 -987 -916 -947 -982 -950 -974 -915 -932 -958 -981 -941 -961 -983 -952",
"output": "95 -1000 -986 -979 -955 -966 -963 -973 -959 -972 -906 -924 -927 -929 -918 -977 -967 -921 -989 -911 -995 -945 -919 -971 -913 -912 -933 -969 -975 -920 -988 -997 -994 -953 -962 -940 -905 -978 -948 -957 -996 -976 -949 -931 -903 -985 -923 -993 -944 -909 -938 -946 -934 -992 -904 -980 -954 -943 -917 -968 -991 -956 -902 -942 -999 -998 -908 -928 -930 -914 -922 -936 -960 -937 -939 -926 -965 -925 -951 -910 -907 -970 -990 -984 -964 -987 -916 -947 -982 -950 -974 -915 -932 -958 -981 -941\n2 -952 -983\n2 0 -961"
},
{
"input": "59\n-990 -876 -641 -726 718 -53 803 -954 894 -265 -587 -665 904 349 754 -978 441 794 -768 -428 -569 -476 188 -620 -290 -333 45 705 -201 109 165 446 13 122 714 -562 -15 -86 -960 43 329 578 287 -776 -14 -71 915 886 -259 337 -495 913 -498 -669 -673 818 225 647 0",
"output": "29 -990 -876 -641 -726 -53 -954 -265 -587 -665 -978 -768 -428 -569 -476 -620 -290 -333 -201 -562 -15 -86 -960 -776 -14 -71 -259 -495 -498 -669\n28 718 803 894 904 349 754 441 794 188 45 705 109 165 446 13 122 714 43 329 578 287 915 886 337 913 818 225 647\n2 0 -673"
},
{
"input": "64\n502 885 -631 -906 735 687 642 -29 -696 -165 -524 15 -129 -663 -846 -501 -651 895 -341 -833 -142 33 -847 688 945 -192 -587 -930 603 849 736 676 788 256 863 -509 319 -49 -807 -158 218 -886 -143 -639 118 -156 -291 325 892 -916 -622 -960 -959 -731 -943 436 -535 861 745 589 -159 376 -182 0",
"output": "35 -631 -906 -29 -696 -165 -524 -129 -663 -846 -501 -651 -341 -833 -142 -847 -192 -587 -930 -509 -49 -807 -158 -886 -143 -639 -156 -291 -916 -622 -960 -959 -731 -943 -535 -159\n27 502 885 735 687 642 15 895 33 688 945 603 849 736 676 788 256 863 319 218 118 325 892 436 861 745 589 376\n2 0 -182"
},
{
"input": "5\n-1 -2 -3 -4 0",
"output": "1 -1\n2 -4 -3\n2 0 -2"
},
{
"input": "3\n-101 101 0",
"output": "1 -101\n1 101\n1 0"
},
{
"input": "21\n-100 -200 -300 -400 -500 -600 -700 -800 -900 -1000 0 100 200 300 400 500 600 700 800 900 1000",
"output": "9 -100 -200 -300 -400 -500 -600 -700 -800 -900\n10 100 200 300 400 500 600 700 800 900 1000\n2 0 -1000"
},
{
"input": "4\n0 -1 -2 -3",
"output": "1 -1\n2 -3 -2\n1 0"
}
] | 1,693,850,939 | 2,147,483,647 | Python 3 | OK | TESTS | 20 | 62 | 0 | '''
Welcome to GDB Online.
GDB online is an online compiler and debugger tool for C, C++, Python, Java, PHP, Ruby, Perl,
C#, OCaml, VB, Swift, Pascal, Fortran, Haskell, Objective-C, Assembly, HTML, CSS, JS, SQLite, Prolog.
Code, Compile, Run and Debug online from anywhere in world.
'''
n=int(input())
l=list(map(int,input().split()))
#print(l)
neg=0
a1=[]
a2=[]
a3=[]
pos=0
#s=input()
for i in l:
if(i<0):a1.append(i)
if(i>0):
a2.append(i)
if(i==0):a3.append(i)
if(len(a2)==0):
a2.append(a1.pop())
a2.append(a1.pop())
if(len(a1)%2==0):
a3.append(a1.pop())
print(len(a1),end=" ")
for i in a1:
print(i,end=" ")
print()
print(len(a2),end=" ")
for i in a2:
print(i,end=" ")
print()
print(len(a3),end=" ")
for i in a3:
print(i,end=" ")
print()
| Title: Array
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vitaly has an array of *n* distinct integers. Vitaly wants to divide this array into three non-empty sets so as the following conditions hold:
1. The product of all numbers in the first set is less than zero (<=<<=0). 1. The product of all numbers in the second set is greater than zero (<=><=0). 1. The product of all numbers in the third set is equal to zero. 1. Each number from the initial array must occur in exactly one set.
Help Vitaly. Divide the given array.
Input Specification:
The first line of the input contains integer *n* (3<=≤<=*n*<=≤<=100). The second line contains *n* space-separated distinct integers *a*1,<=*a*2,<=...,<=*a**n* (|*a**i*|<=≤<=103) — the array elements.
Output Specification:
In the first line print integer *n*1 (*n*1<=><=0) — the number of elements in the first set. Then print *n*1 numbers — the elements that got to the first set.
In the next line print integer *n*2 (*n*2<=><=0) — the number of elements in the second set. Then print *n*2 numbers — the elements that got to the second set.
In the next line print integer *n*3 (*n*3<=><=0) — the number of elements in the third set. Then print *n*3 numbers — the elements that got to the third set.
The printed sets must meet the described conditions. It is guaranteed that the solution exists. If there are several solutions, you are allowed to print any of them.
Demo Input:
['3\n-1 2 0\n', '4\n-1 -2 -3 0\n']
Demo Output:
['1 -1\n1 2\n1 0\n', '1 -1\n2 -3 -2\n1 0\n']
Note:
none | ```python
'''
Welcome to GDB Online.
GDB online is an online compiler and debugger tool for C, C++, Python, Java, PHP, Ruby, Perl,
C#, OCaml, VB, Swift, Pascal, Fortran, Haskell, Objective-C, Assembly, HTML, CSS, JS, SQLite, Prolog.
Code, Compile, Run and Debug online from anywhere in world.
'''
n=int(input())
l=list(map(int,input().split()))
#print(l)
neg=0
a1=[]
a2=[]
a3=[]
pos=0
#s=input()
for i in l:
if(i<0):a1.append(i)
if(i>0):
a2.append(i)
if(i==0):a3.append(i)
if(len(a2)==0):
a2.append(a1.pop())
a2.append(a1.pop())
if(len(a1)%2==0):
a3.append(a1.pop())
print(len(a1),end=" ")
for i in a1:
print(i,end=" ")
print()
print(len(a2),end=" ")
for i in a2:
print(i,end=" ")
print()
print(len(a3),end=" ")
for i in a3:
print(i,end=" ")
print()
``` | 3 | |
570 | B | Simple Game | PROGRAMMING | 1,300 | [
"constructive algorithms",
"games",
"greedy",
"implementation",
"math"
] | null | null | One day Misha and Andrew were playing a very simple game. First, each player chooses an integer in the range from 1 to *n*. Let's assume that Misha chose number *m*, and Andrew chose number *a*.
Then, by using a random generator they choose a random integer *c* in the range between 1 and *n* (any integer from 1 to *n* is chosen with the same probability), after which the winner is the player, whose number was closer to *c*. The boys agreed that if *m* and *a* are located on the same distance from *c*, Misha wins.
Andrew wants to win very much, so he asks you to help him. You know the number selected by Misha, and number *n*. You need to determine which value of *a* Andrew must choose, so that the probability of his victory is the highest possible.
More formally, you need to find such integer *a* (1<=≤<=*a*<=≤<=*n*), that the probability that is maximal, where *c* is the equiprobably chosen integer from 1 to *n* (inclusive). | The first line contains two integers *n* and *m* (1<=≤<=*m*<=≤<=*n*<=≤<=109) — the range of numbers in the game, and the number selected by Misha respectively. | Print a single number — such value *a*, that probability that Andrew wins is the highest. If there are multiple such values, print the minimum of them. | [
"3 1\n",
"4 3\n"
] | [
"2",
"2"
] | In the first sample test: Andrew wins if *c* is equal to 2 or 3. The probability that Andrew wins is 2 / 3. If Andrew chooses *a* = 3, the probability of winning will be 1 / 3. If *a* = 1, the probability of winning is 0.
In the second sample test: Andrew wins if *c* is equal to 1 and 2. The probability that Andrew wins is 1 / 2. For other choices of *a* the probability of winning is less. | 1,000 | [
{
"input": "3 1",
"output": "2"
},
{
"input": "4 3",
"output": "2"
},
{
"input": "5 5",
"output": "4"
},
{
"input": "10 5",
"output": "6"
},
{
"input": "20 13",
"output": "12"
},
{
"input": "51 1",
"output": "2"
},
{
"input": "100 50",
"output": "51"
},
{
"input": "100 51",
"output": "50"
},
{
"input": "100 49",
"output": "50"
},
{
"input": "1000000000 1000000000",
"output": "999999999"
},
{
"input": "1000000000 1",
"output": "2"
},
{
"input": "1000000000 100000000",
"output": "100000001"
},
{
"input": "1000000000 500000000",
"output": "500000001"
},
{
"input": "1000000000 123124",
"output": "123125"
},
{
"input": "12412523 125123",
"output": "125124"
},
{
"input": "54645723 432423",
"output": "432424"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "262833325 131416663",
"output": "131416662"
},
{
"input": "477667530 238833766",
"output": "238833765"
},
{
"input": "692501734 346250868",
"output": "346250867"
},
{
"input": "907335939 453667970",
"output": "453667969"
},
{
"input": "746085224 373042613",
"output": "373042612"
},
{
"input": "189520699 94760350",
"output": "94760349"
},
{
"input": "404354904 202177453",
"output": "202177452"
},
{
"input": "619189108 309594555",
"output": "309594554"
},
{
"input": "81813292 40906647",
"output": "40906646"
},
{
"input": "296647497 148323750",
"output": "148323749"
},
{
"input": "511481701 255740851",
"output": "255740850"
},
{
"input": "726315905 363157953",
"output": "363157952"
},
{
"input": "496110970 201868357",
"output": "201868358"
},
{
"input": "710945175 173165570",
"output": "173165571"
},
{
"input": "925779379 720443954",
"output": "720443953"
},
{
"input": "140613583 93171580",
"output": "93171579"
},
{
"input": "355447788 85890184",
"output": "85890185"
},
{
"input": "570281992 291648263",
"output": "291648262"
},
{
"input": "541904957 459371829",
"output": "459371828"
},
{
"input": "756739161 125332525",
"output": "125332526"
},
{
"input": "971573366 216791157",
"output": "216791158"
},
{
"input": "186407570 160453970",
"output": "160453969"
},
{
"input": "401241775 170032078",
"output": "170032079"
},
{
"input": "616075979 207073797",
"output": "207073798"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "2 1",
"output": "2"
},
{
"input": "2 2",
"output": "1"
},
{
"input": "3 1",
"output": "2"
},
{
"input": "3 2",
"output": "1"
},
{
"input": "3 3",
"output": "2"
},
{
"input": "4 1",
"output": "2"
},
{
"input": "4 2",
"output": "3"
},
{
"input": "4 3",
"output": "2"
},
{
"input": "4 4",
"output": "3"
},
{
"input": "5 1",
"output": "2"
},
{
"input": "5 2",
"output": "3"
},
{
"input": "5 3",
"output": "2"
},
{
"input": "5 4",
"output": "3"
},
{
"input": "5 5",
"output": "4"
},
{
"input": "3 2",
"output": "1"
},
{
"input": "7 4",
"output": "3"
},
{
"input": "2 2",
"output": "1"
},
{
"input": "7 3",
"output": "4"
}
] | 1,627,385,036 | 2,147,483,647 | Python 3 | OK | TESTS | 60 | 77 | 6,758,400 | n, m = map(int,input().split())
print( 1 if n==1 else (m+(-1 if m-1 >= n-m else +1)) ) | Title: Simple Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day Misha and Andrew were playing a very simple game. First, each player chooses an integer in the range from 1 to *n*. Let's assume that Misha chose number *m*, and Andrew chose number *a*.
Then, by using a random generator they choose a random integer *c* in the range between 1 and *n* (any integer from 1 to *n* is chosen with the same probability), after which the winner is the player, whose number was closer to *c*. The boys agreed that if *m* and *a* are located on the same distance from *c*, Misha wins.
Andrew wants to win very much, so he asks you to help him. You know the number selected by Misha, and number *n*. You need to determine which value of *a* Andrew must choose, so that the probability of his victory is the highest possible.
More formally, you need to find such integer *a* (1<=≤<=*a*<=≤<=*n*), that the probability that is maximal, where *c* is the equiprobably chosen integer from 1 to *n* (inclusive).
Input Specification:
The first line contains two integers *n* and *m* (1<=≤<=*m*<=≤<=*n*<=≤<=109) — the range of numbers in the game, and the number selected by Misha respectively.
Output Specification:
Print a single number — such value *a*, that probability that Andrew wins is the highest. If there are multiple such values, print the minimum of them.
Demo Input:
['3 1\n', '4 3\n']
Demo Output:
['2', '2']
Note:
In the first sample test: Andrew wins if *c* is equal to 2 or 3. The probability that Andrew wins is 2 / 3. If Andrew chooses *a* = 3, the probability of winning will be 1 / 3. If *a* = 1, the probability of winning is 0.
In the second sample test: Andrew wins if *c* is equal to 1 and 2. The probability that Andrew wins is 1 / 2. For other choices of *a* the probability of winning is less. | ```python
n, m = map(int,input().split())
print( 1 if n==1 else (m+(-1 if m-1 >= n-m else +1)) )
``` | 3 | |
165 | B | Burning Midnight Oil | PROGRAMMING | 1,500 | [
"binary search",
"implementation"
] | null | null | One day a highly important task was commissioned to Vasya — writing a program in a night. The program consists of *n* lines of code. Vasya is already exhausted, so he works like that: first he writes *v* lines of code, drinks a cup of tea, then he writes as much as lines, drinks another cup of tea, then he writes lines and so on: , , , ...
The expression is regarded as the integral part from dividing number *a* by number *b*.
The moment the current value equals 0, Vasya immediately falls asleep and he wakes up only in the morning, when the program should already be finished.
Vasya is wondering, what minimum allowable value *v* can take to let him write not less than *n* lines of code before he falls asleep. | The input consists of two integers *n* and *k*, separated by spaces — the size of the program in lines and the productivity reduction coefficient, 1<=≤<=*n*<=≤<=109, 2<=≤<=*k*<=≤<=10. | Print the only integer — the minimum value of *v* that lets Vasya write the program in one night. | [
"7 2\n",
"59 9\n"
] | [
"4\n",
"54\n"
] | In the first sample the answer is *v* = 4. Vasya writes the code in the following portions: first 4 lines, then 2, then 1, and then Vasya falls asleep. Thus, he manages to write 4 + 2 + 1 = 7 lines in a night and complete the task.
In the second sample the answer is *v* = 54. Vasya writes the code in the following portions: 54, 6. The total sum is 54 + 6 = 60, that's even more than *n* = 59. | 1,000 | [
{
"input": "7 2",
"output": "4"
},
{
"input": "59 9",
"output": "54"
},
{
"input": "1 9",
"output": "1"
},
{
"input": "11 2",
"output": "7"
},
{
"input": "747 2",
"output": "376"
},
{
"input": "6578 2",
"output": "3293"
},
{
"input": "37212 2",
"output": "18609"
},
{
"input": "12357 2",
"output": "6181"
},
{
"input": "7998332 2",
"output": "3999172"
},
{
"input": "86275251 2",
"output": "43137632"
},
{
"input": "75584551 2",
"output": "37792280"
},
{
"input": "6 3",
"output": "5"
},
{
"input": "43 4",
"output": "33"
},
{
"input": "811 3",
"output": "543"
},
{
"input": "3410 4",
"output": "2560"
},
{
"input": "21341 4",
"output": "16009"
},
{
"input": "696485 4",
"output": "522368"
},
{
"input": "8856748 3",
"output": "5904504"
},
{
"input": "2959379 4",
"output": "2219538"
},
{
"input": "831410263 3",
"output": "554273516"
},
{
"input": "2 5",
"output": "2"
},
{
"input": "19 6",
"output": "17"
},
{
"input": "715 7",
"output": "615"
},
{
"input": "9122 5",
"output": "7300"
},
{
"input": "89117 6",
"output": "74268"
},
{
"input": "689973 7",
"output": "591408"
},
{
"input": "3024524 5",
"output": "2419624"
},
{
"input": "67127156 6",
"output": "55939302"
},
{
"input": "412262167 7",
"output": "353367574"
},
{
"input": "6 8",
"output": "6"
},
{
"input": "59 9",
"output": "54"
},
{
"input": "246 10",
"output": "222"
},
{
"input": "5314 8",
"output": "4651"
},
{
"input": "15309 9",
"output": "13609"
},
{
"input": "35648 10",
"output": "32085"
},
{
"input": "3018012 8",
"output": "2640764"
},
{
"input": "92153348 9",
"output": "81914089"
},
{
"input": "177583558 10",
"output": "159825206"
},
{
"input": "1000000000 2",
"output": "500000008"
},
{
"input": "1000000000 3",
"output": "666666672"
},
{
"input": "1000000000 4",
"output": "750000005"
},
{
"input": "1000000000 5",
"output": "800000003"
},
{
"input": "1000000000 6",
"output": "833333338"
},
{
"input": "1000000000 7",
"output": "857142861"
},
{
"input": "1000000000 8",
"output": "875000004"
},
{
"input": "1000000000 9",
"output": "888888894"
},
{
"input": "1000000000 10",
"output": "900000001"
},
{
"input": "1 4",
"output": "1"
},
{
"input": "2 10",
"output": "2"
},
{
"input": "1 2",
"output": "1"
},
{
"input": "6 8",
"output": "6"
},
{
"input": "987862820 9",
"output": "878100288"
},
{
"input": "979591791 9",
"output": "870748262"
},
{
"input": "948889213 9",
"output": "843457081"
},
{
"input": "8 9",
"output": "8"
},
{
"input": "999999999 10",
"output": "900000000"
}
] | 1,685,218,998 | 2,147,483,647 | PyPy 3-64 | OK | TESTS | 56 | 124 | 1,843,200 | import math
n, k = map(int, input().split())
def finished(v):
if v == 0:
return False
total = 0
p = 0
cur_sum = math.floor(v / math.pow(k, p))
while cur_sum > 0:
total += cur_sum
p += 1
cur_sum = math.floor(v / math.pow(k, p))
return total >= n
low = 1
high = n
while low <= high:
mid = (low + high) // 2
if finished(mid) and not finished(mid - 1):
print(mid)
break
elif finished(mid):
high = mid - 1
else:
low = mid + 1
| Title: Burning Midnight Oil
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day a highly important task was commissioned to Vasya — writing a program in a night. The program consists of *n* lines of code. Vasya is already exhausted, so he works like that: first he writes *v* lines of code, drinks a cup of tea, then he writes as much as lines, drinks another cup of tea, then he writes lines and so on: , , , ...
The expression is regarded as the integral part from dividing number *a* by number *b*.
The moment the current value equals 0, Vasya immediately falls asleep and he wakes up only in the morning, when the program should already be finished.
Vasya is wondering, what minimum allowable value *v* can take to let him write not less than *n* lines of code before he falls asleep.
Input Specification:
The input consists of two integers *n* and *k*, separated by spaces — the size of the program in lines and the productivity reduction coefficient, 1<=≤<=*n*<=≤<=109, 2<=≤<=*k*<=≤<=10.
Output Specification:
Print the only integer — the minimum value of *v* that lets Vasya write the program in one night.
Demo Input:
['7 2\n', '59 9\n']
Demo Output:
['4\n', '54\n']
Note:
In the first sample the answer is *v* = 4. Vasya writes the code in the following portions: first 4 lines, then 2, then 1, and then Vasya falls asleep. Thus, he manages to write 4 + 2 + 1 = 7 lines in a night and complete the task.
In the second sample the answer is *v* = 54. Vasya writes the code in the following portions: 54, 6. The total sum is 54 + 6 = 60, that's even more than *n* = 59. | ```python
import math
n, k = map(int, input().split())
def finished(v):
if v == 0:
return False
total = 0
p = 0
cur_sum = math.floor(v / math.pow(k, p))
while cur_sum > 0:
total += cur_sum
p += 1
cur_sum = math.floor(v / math.pow(k, p))
return total >= n
low = 1
high = n
while low <= high:
mid = (low + high) // 2
if finished(mid) and not finished(mid - 1):
print(mid)
break
elif finished(mid):
high = mid - 1
else:
low = mid + 1
``` | 3 | |
983 | B | XOR-pyramid | PROGRAMMING | 1,800 | [
"dp"
] | null | null | For an array $b$ of length $m$ we define the function $f$ as
where $\oplus$ is [bitwise exclusive OR](https://en.wikipedia.org/wiki/Bitwise_operation#XOR).
For example, $f(1,2,4,8)=f(1\oplus2,2\oplus4,4\oplus8)=f(3,6,12)=f(3\oplus6,6\oplus12)=f(5,10)=f(5\oplus10)=f(15)=15$
You are given an array $a$ and a few queries. Each query is represented as two integers $l$ and $r$. The answer is the maximum value of $f$ on all continuous subsegments of the array $a_l, a_{l+1}, \ldots, a_r$. | The first line contains a single integer $n$ ($1 \le n \le 5000$) — the length of $a$.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($0 \le a_i \le 2^{30}-1$) — the elements of the array.
The third line contains a single integer $q$ ($1 \le q \le 100\,000$) — the number of queries.
Each of the next $q$ lines contains a query represented as two integers $l$, $r$ ($1 \le l \le r \le n$). | Print $q$ lines — the answers for the queries. | [
"3\n8 4 1\n2\n2 3\n1 2\n",
"6\n1 2 4 8 16 32\n4\n1 6\n2 5\n3 4\n1 2\n"
] | [
"5\n12\n",
"60\n30\n12\n3\n"
] | In first sample in both queries the maximum value of the function is reached on the subsegment that is equal to the whole segment.
In second sample, optimal segment for first query are $[3,6]$, for second query — $[2,5]$, for third — $[3,4]$, for fourth — $[1,2]$. | 1,000 | [
{
"input": "3\n8 4 1\n2\n2 3\n1 2",
"output": "5\n12"
},
{
"input": "6\n1 2 4 8 16 32\n4\n1 6\n2 5\n3 4\n1 2",
"output": "60\n30\n12\n3"
}
] | 1,670,797,210 | 2,147,483,647 | PyPy 3-64 | RUNTIME_ERROR | TESTS | 15 | 280 | 36,761,600 | import sys
import math
from heapq import *
from bisect import *
from itertools import *
from functools import *
from collections import *
def read(fn=int):
return map(fn, input().split())
n, = read()
a = [*read()]
# g = [[0] * n for _ in range(n)]
# for i in range(n):
# for j in range(i,n):
# if not i:
# g[i][j] = (l[j],l[j])
# else:
# v = g[i-1][j-1][0] ^ g[i-1][j][0]
# m = max(v, g[i-1][j-1][1], g[i-1][j][1])
# g[i][j] = (v,m)
@cache
def f(i,j):
if i == 0:
return a[j],a[j]
l = f(i-1,j-1)
r = f(i-1,j)
v = l[0] ^ r[0]
m = max(v, l[1], r[1])
return v,m
q, = read()
for _ in range(q):
l,r = read()
l -= 1
r -= 1
print(f(r-l,r)[1])
# print(g[r-l][r][1]) | Title: XOR-pyramid
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
For an array $b$ of length $m$ we define the function $f$ as
where $\oplus$ is [bitwise exclusive OR](https://en.wikipedia.org/wiki/Bitwise_operation#XOR).
For example, $f(1,2,4,8)=f(1\oplus2,2\oplus4,4\oplus8)=f(3,6,12)=f(3\oplus6,6\oplus12)=f(5,10)=f(5\oplus10)=f(15)=15$
You are given an array $a$ and a few queries. Each query is represented as two integers $l$ and $r$. The answer is the maximum value of $f$ on all continuous subsegments of the array $a_l, a_{l+1}, \ldots, a_r$.
Input Specification:
The first line contains a single integer $n$ ($1 \le n \le 5000$) — the length of $a$.
The second line contains $n$ integers $a_1, a_2, \dots, a_n$ ($0 \le a_i \le 2^{30}-1$) — the elements of the array.
The third line contains a single integer $q$ ($1 \le q \le 100\,000$) — the number of queries.
Each of the next $q$ lines contains a query represented as two integers $l$, $r$ ($1 \le l \le r \le n$).
Output Specification:
Print $q$ lines — the answers for the queries.
Demo Input:
['3\n8 4 1\n2\n2 3\n1 2\n', '6\n1 2 4 8 16 32\n4\n1 6\n2 5\n3 4\n1 2\n']
Demo Output:
['5\n12\n', '60\n30\n12\n3\n']
Note:
In first sample in both queries the maximum value of the function is reached on the subsegment that is equal to the whole segment.
In second sample, optimal segment for first query are $[3,6]$, for second query — $[2,5]$, for third — $[3,4]$, for fourth — $[1,2]$. | ```python
import sys
import math
from heapq import *
from bisect import *
from itertools import *
from functools import *
from collections import *
def read(fn=int):
return map(fn, input().split())
n, = read()
a = [*read()]
# g = [[0] * n for _ in range(n)]
# for i in range(n):
# for j in range(i,n):
# if not i:
# g[i][j] = (l[j],l[j])
# else:
# v = g[i-1][j-1][0] ^ g[i-1][j][0]
# m = max(v, g[i-1][j-1][1], g[i-1][j][1])
# g[i][j] = (v,m)
@cache
def f(i,j):
if i == 0:
return a[j],a[j]
l = f(i-1,j-1)
r = f(i-1,j)
v = l[0] ^ r[0]
m = max(v, l[1], r[1])
return v,m
q, = read()
for _ in range(q):
l,r = read()
l -= 1
r -= 1
print(f(r-l,r)[1])
# print(g[r-l][r][1])
``` | -1 | |
705 | A | Hulk | PROGRAMMING | 800 | [
"implementation"
] | null | null | Dr. Bruce Banner hates his enemies (like others don't). As we all know, he can barely talk when he turns into the incredible Hulk. That's why he asked you to help him to express his feelings.
Hulk likes the Inception so much, and like that his feelings are complicated. They have *n* layers. The first layer is hate, second one is love, third one is hate and so on...
For example if *n*<==<=1, then his feeling is "I hate it" or if *n*<==<=2 it's "I hate that I love it", and if *n*<==<=3 it's "I hate that I love that I hate it" and so on.
Please help Dr. Banner. | The only line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100) — the number of layers of love and hate. | Print Dr.Banner's feeling in one line. | [
"1\n",
"2\n",
"3\n"
] | [
"I hate it\n",
"I hate that I love it\n",
"I hate that I love that I hate it\n"
] | none | 500 | [
{
"input": "1",
"output": "I hate it"
},
{
"input": "2",
"output": "I hate that I love it"
},
{
"input": "3",
"output": "I hate that I love that I hate it"
},
{
"input": "4",
"output": "I hate that I love that I hate that I love it"
},
{
"input": "5",
"output": "I hate that I love that I hate that I love that I hate it"
},
{
"input": "10",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love it"
},
{
"input": "18",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love it"
},
{
"input": "19",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate it"
},
{
"input": "76",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "77",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "81",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "82",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "85",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "86",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "100",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "99",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "98",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "33",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate it"
},
{
"input": "34",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love it"
},
{
"input": "57",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
},
{
"input": "100",
"output": "I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate that I love that I hate ..."
}
] | 1,688,714,065 | 2,147,483,647 | Python 3 | OK | TESTS | 21 | 31 | 0 | l = int(input())
if l == 1:
st = "I hate it"
else:
st = "I hate that"
for i in range(1,l):
if (i+1)%2==0:
if (i)==l-1:
st+=" I love it"
else:
st+=" I love that"
else:
if i==l-1:
st+=" I hate it"
else:
st+=" I hate that"
print(st) | Title: Hulk
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Dr. Bruce Banner hates his enemies (like others don't). As we all know, he can barely talk when he turns into the incredible Hulk. That's why he asked you to help him to express his feelings.
Hulk likes the Inception so much, and like that his feelings are complicated. They have *n* layers. The first layer is hate, second one is love, third one is hate and so on...
For example if *n*<==<=1, then his feeling is "I hate it" or if *n*<==<=2 it's "I hate that I love it", and if *n*<==<=3 it's "I hate that I love that I hate it" and so on.
Please help Dr. Banner.
Input Specification:
The only line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100) — the number of layers of love and hate.
Output Specification:
Print Dr.Banner's feeling in one line.
Demo Input:
['1\n', '2\n', '3\n']
Demo Output:
['I hate it\n', 'I hate that I love it\n', 'I hate that I love that I hate it\n']
Note:
none | ```python
l = int(input())
if l == 1:
st = "I hate it"
else:
st = "I hate that"
for i in range(1,l):
if (i+1)%2==0:
if (i)==l-1:
st+=" I love it"
else:
st+=" I love that"
else:
if i==l-1:
st+=" I hate it"
else:
st+=" I hate that"
print(st)
``` | 3 | |
353 | A | Domino | PROGRAMMING | 1,200 | [
"implementation",
"math"
] | null | null | Valera has got *n* domino pieces in a row. Each piece consists of two halves — the upper one and the lower one. Each of the halves contains a number from 1 to 6. Valera loves even integers very much, so he wants the sum of the numbers on the upper halves and the sum of the numbers on the lower halves to be even.
To do that, Valera can rotate the dominoes by 180 degrees. After the rotation the upper and the lower halves swap places. This action takes one second. Help Valera find out the minimum time he must spend rotating dominoes to make his wish come true. | The first line contains integer *n* (1<=≤<=*n*<=≤<=100), denoting the number of dominoes Valera has. Next *n* lines contain two space-separated integers *x**i*,<=*y**i* (1<=≤<=*x**i*,<=*y**i*<=≤<=6). Number *x**i* is initially written on the upper half of the *i*-th domino, *y**i* is initially written on the lower half. | Print a single number — the minimum required number of seconds. If Valera can't do the task in any time, print <=-<=1. | [
"2\n4 2\n6 4\n",
"1\n2 3\n",
"3\n1 4\n2 3\n4 4\n"
] | [
"0\n",
"-1\n",
"1\n"
] | In the first test case the sum of the numbers on the upper halves equals 10 and the sum of the numbers on the lower halves equals 6. Both numbers are even, so Valera doesn't required to do anything.
In the second sample Valera has only one piece of domino. It is written 3 on the one of its halves, therefore one of the sums will always be odd.
In the third case Valera can rotate the first piece, and after that the sum on the upper halves will be equal to 10, and the sum on the lower halves will be equal to 8. | 500 | [
{
"input": "2\n4 2\n6 4",
"output": "0"
},
{
"input": "1\n2 3",
"output": "-1"
},
{
"input": "3\n1 4\n2 3\n4 4",
"output": "1"
},
{
"input": "5\n5 4\n5 4\n1 5\n5 5\n3 3",
"output": "1"
},
{
"input": "20\n1 3\n5 2\n5 2\n2 6\n2 4\n1 1\n1 3\n1 4\n2 6\n4 2\n5 6\n2 2\n6 2\n4 3\n2 1\n6 2\n6 5\n4 5\n2 4\n1 4",
"output": "-1"
},
{
"input": "100\n2 3\n2 4\n3 3\n1 4\n5 2\n5 4\n6 6\n3 4\n1 1\n4 2\n5 1\n5 5\n5 3\n3 6\n4 1\n1 6\n1 1\n3 2\n4 5\n6 1\n6 4\n1 1\n3 4\n3 3\n2 2\n1 1\n4 4\n6 4\n3 2\n5 2\n6 4\n3 2\n3 5\n4 4\n1 4\n5 2\n3 4\n1 4\n2 2\n5 6\n3 5\n6 1\n5 5\n1 6\n6 3\n1 4\n1 5\n5 5\n4 1\n3 2\n4 1\n5 5\n5 5\n1 5\n1 2\n6 4\n1 3\n3 6\n4 3\n3 5\n6 4\n2 6\n5 5\n1 4\n2 2\n2 3\n5 1\n2 5\n1 2\n2 6\n5 5\n4 6\n1 4\n3 6\n2 3\n6 1\n6 5\n3 2\n6 4\n4 5\n4 5\n2 6\n1 3\n6 2\n1 2\n2 3\n4 3\n5 4\n3 4\n1 6\n6 6\n2 4\n4 1\n3 1\n2 6\n5 4\n1 2\n6 5\n3 6\n2 4",
"output": "-1"
},
{
"input": "1\n2 4",
"output": "0"
},
{
"input": "1\n1 1",
"output": "-1"
},
{
"input": "1\n1 2",
"output": "-1"
},
{
"input": "2\n1 1\n3 3",
"output": "0"
},
{
"input": "2\n1 1\n2 2",
"output": "-1"
},
{
"input": "2\n1 1\n1 2",
"output": "-1"
},
{
"input": "5\n1 2\n6 6\n1 1\n3 3\n6 1",
"output": "1"
},
{
"input": "5\n5 4\n2 6\n6 2\n1 4\n6 2",
"output": "0"
},
{
"input": "10\n4 1\n3 2\n1 2\n2 6\n3 5\n2 1\n5 2\n4 6\n5 6\n3 1",
"output": "0"
},
{
"input": "10\n6 1\n4 4\n2 6\n6 5\n3 6\n6 3\n2 4\n5 1\n1 6\n1 5",
"output": "-1"
},
{
"input": "15\n1 2\n5 1\n6 4\n5 1\n1 6\n2 6\n3 1\n6 4\n3 1\n2 1\n6 4\n3 5\n6 2\n1 6\n1 1",
"output": "1"
},
{
"input": "15\n3 3\n2 1\n5 4\n3 3\n5 3\n5 4\n2 5\n1 3\n3 2\n3 3\n3 5\n2 5\n4 1\n2 3\n5 4",
"output": "-1"
},
{
"input": "20\n1 5\n6 4\n4 3\n6 2\n1 1\n1 5\n6 3\n2 3\n3 6\n3 6\n3 6\n2 5\n4 3\n4 6\n5 5\n4 6\n3 4\n4 2\n3 3\n5 2",
"output": "0"
},
{
"input": "20\n2 1\n6 5\n3 1\n2 5\n3 5\n4 1\n1 1\n5 4\n5 1\n2 4\n1 5\n3 2\n1 2\n3 5\n5 2\n1 2\n1 3\n4 2\n2 3\n4 5",
"output": "-1"
},
{
"input": "25\n4 1\n6 3\n1 3\n2 3\n2 4\n6 6\n4 2\n4 2\n1 5\n5 4\n1 2\n2 5\n3 6\n4 1\n3 4\n2 6\n6 1\n5 6\n6 6\n4 2\n1 5\n3 3\n3 3\n6 5\n1 4",
"output": "-1"
},
{
"input": "25\n5 5\n4 3\n2 5\n4 3\n4 6\n4 2\n5 6\n2 1\n5 4\n6 6\n1 3\n1 4\n2 3\n5 6\n5 4\n5 6\n5 4\n6 3\n3 5\n1 3\n2 5\n2 2\n4 4\n2 1\n4 4",
"output": "-1"
},
{
"input": "30\n3 5\n2 5\n1 6\n1 6\n2 4\n5 5\n5 4\n5 6\n5 4\n2 1\n2 4\n1 6\n3 5\n1 1\n3 6\n5 5\n1 6\n3 4\n1 4\n4 6\n2 1\n3 3\n1 3\n4 5\n1 4\n1 6\n2 1\n4 6\n3 5\n5 6",
"output": "1"
},
{
"input": "30\n2 3\n3 1\n6 6\n1 3\n5 5\n3 6\n4 5\n2 1\n1 3\n2 3\n4 4\n2 4\n6 4\n2 4\n5 4\n2 1\n2 5\n2 5\n4 2\n1 4\n2 6\n3 2\n3 2\n6 6\n4 2\n3 4\n6 3\n6 6\n6 6\n5 5",
"output": "1"
},
{
"input": "35\n6 1\n4 3\n1 2\n4 3\n6 4\n4 6\n3 1\n5 5\n3 4\n5 4\n4 6\n1 6\n2 4\n6 6\n5 4\n5 2\n1 3\n1 4\n3 5\n1 4\n2 3\n4 5\n4 3\n6 1\n5 3\n3 2\n5 6\n3 5\n6 5\n4 1\n1 3\n5 5\n4 6\n6 1\n1 3",
"output": "1"
},
{
"input": "35\n4 3\n5 6\n4 5\n2 5\n6 6\n4 1\n2 2\n4 2\n3 4\n4 1\n6 6\n6 3\n1 5\n1 5\n5 6\n4 2\n4 6\n5 5\n2 2\n5 2\n1 2\n4 6\n6 6\n6 5\n2 1\n3 5\n2 5\n3 1\n5 3\n6 4\n4 6\n5 6\n5 1\n3 4\n3 5",
"output": "1"
},
{
"input": "40\n5 6\n1 1\n3 3\n2 6\n6 6\n5 4\n6 4\n3 5\n1 3\n4 4\n4 4\n2 5\n1 3\n3 6\n5 2\n4 3\n4 4\n5 6\n2 3\n1 1\n3 1\n1 1\n1 5\n4 3\n5 5\n3 4\n6 6\n5 6\n2 2\n6 6\n2 1\n2 4\n5 2\n2 2\n1 1\n1 4\n4 2\n3 5\n5 5\n4 5",
"output": "-1"
},
{
"input": "40\n3 2\n5 3\n4 6\n3 5\n6 1\n5 2\n1 2\n6 2\n5 3\n3 2\n4 4\n3 3\n5 2\n4 5\n1 4\n5 1\n3 3\n1 3\n1 3\n2 1\n3 6\n4 2\n4 6\n6 2\n2 5\n2 2\n2 5\n3 3\n5 3\n2 1\n3 2\n2 3\n6 3\n6 3\n3 4\n3 2\n4 3\n5 4\n2 4\n4 6",
"output": "-1"
},
{
"input": "45\n2 4\n3 4\n6 1\n5 5\n1 1\n3 5\n4 3\n5 2\n3 6\n6 1\n4 4\n6 1\n2 1\n6 1\n3 6\n3 3\n6 1\n1 2\n1 5\n6 5\n1 3\n5 6\n6 1\n4 5\n3 6\n2 2\n1 2\n4 5\n5 6\n1 5\n6 2\n2 4\n3 3\n3 1\n6 5\n6 5\n2 1\n5 2\n2 1\n3 3\n2 2\n1 4\n2 2\n3 3\n2 1",
"output": "-1"
},
{
"input": "45\n6 6\n1 6\n1 2\n3 5\n4 4\n2 1\n5 3\n2 1\n5 2\n5 3\n1 4\n5 2\n4 2\n3 6\n5 2\n1 5\n4 4\n5 5\n6 5\n2 1\n2 6\n5 5\n2 1\n6 1\n1 6\n6 5\n2 4\n4 3\n2 6\n2 4\n6 5\n6 4\n6 3\n6 6\n2 1\n6 4\n5 6\n5 4\n1 5\n5 1\n3 3\n5 6\n2 5\n4 5\n3 6",
"output": "-1"
},
{
"input": "50\n4 4\n5 1\n6 4\n6 2\n6 2\n1 4\n5 5\n4 2\n5 5\n5 4\n1 3\n3 5\n6 1\n6 1\n1 4\n4 3\n5 1\n3 6\n2 2\n6 2\n4 4\n2 3\n4 2\n6 5\n5 6\n2 2\n2 4\n3 5\n1 5\n3 2\n3 4\n5 6\n4 6\n1 6\n4 5\n2 6\n2 2\n3 5\n6 4\n5 1\n4 3\n3 4\n3 5\n3 3\n2 3\n3 2\n2 2\n1 4\n3 1\n4 4",
"output": "1"
},
{
"input": "50\n1 2\n1 4\n1 1\n4 5\n4 4\n3 2\n4 5\n3 5\n1 1\n3 4\n3 2\n2 4\n2 6\n2 6\n3 2\n4 6\n1 6\n3 1\n1 6\n2 1\n4 1\n1 6\n4 3\n6 6\n5 2\n6 4\n2 1\n4 3\n6 4\n5 1\n5 5\n3 1\n1 1\n5 5\n2 2\n2 3\n2 3\n3 5\n5 5\n1 6\n1 5\n3 6\n3 6\n1 1\n3 3\n2 6\n5 5\n1 3\n6 3\n6 6",
"output": "-1"
},
{
"input": "55\n3 2\n5 6\n5 1\n3 5\n5 5\n1 5\n5 4\n6 3\n5 6\n4 2\n3 1\n1 2\n5 5\n1 1\n5 2\n6 3\n5 4\n3 6\n4 6\n2 6\n6 4\n1 4\n1 6\n4 1\n2 5\n4 3\n2 1\n2 1\n6 2\n3 1\n2 5\n4 4\n6 3\n2 2\n3 5\n5 1\n3 6\n5 4\n4 6\n6 5\n5 6\n2 2\n3 2\n5 2\n6 5\n2 2\n5 3\n3 1\n4 5\n6 4\n2 4\n1 2\n5 6\n2 6\n5 2",
"output": "0"
},
{
"input": "55\n4 6\n3 3\n6 5\n5 3\n5 6\n2 3\n2 2\n3 4\n3 1\n5 4\n5 4\n2 4\n3 4\n4 5\n1 5\n6 3\n1 1\n5 1\n3 4\n1 5\n3 1\n2 5\n3 3\n4 3\n3 3\n3 1\n6 6\n3 3\n3 3\n5 6\n5 3\n3 5\n1 4\n5 5\n1 3\n1 4\n3 5\n3 6\n2 4\n2 4\n5 1\n6 4\n5 1\n5 5\n1 1\n3 2\n4 3\n5 4\n5 1\n2 4\n4 3\n6 1\n3 4\n1 5\n6 3",
"output": "-1"
},
{
"input": "60\n2 6\n1 4\n3 2\n1 2\n3 2\n2 4\n6 4\n4 6\n1 3\n3 1\n6 5\n2 4\n5 4\n4 2\n1 6\n3 4\n4 5\n5 2\n1 5\n5 4\n3 4\n3 4\n4 4\n4 1\n6 6\n3 6\n2 4\n2 1\n4 4\n6 5\n3 1\n4 3\n1 3\n6 3\n5 5\n1 4\n3 1\n3 6\n1 5\n3 1\n1 5\n4 4\n1 3\n2 4\n6 2\n4 1\n5 3\n3 4\n5 6\n1 2\n1 6\n6 3\n1 6\n3 6\n3 4\n6 2\n4 6\n2 3\n3 3\n3 3",
"output": "-1"
},
{
"input": "60\n2 3\n4 6\n2 4\n1 3\n5 6\n1 5\n1 2\n1 3\n5 6\n4 3\n4 2\n3 1\n1 3\n3 5\n1 5\n3 4\n2 4\n3 5\n4 5\n1 2\n3 1\n1 5\n2 5\n6 2\n1 6\n3 3\n6 2\n5 3\n1 3\n1 4\n6 4\n6 3\n4 2\n4 2\n1 4\n1 3\n3 2\n3 1\n2 1\n1 2\n3 1\n2 6\n1 4\n3 6\n3 3\n1 5\n2 4\n5 5\n6 2\n5 2\n3 3\n5 3\n3 4\n4 5\n5 6\n2 4\n5 3\n3 1\n2 4\n5 4",
"output": "-1"
},
{
"input": "65\n5 4\n3 3\n1 2\n4 3\n3 5\n1 5\n4 5\n2 6\n1 2\n1 5\n6 3\n2 6\n4 3\n3 6\n1 5\n3 5\n4 6\n2 5\n6 5\n1 4\n3 4\n4 3\n1 4\n2 5\n6 5\n3 1\n4 3\n1 2\n1 1\n6 1\n5 2\n3 2\n1 6\n2 6\n3 3\n6 6\n4 6\n1 5\n5 1\n4 5\n1 4\n3 2\n5 4\n4 2\n6 2\n1 3\n4 2\n5 3\n6 4\n3 6\n1 2\n6 1\n6 6\n3 3\n4 2\n3 5\n4 6\n4 1\n5 4\n6 1\n5 1\n5 6\n6 1\n4 6\n5 5",
"output": "1"
},
{
"input": "65\n5 4\n6 3\n5 4\n4 5\n5 3\n3 6\n1 3\n3 1\n1 3\n6 1\n6 4\n1 3\n2 2\n4 6\n4 1\n5 6\n6 5\n1 1\n1 3\n6 6\n4 1\n2 4\n5 4\n4 1\n5 5\n5 3\n6 2\n2 6\n4 2\n2 2\n6 2\n3 3\n4 5\n4 3\n3 1\n1 4\n4 5\n3 2\n5 5\n4 6\n5 1\n3 4\n5 4\n5 2\n1 6\n4 2\n3 4\n3 4\n1 3\n1 2\n3 3\n3 6\n6 4\n4 6\n6 2\n6 5\n3 2\n2 1\n6 4\n2 1\n1 5\n5 2\n6 5\n3 6\n5 1",
"output": "1"
},
{
"input": "70\n4 1\n2 6\n1 1\n5 6\n5 1\n2 3\n3 5\n1 1\n1 1\n4 6\n4 3\n1 5\n2 2\n2 3\n3 1\n6 4\n3 1\n4 2\n5 4\n1 3\n3 5\n5 2\n5 6\n4 4\n4 5\n2 2\n4 5\n3 2\n3 5\n2 5\n2 6\n5 5\n2 6\n5 1\n1 1\n2 5\n3 1\n1 2\n6 4\n6 5\n5 5\n5 1\n1 5\n2 2\n6 3\n4 3\n6 2\n5 5\n1 1\n6 2\n6 6\n3 4\n2 2\n3 5\n1 5\n2 5\n4 5\n2 4\n6 3\n5 1\n2 6\n4 2\n1 4\n1 6\n6 2\n5 2\n5 6\n2 5\n5 6\n5 5",
"output": "-1"
},
{
"input": "70\n4 3\n6 4\n5 5\n3 1\n1 2\n2 5\n4 6\n4 2\n3 2\n4 2\n1 5\n2 2\n4 3\n1 2\n6 1\n6 6\n1 6\n5 1\n2 2\n6 3\n4 2\n4 3\n1 2\n6 6\n3 3\n6 5\n6 2\n3 6\n6 6\n4 6\n5 2\n5 4\n3 3\n1 6\n5 6\n2 3\n4 6\n1 1\n1 2\n6 6\n1 1\n3 4\n1 6\n2 6\n3 4\n6 3\n5 3\n1 2\n2 3\n4 6\n2 1\n6 4\n4 6\n4 6\n4 2\n5 5\n3 5\n3 2\n4 3\n3 6\n1 4\n3 6\n1 4\n1 6\n1 5\n5 6\n4 4\n3 3\n3 5\n2 2",
"output": "0"
},
{
"input": "75\n1 3\n4 5\n4 1\n6 5\n2 1\n1 4\n5 4\n1 5\n5 3\n1 2\n4 1\n1 1\n5 1\n5 3\n1 5\n4 2\n2 2\n6 3\n1 2\n4 3\n2 5\n5 3\n5 5\n4 1\n4 6\n2 5\n6 1\n2 4\n6 4\n5 2\n6 2\n2 4\n1 3\n5 4\n6 5\n5 4\n6 4\n1 5\n4 6\n1 5\n1 1\n4 4\n3 5\n6 3\n6 5\n1 5\n2 1\n1 5\n6 6\n2 2\n2 2\n4 4\n6 6\n5 4\n4 5\n3 2\n2 4\n1 1\n4 3\n3 2\n5 4\n1 6\n1 2\n2 2\n3 5\n2 6\n1 1\n2 2\n2 3\n6 2\n3 6\n4 4\n5 1\n4 1\n4 1",
"output": "0"
},
{
"input": "75\n1 1\n2 1\n5 5\n6 5\n6 3\n1 6\n6 1\n4 4\n2 1\n6 2\n3 1\n6 4\n1 6\n2 2\n4 3\n4 2\n1 2\n6 2\n4 2\n5 1\n1 2\n3 2\n6 6\n6 3\n2 4\n4 1\n4 1\n2 4\n5 5\n2 3\n5 5\n4 5\n3 1\n1 5\n4 3\n2 3\n3 5\n4 6\n5 6\n1 6\n2 3\n2 2\n1 2\n5 6\n1 4\n1 5\n1 3\n6 2\n1 2\n4 2\n2 1\n1 3\n6 4\n4 1\n5 2\n6 2\n3 5\n2 3\n4 2\n5 1\n5 6\n3 2\n2 1\n6 6\n2 1\n6 2\n1 1\n3 2\n1 2\n3 5\n4 6\n1 3\n3 4\n5 5\n6 2",
"output": "1"
},
{
"input": "80\n3 1\n6 3\n2 2\n2 2\n6 3\n6 1\n6 5\n1 4\n3 6\n6 5\n1 3\n2 4\n1 4\n3 1\n5 3\n5 3\n1 4\n2 5\n4 3\n4 4\n4 5\n6 1\n3 1\n2 6\n4 2\n3 1\n6 5\n2 6\n2 2\n5 1\n1 3\n5 1\n2 1\n4 3\n6 3\n3 5\n4 3\n5 6\n3 3\n4 1\n5 1\n6 5\n5 1\n2 5\n6 1\n3 2\n4 3\n3 3\n5 6\n1 6\n5 2\n1 5\n5 6\n6 4\n2 2\n4 2\n4 6\n4 2\n4 4\n6 5\n5 2\n6 2\n4 6\n6 4\n4 3\n5 1\n4 1\n3 5\n3 2\n3 2\n5 3\n5 4\n3 4\n1 3\n1 2\n6 6\n6 3\n6 1\n5 6\n3 2",
"output": "0"
},
{
"input": "80\n4 5\n3 3\n3 6\n4 5\n3 4\n6 5\n1 5\n2 5\n5 6\n5 1\n5 1\n1 2\n5 5\n5 1\n2 3\n1 1\n4 5\n4 1\n1 1\n5 5\n5 6\n5 2\n5 4\n4 2\n6 2\n5 3\n3 2\n4 2\n1 3\n1 6\n2 1\n6 6\n4 5\n6 4\n2 2\n1 6\n6 2\n4 3\n2 3\n4 6\n4 6\n6 2\n3 4\n4 3\n5 5\n1 6\n3 2\n4 6\n2 3\n1 6\n5 4\n4 2\n5 4\n1 1\n4 3\n5 1\n3 6\n6 2\n3 1\n4 1\n5 3\n2 2\n3 4\n3 6\n3 5\n5 5\n5 1\n3 5\n2 6\n6 3\n6 5\n3 3\n5 6\n1 2\n3 1\n6 3\n3 4\n6 6\n6 6\n1 2",
"output": "-1"
},
{
"input": "85\n6 3\n4 1\n1 2\n3 5\n6 4\n6 2\n2 6\n1 2\n1 5\n6 2\n1 4\n6 6\n2 4\n4 6\n4 5\n1 6\n3 1\n2 5\n5 1\n5 2\n3 5\n1 1\n4 1\n2 3\n1 1\n3 3\n6 4\n1 4\n1 1\n3 6\n1 5\n1 6\n2 5\n2 2\n5 1\n6 6\n1 3\n1 5\n5 6\n4 5\n4 3\n5 5\n1 3\n6 3\n4 6\n2 4\n5 6\n6 2\n4 5\n1 4\n1 4\n6 5\n1 6\n6 1\n1 6\n5 5\n2 1\n5 2\n2 3\n1 6\n1 6\n1 6\n5 6\n2 4\n6 5\n6 5\n4 2\n5 4\n3 4\n4 3\n6 6\n3 3\n3 2\n3 6\n2 5\n2 1\n2 5\n3 4\n1 2\n5 4\n6 2\n5 1\n1 4\n3 4\n4 5",
"output": "0"
},
{
"input": "85\n3 1\n3 2\n6 3\n1 3\n2 1\n3 6\n1 4\n2 5\n6 5\n1 6\n1 5\n1 1\n4 3\n3 5\n4 6\n3 2\n6 6\n4 4\n4 1\n5 5\n4 2\n6 2\n2 2\n4 5\n6 1\n3 4\n4 5\n3 5\n4 2\n3 5\n4 4\n3 1\n4 4\n6 4\n1 4\n5 5\n1 5\n2 2\n6 5\n5 6\n6 5\n3 2\n3 2\n6 1\n6 5\n2 1\n4 6\n2 1\n3 1\n5 6\n1 3\n5 4\n1 4\n1 4\n5 3\n2 3\n1 3\n2 2\n5 3\n2 3\n2 3\n1 3\n3 6\n4 4\n6 6\n6 2\n5 1\n5 5\n5 5\n1 2\n1 4\n2 4\n3 6\n4 6\n6 3\n6 4\n5 5\n3 2\n5 4\n5 4\n4 5\n6 4\n2 1\n5 2\n5 1",
"output": "-1"
},
{
"input": "90\n5 2\n5 5\n5 1\n4 6\n4 3\n5 3\n5 6\n5 1\n3 4\n1 3\n4 2\n1 6\n6 4\n1 2\n6 1\n4 1\n6 2\n6 5\n6 2\n5 4\n3 6\n1 1\n5 5\n2 2\n1 6\n3 5\n6 5\n1 6\n1 5\n2 3\n2 6\n2 3\n3 3\n1 3\n5 1\n2 5\n3 6\n1 2\n4 4\n1 6\n2 3\n1 5\n2 5\n1 3\n2 2\n4 6\n3 6\n6 3\n1 2\n4 3\n4 5\n4 6\n3 2\n6 5\n6 2\n2 5\n2 4\n1 3\n1 6\n4 3\n1 3\n6 4\n4 6\n4 1\n1 1\n4 1\n4 4\n6 2\n6 5\n1 1\n2 2\n3 1\n1 4\n6 2\n5 2\n1 4\n1 3\n6 5\n3 2\n6 4\n3 4\n2 6\n2 2\n6 3\n4 6\n1 2\n4 2\n3 4\n2 3\n1 5",
"output": "-1"
},
{
"input": "90\n1 4\n3 5\n4 2\n2 5\n4 3\n2 6\n2 6\n3 2\n4 4\n6 1\n4 3\n2 3\n5 3\n6 6\n2 2\n6 3\n4 1\n4 4\n5 6\n6 4\n4 2\n5 6\n4 6\n4 4\n6 4\n4 1\n5 3\n3 2\n4 4\n5 2\n5 4\n6 4\n1 2\n3 3\n3 4\n6 4\n1 6\n4 2\n3 2\n1 1\n2 2\n5 1\n6 6\n4 1\n5 2\n3 6\n2 1\n2 2\n4 6\n6 5\n4 4\n5 5\n5 6\n1 6\n1 4\n5 6\n3 6\n6 3\n5 6\n6 5\n5 1\n6 1\n6 6\n6 3\n1 5\n4 5\n3 1\n6 6\n3 4\n6 2\n1 4\n2 2\n3 2\n5 6\n2 4\n1 4\n6 3\n4 6\n1 4\n5 2\n1 2\n6 5\n1 5\n1 4\n4 2\n2 5\n3 2\n5 1\n5 4\n5 3",
"output": "-1"
},
{
"input": "95\n4 3\n3 2\n5 5\n5 3\n1 6\n4 4\n5 5\n6 5\n3 5\n1 5\n4 2\n5 1\n1 2\n2 3\n6 4\n2 3\n6 3\n6 5\n5 6\n1 4\n2 6\n2 6\n2 5\n2 1\n3 1\n3 5\n2 2\n6 1\n2 4\n4 6\n6 6\n6 4\n3 2\n5 1\n4 3\n6 5\n2 3\n4 1\n2 5\n6 5\n6 5\n6 5\n5 1\n5 4\n4 6\n3 2\n2 5\n2 6\n4 6\n6 3\n6 4\n5 6\n4 6\n2 4\n3 4\n1 4\n2 4\n2 3\n5 6\n6 4\n3 1\n5 1\n3 6\n3 5\n2 6\n6 3\n4 3\n3 1\n6 1\n2 2\n6 3\n2 2\n2 2\n6 4\n6 1\n2 1\n5 6\n5 4\n5 2\n3 4\n3 6\n2 1\n1 6\n5 5\n2 6\n2 3\n3 6\n1 3\n1 5\n5 1\n1 2\n2 2\n5 3\n6 4\n4 5",
"output": "0"
},
{
"input": "95\n4 5\n5 6\n3 2\n5 1\n4 3\n4 1\n6 1\n5 2\n2 4\n5 3\n2 3\n6 4\n4 1\n1 6\n2 6\n2 3\n4 6\n2 4\n3 4\n4 2\n5 5\n1 1\n1 5\n4 3\n4 5\n6 2\n6 1\n6 3\n5 5\n4 1\n5 1\n2 3\n5 1\n3 6\n6 6\n4 5\n4 4\n4 3\n1 6\n6 6\n4 6\n6 4\n1 2\n6 2\n4 6\n6 6\n5 5\n6 1\n5 2\n4 5\n6 6\n6 5\n4 4\n1 5\n4 6\n4 1\n3 6\n5 1\n3 1\n4 6\n4 5\n1 3\n5 4\n4 5\n2 2\n6 1\n5 2\n6 5\n2 2\n1 1\n6 3\n6 1\n2 6\n3 3\n2 1\n4 6\n2 4\n5 5\n5 2\n3 2\n1 2\n6 6\n6 2\n5 1\n2 6\n5 2\n2 2\n5 5\n3 5\n3 3\n2 6\n5 3\n4 3\n1 6\n5 4",
"output": "-1"
},
{
"input": "100\n1 1\n3 5\n2 1\n1 2\n3 4\n5 6\n5 6\n6 1\n5 5\n2 4\n5 5\n5 6\n6 2\n6 6\n2 6\n1 4\n2 2\n3 2\n1 3\n5 5\n6 3\n5 6\n1 1\n1 2\n1 2\n2 1\n2 3\n1 6\n4 3\n1 1\n2 5\n2 4\n4 4\n1 5\n3 3\n6 1\n3 5\n1 1\n3 6\n3 1\n4 2\n4 3\n3 6\n6 6\n1 6\n6 2\n2 5\n5 4\n6 3\n1 4\n2 6\n6 2\n3 4\n6 1\n6 5\n4 6\n6 5\n4 4\n3 1\n6 3\n5 1\n2 4\n5 1\n1 2\n2 4\n2 1\n6 6\n5 3\n4 6\n6 3\n5 5\n3 3\n1 1\n6 5\n4 3\n2 6\n1 5\n3 5\n2 4\n4 5\n1 6\n2 3\n6 3\n5 5\n2 6\n2 6\n3 4\n3 2\n6 1\n3 4\n6 4\n3 3\n2 3\n5 1\n3 1\n6 2\n2 3\n6 4\n1 4\n1 2",
"output": "-1"
},
{
"input": "100\n1 1\n5 5\n1 2\n5 3\n5 5\n2 2\n1 5\n3 4\n3 2\n1 3\n5 6\n4 5\n2 1\n5 5\n2 2\n1 6\n6 1\n5 1\n4 1\n4 6\n3 5\n6 1\n2 3\n5 6\n3 6\n2 3\n5 6\n1 6\n3 2\n2 2\n3 3\n6 5\n5 5\n1 4\n5 6\n6 4\n1 4\n1 2\n2 6\n3 2\n6 4\n5 3\n3 3\n6 4\n4 6\n2 2\n5 6\n5 1\n1 2\n3 4\n4 5\n1 1\n3 4\n5 2\n4 5\n3 3\n1 1\n3 4\n1 6\n2 4\n1 3\n3 2\n6 5\n1 6\n3 6\n2 3\n2 6\n5 1\n5 5\n5 6\n4 1\n6 2\n3 6\n5 3\n2 2\n2 4\n6 6\n3 6\n4 6\n2 5\n5 3\n1 2\n3 4\n3 4\n6 2\n2 4\n2 2\n4 6\n3 5\n4 2\n5 6\n4 2\n2 3\n6 2\n5 6\n2 1\n3 3\n6 6\n4 3\n4 2",
"output": "1"
},
{
"input": "1\n2 2",
"output": "0"
},
{
"input": "3\n2 4\n6 6\n3 3",
"output": "-1"
},
{
"input": "2\n3 6\n4 1",
"output": "1"
},
{
"input": "3\n1 1\n1 1\n3 3",
"output": "-1"
},
{
"input": "3\n2 3\n1 1\n2 3",
"output": "1"
},
{
"input": "3\n2 2\n2 1\n1 2",
"output": "1"
},
{
"input": "3\n1 1\n1 1\n1 1",
"output": "-1"
}
] | 1,622,004,814 | 2,147,483,647 | Python 3 | OK | TESTS | 59 | 124 | 0 | n=int(input());
upper=[];
lower=[];
for i in range(n):
x,y=map(int,input().split());
upper.append(x);
lower.append(y);
if sum(upper)%2==0 and sum(lower)%2==0:
print(0);
else:
if (sum(upper)+sum(lower))%2==1:
print(-1);
else:
for i in range(0,n):
khoi_i_la_chan_le=upper[i]%2!=lower[i]%2;
if khoi_i_la_chan_le:
co_chan_le=True;
break;
else:
co_chan_le=False;
if co_chan_le:
print(1);
else:
print(-1);
| Title: Domino
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera has got *n* domino pieces in a row. Each piece consists of two halves — the upper one and the lower one. Each of the halves contains a number from 1 to 6. Valera loves even integers very much, so he wants the sum of the numbers on the upper halves and the sum of the numbers on the lower halves to be even.
To do that, Valera can rotate the dominoes by 180 degrees. After the rotation the upper and the lower halves swap places. This action takes one second. Help Valera find out the minimum time he must spend rotating dominoes to make his wish come true.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=100), denoting the number of dominoes Valera has. Next *n* lines contain two space-separated integers *x**i*,<=*y**i* (1<=≤<=*x**i*,<=*y**i*<=≤<=6). Number *x**i* is initially written on the upper half of the *i*-th domino, *y**i* is initially written on the lower half.
Output Specification:
Print a single number — the minimum required number of seconds. If Valera can't do the task in any time, print <=-<=1.
Demo Input:
['2\n4 2\n6 4\n', '1\n2 3\n', '3\n1 4\n2 3\n4 4\n']
Demo Output:
['0\n', '-1\n', '1\n']
Note:
In the first test case the sum of the numbers on the upper halves equals 10 and the sum of the numbers on the lower halves equals 6. Both numbers are even, so Valera doesn't required to do anything.
In the second sample Valera has only one piece of domino. It is written 3 on the one of its halves, therefore one of the sums will always be odd.
In the third case Valera can rotate the first piece, and after that the sum on the upper halves will be equal to 10, and the sum on the lower halves will be equal to 8. | ```python
n=int(input());
upper=[];
lower=[];
for i in range(n):
x,y=map(int,input().split());
upper.append(x);
lower.append(y);
if sum(upper)%2==0 and sum(lower)%2==0:
print(0);
else:
if (sum(upper)+sum(lower))%2==1:
print(-1);
else:
for i in range(0,n):
khoi_i_la_chan_le=upper[i]%2!=lower[i]%2;
if khoi_i_la_chan_le:
co_chan_le=True;
break;
else:
co_chan_le=False;
if co_chan_le:
print(1);
else:
print(-1);
``` | 3 | |
955 | C | Sad powers | PROGRAMMING | 2,100 | [
"binary search",
"math",
"number theory"
] | null | null | You're given *Q* queries of the form (*L*,<=*R*).
For each query you have to find the number of such *x* that *L*<=≤<=*x*<=≤<=*R* and there exist integer numbers *a*<=><=0, *p*<=><=1 such that *x*<==<=*a**p*. | The first line contains the number of queries *Q* (1<=≤<=*Q*<=≤<=105).
The next *Q* lines contains two integers *L*, *R* each (1<=≤<=*L*<=≤<=*R*<=≤<=1018). | Output *Q* lines — the answers to the queries. | [
"6\n1 4\n9 9\n5 7\n12 29\n137 591\n1 1000000\n"
] | [
"2\n1\n0\n3\n17\n1111\n"
] | In query one the suitable numbers are 1 and 4. | 1,500 | [
{
"input": "6\n1 4\n9 9\n5 7\n12 29\n137 591\n1 1000000",
"output": "2\n1\n0\n3\n17\n1111"
},
{
"input": "20\n862 928\n758 964\n541 789\n622 943\n328 900\n14 764\n217 972\n461 847\n442 468\n900 986\n518 529\n938 993\n549 851\n690 944\n484 601\n320 910\n98 868\n816 915\n765 880\n551 770",
"output": "1\n4\n5\n6\n14\n32\n20\n9\n0\n2\n1\n1\n6\n4\n4\n15\n26\n2\n2\n4"
}
] | 1,693,589,752 | 3,652 | PyPy 3-64 | TIME_LIMIT_EXCEEDED | TESTS | 2 | 2,000 | 5,836,800 | import sys
input = sys.stdin.buffer.readline
my_max = [0 for i in range(61)]
for i in range(2, 61):
my_max[i] = int((10**18)**(1/i))+4
def iroot(n, k=2):
if n == 0 or n==1:
return n
if n < 0:
return -iroot(-n, k) if k & 1 else None
u, s = n, n + 1
while u < s:
s = u
t = (k - 1) * s + n // s**(k - 1)
u = t // k
return s
sign = [1 for i in range(61)]
for i in range(2, 61):
for j in range(2, i):
if i % j==0:
if i % (j*j)==0:
sign[i]= 0
else:
sign[i] = -1*sign[i//j]
break
sign = [(i, sign[i]) for i in range(2, 61) if sign[i] != 0]
def process(L, R):
answer = 0
for i, s in sign:
R1 = iroot(R, i)
if R1==0:
break
L1 = iroot(L-1, i)
if L1==0:
entry = R1-1
else:
entry = R1-L1
answer = answer+s*entry
if L==1:
answer+=1
sys.stdout.write(f'{answer}\n')
return
Q = int(input())
for i in range(Q):
L, R = [int(x) for x in input().split()]
process(L, R) | Title: Sad powers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You're given *Q* queries of the form (*L*,<=*R*).
For each query you have to find the number of such *x* that *L*<=≤<=*x*<=≤<=*R* and there exist integer numbers *a*<=><=0, *p*<=><=1 such that *x*<==<=*a**p*.
Input Specification:
The first line contains the number of queries *Q* (1<=≤<=*Q*<=≤<=105).
The next *Q* lines contains two integers *L*, *R* each (1<=≤<=*L*<=≤<=*R*<=≤<=1018).
Output Specification:
Output *Q* lines — the answers to the queries.
Demo Input:
['6\n1 4\n9 9\n5 7\n12 29\n137 591\n1 1000000\n']
Demo Output:
['2\n1\n0\n3\n17\n1111\n']
Note:
In query one the suitable numbers are 1 and 4. | ```python
import sys
input = sys.stdin.buffer.readline
my_max = [0 for i in range(61)]
for i in range(2, 61):
my_max[i] = int((10**18)**(1/i))+4
def iroot(n, k=2):
if n == 0 or n==1:
return n
if n < 0:
return -iroot(-n, k) if k & 1 else None
u, s = n, n + 1
while u < s:
s = u
t = (k - 1) * s + n // s**(k - 1)
u = t // k
return s
sign = [1 for i in range(61)]
for i in range(2, 61):
for j in range(2, i):
if i % j==0:
if i % (j*j)==0:
sign[i]= 0
else:
sign[i] = -1*sign[i//j]
break
sign = [(i, sign[i]) for i in range(2, 61) if sign[i] != 0]
def process(L, R):
answer = 0
for i, s in sign:
R1 = iroot(R, i)
if R1==0:
break
L1 = iroot(L-1, i)
if L1==0:
entry = R1-1
else:
entry = R1-L1
answer = answer+s*entry
if L==1:
answer+=1
sys.stdout.write(f'{answer}\n')
return
Q = int(input())
for i in range(Q):
L, R = [int(x) for x in input().split()]
process(L, R)
``` | 0 | |
584 | B | Kolya and Tanya | PROGRAMMING | 1,500 | [
"combinatorics"
] | null | null | Kolya loves putting gnomes at the circle table and giving them coins, and Tanya loves studying triplets of gnomes, sitting in the vertexes of an equilateral triangle.
More formally, there are 3*n* gnomes sitting in a circle. Each gnome can have from 1 to 3 coins. Let's number the places in the order they occur in the circle by numbers from 0 to 3*n*<=-<=1, let the gnome sitting on the *i*-th place have *a**i* coins. If there is an integer *i* (0<=≤<=*i*<=<<=*n*) such that *a**i*<=+<=*a**i*<=+<=*n*<=+<=*a**i*<=+<=2*n*<=≠<=6, then Tanya is satisfied.
Count the number of ways to choose *a**i* so that Tanya is satisfied. As there can be many ways of distributing coins, print the remainder of this number modulo 109<=+<=7. Two ways, *a* and *b*, are considered distinct if there is index *i* (0<=≤<=*i*<=<<=3*n*), such that *a**i*<=≠<=*b**i* (that is, some gnome got different number of coins in these two ways). | A single line contains number *n* (1<=≤<=*n*<=≤<=105) — the number of the gnomes divided by three. | Print a single number — the remainder of the number of variants of distributing coins that satisfy Tanya modulo 109<=+<=7. | [
"1\n",
"2\n"
] | [
"20",
"680"
] | 20 ways for *n* = 1 (gnome with index 0 sits on the top of the triangle, gnome 1 on the right vertex, gnome 2 on the left vertex): <img class="tex-graphics" src="https://espresso.codeforces.com/64df38b85ccb482cf88d02dc52e348e33313f9da.png" style="max-width: 100.0%;max-height: 100.0%;"/> | 1,000 | [
{
"input": "1",
"output": "20"
},
{
"input": "2",
"output": "680"
},
{
"input": "3",
"output": "19340"
},
{
"input": "4",
"output": "529040"
},
{
"input": "5",
"output": "14332100"
},
{
"input": "7",
"output": "459529590"
},
{
"input": "10",
"output": "848178170"
},
{
"input": "14",
"output": "356372551"
},
{
"input": "58000",
"output": "66667472"
},
{
"input": "6",
"output": "387302840"
},
{
"input": "8",
"output": "423769706"
},
{
"input": "9",
"output": "557078005"
},
{
"input": "15",
"output": "83420839"
},
{
"input": "20",
"output": "208683407"
},
{
"input": "22",
"output": "695178405"
},
{
"input": "48",
"output": "974152357"
},
{
"input": "74",
"output": "972015869"
},
{
"input": "100",
"output": "364994225"
},
{
"input": "866",
"output": "363347020"
},
{
"input": "1673",
"output": "112069243"
},
{
"input": "555",
"output": "506150275"
},
{
"input": "2000",
"output": "394190362"
},
{
"input": "9877",
"output": "915063121"
},
{
"input": "5984",
"output": "546302050"
},
{
"input": "2091",
"output": "982683445"
},
{
"input": "10000",
"output": "246305722"
},
{
"input": "10868",
"output": "118127713"
},
{
"input": "66115",
"output": "413345995"
},
{
"input": "62212",
"output": "587210092"
},
{
"input": "100000",
"output": "192156836"
},
{
"input": "2441",
"output": "149858187"
},
{
"input": "18569",
"output": "54080463"
},
{
"input": "69289",
"output": "582363404"
},
{
"input": "85417",
"output": "796810422"
},
{
"input": "68841",
"output": "371243141"
},
{
"input": "10000",
"output": "246305722"
},
{
"input": "4343",
"output": "682818914"
},
{
"input": "12312",
"output": "837337190"
},
{
"input": "5462",
"output": "719513799"
},
{
"input": "100",
"output": "364994225"
},
{
"input": "11",
"output": "550315374"
},
{
"input": "100000",
"output": "192156836"
}
] | 1,690,407,763 | 2,147,483,647 | Python 3 | COMPILATION_ERROR | TESTS | 0 | 0 | 0 | n = int(input(""))
a=pow(27, n)
b=pow(7, n))
m=(pow(10, 9) + 7)
print((a -b %m ) | Title: Kolya and Tanya
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Kolya loves putting gnomes at the circle table and giving them coins, and Tanya loves studying triplets of gnomes, sitting in the vertexes of an equilateral triangle.
More formally, there are 3*n* gnomes sitting in a circle. Each gnome can have from 1 to 3 coins. Let's number the places in the order they occur in the circle by numbers from 0 to 3*n*<=-<=1, let the gnome sitting on the *i*-th place have *a**i* coins. If there is an integer *i* (0<=≤<=*i*<=<<=*n*) such that *a**i*<=+<=*a**i*<=+<=*n*<=+<=*a**i*<=+<=2*n*<=≠<=6, then Tanya is satisfied.
Count the number of ways to choose *a**i* so that Tanya is satisfied. As there can be many ways of distributing coins, print the remainder of this number modulo 109<=+<=7. Two ways, *a* and *b*, are considered distinct if there is index *i* (0<=≤<=*i*<=<<=3*n*), such that *a**i*<=≠<=*b**i* (that is, some gnome got different number of coins in these two ways).
Input Specification:
A single line contains number *n* (1<=≤<=*n*<=≤<=105) — the number of the gnomes divided by three.
Output Specification:
Print a single number — the remainder of the number of variants of distributing coins that satisfy Tanya modulo 109<=+<=7.
Demo Input:
['1\n', '2\n']
Demo Output:
['20', '680']
Note:
20 ways for *n* = 1 (gnome with index 0 sits on the top of the triangle, gnome 1 on the right vertex, gnome 2 on the left vertex): <img class="tex-graphics" src="https://espresso.codeforces.com/64df38b85ccb482cf88d02dc52e348e33313f9da.png" style="max-width: 100.0%;max-height: 100.0%;"/> | ```python
n = int(input(""))
a=pow(27, n)
b=pow(7, n))
m=(pow(10, 9) + 7)
print((a -b %m )
``` | -1 | |
84 | A | Toy Army | PROGRAMMING | 900 | [
"math",
"number theory"
] | A. Toy Army | 2 | 256 | The hero of our story, Valera, and his best friend Arcady are still in school, and therefore they spend all the free time playing turn-based strategy "GAGA: Go And Go Again". The gameplay is as follows.
There are two armies on the playing field each of which consists of *n* men (*n* is always even). The current player specifies for each of her soldiers an enemy's soldier he will shoot (a target) and then all the player's soldiers shot simultaneously. This is a game world, and so each soldier shoots perfectly, that is he absolutely always hits the specified target. If an enemy soldier is hit, he will surely die. It may happen that several soldiers had been indicated the same target. Killed soldiers do not participate in the game anymore.
The game "GAGA" consists of three steps: first Valera makes a move, then Arcady, then Valera again and the game ends.
You are asked to calculate the maximum total number of soldiers that may be killed during the game. | The input data consist of a single integer *n* (2<=≤<=*n*<=≤<=108, *n* is even). Please note that before the game starts there are 2*n* soldiers on the fields. | Print a single number — a maximum total number of soldiers that could be killed in the course of the game in three turns. | [
"2\n",
"4\n"
] | [
"3\n",
"6\n"
] | The first sample test:
1) Valera's soldiers 1 and 2 shoot at Arcady's soldier 1.
2) Arcady's soldier 2 shoots at Valera's soldier 1.
3) Valera's soldier 1 shoots at Arcady's soldier 2.
There are 3 soldiers killed in total: Valera's soldier 1 and Arcady's soldiers 1 and 2. | 500 | [
{
"input": "2",
"output": "3"
},
{
"input": "4",
"output": "6"
},
{
"input": "6",
"output": "9"
},
{
"input": "8",
"output": "12"
},
{
"input": "10",
"output": "15"
},
{
"input": "140",
"output": "210"
},
{
"input": "500",
"output": "750"
},
{
"input": "1000",
"output": "1500"
},
{
"input": "2000",
"output": "3000"
},
{
"input": "50000",
"output": "75000"
},
{
"input": "10000",
"output": "15000"
},
{
"input": "25460",
"output": "38190"
},
{
"input": "54646",
"output": "81969"
},
{
"input": "59790",
"output": "89685"
},
{
"input": "578456",
"output": "867684"
},
{
"input": "56798056",
"output": "85197084"
},
{
"input": "8457980",
"output": "12686970"
},
{
"input": "5687986",
"output": "8531979"
},
{
"input": "10984932",
"output": "16477398"
},
{
"input": "99999994",
"output": "149999991"
},
{
"input": "99999996",
"output": "149999994"
},
{
"input": "99999998",
"output": "149999997"
},
{
"input": "100000000",
"output": "150000000"
}
] | 1,679,121,127 | 2,147,483,647 | Python 3 | OK | TESTS | 23 | 92 | 0 | n = int(input())
print((2*n)-(n//2))#Source code should contain 50 characters at least
| Title: Toy Army
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
The hero of our story, Valera, and his best friend Arcady are still in school, and therefore they spend all the free time playing turn-based strategy "GAGA: Go And Go Again". The gameplay is as follows.
There are two armies on the playing field each of which consists of *n* men (*n* is always even). The current player specifies for each of her soldiers an enemy's soldier he will shoot (a target) and then all the player's soldiers shot simultaneously. This is a game world, and so each soldier shoots perfectly, that is he absolutely always hits the specified target. If an enemy soldier is hit, he will surely die. It may happen that several soldiers had been indicated the same target. Killed soldiers do not participate in the game anymore.
The game "GAGA" consists of three steps: first Valera makes a move, then Arcady, then Valera again and the game ends.
You are asked to calculate the maximum total number of soldiers that may be killed during the game.
Input Specification:
The input data consist of a single integer *n* (2<=≤<=*n*<=≤<=108, *n* is even). Please note that before the game starts there are 2*n* soldiers on the fields.
Output Specification:
Print a single number — a maximum total number of soldiers that could be killed in the course of the game in three turns.
Demo Input:
['2\n', '4\n']
Demo Output:
['3\n', '6\n']
Note:
The first sample test:
1) Valera's soldiers 1 and 2 shoot at Arcady's soldier 1.
2) Arcady's soldier 2 shoots at Valera's soldier 1.
3) Valera's soldier 1 shoots at Arcady's soldier 2.
There are 3 soldiers killed in total: Valera's soldier 1 and Arcady's soldiers 1 and 2. | ```python
n = int(input())
print((2*n)-(n//2))#Source code should contain 50 characters at least
``` | 3.977 |
318 | A | Even Odds | PROGRAMMING | 900 | [
"math"
] | null | null | Being a nonconformist, Volodya is displeased with the current state of things, particularly with the order of natural numbers (natural number is positive integer number). He is determined to rearrange them. But there are too many natural numbers, so Volodya decided to start with the first *n*. He writes down the following sequence of numbers: firstly all odd integers from 1 to *n* (in ascending order), then all even integers from 1 to *n* (also in ascending order). Help our hero to find out which number will stand at the position number *k*. | The only line of input contains integers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=1012).
Please, do not use the %lld specifier to read or write 64-bit integers in C++. It is preferred to use the cin, cout streams or the %I64d specifier. | Print the number that will stand at the position number *k* after Volodya's manipulations. | [
"10 3\n",
"7 7\n"
] | [
"5",
"6"
] | In the first sample Volodya's sequence will look like this: {1, 3, 5, 7, 9, 2, 4, 6, 8, 10}. The third place in the sequence is therefore occupied by the number 5. | 500 | [
{
"input": "10 3",
"output": "5"
},
{
"input": "7 7",
"output": "6"
},
{
"input": "7 1",
"output": "1"
},
{
"input": "7 2",
"output": "3"
},
{
"input": "8 5",
"output": "2"
},
{
"input": "8 3",
"output": "5"
},
{
"input": "8 4",
"output": "7"
},
{
"input": "1000000000000 500000000001",
"output": "2"
},
{
"input": "999999999997 499999999999",
"output": "999999999997"
},
{
"input": "999999999999 999999999999",
"output": "999999999998"
},
{
"input": "1000000000000 1",
"output": "1"
},
{
"input": "999999999999 1",
"output": "1"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "1000000000000 1000000000000",
"output": "1000000000000"
},
{
"input": "1000000000000 500000000000",
"output": "999999999999"
},
{
"input": "1000000000000 499999999999",
"output": "999999999997"
},
{
"input": "999999999997 499999999998",
"output": "999999999995"
},
{
"input": "619234238 556154835",
"output": "493075432"
},
{
"input": "38151981 36650624",
"output": "35149266"
},
{
"input": "680402465 442571217",
"output": "204739968"
},
{
"input": "109135284 9408714",
"output": "18817427"
},
{
"input": "603701841 56038951",
"output": "112077901"
},
{
"input": "356764822 321510177",
"output": "286255532"
},
{
"input": "284911189 142190783",
"output": "284381565"
},
{
"input": "91028405 61435545",
"output": "31842684"
}
] | 1,695,675,262 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 7 | 1,000 | 197,529,600 | L = [int(i) for i in input().split()]
lst = []
for i in range(1,L[0]+1,2):
lst.append(i)
for i in range(2,L[0]+1,2):
lst.append(i)
print(lst[L[1]-1])
| Title: Even Odds
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Being a nonconformist, Volodya is displeased with the current state of things, particularly with the order of natural numbers (natural number is positive integer number). He is determined to rearrange them. But there are too many natural numbers, so Volodya decided to start with the first *n*. He writes down the following sequence of numbers: firstly all odd integers from 1 to *n* (in ascending order), then all even integers from 1 to *n* (also in ascending order). Help our hero to find out which number will stand at the position number *k*.
Input Specification:
The only line of input contains integers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=1012).
Please, do not use the %lld specifier to read or write 64-bit integers in C++. It is preferred to use the cin, cout streams or the %I64d specifier.
Output Specification:
Print the number that will stand at the position number *k* after Volodya's manipulations.
Demo Input:
['10 3\n', '7 7\n']
Demo Output:
['5', '6']
Note:
In the first sample Volodya's sequence will look like this: {1, 3, 5, 7, 9, 2, 4, 6, 8, 10}. The third place in the sequence is therefore occupied by the number 5. | ```python
L = [int(i) for i in input().split()]
lst = []
for i in range(1,L[0]+1,2):
lst.append(i)
for i in range(2,L[0]+1,2):
lst.append(i)
print(lst[L[1]-1])
``` | 0 | |
706 | B | Interesting drink | PROGRAMMING | 1,100 | [
"binary search",
"dp",
"implementation"
] | null | null | Vasiliy likes to rest after a hard work, so you may often meet him in some bar nearby. As all programmers do, he loves the famous drink "Beecola", which can be bought in *n* different shops in the city. It's known that the price of one bottle in the shop *i* is equal to *x**i* coins.
Vasiliy plans to buy his favorite drink for *q* consecutive days. He knows, that on the *i*-th day he will be able to spent *m**i* coins. Now, for each of the days he want to know in how many different shops he can buy a bottle of "Beecola". | The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of shops in the city that sell Vasiliy's favourite drink.
The second line contains *n* integers *x**i* (1<=≤<=*x**i*<=≤<=100<=000) — prices of the bottles of the drink in the *i*-th shop.
The third line contains a single integer *q* (1<=≤<=*q*<=≤<=100<=000) — the number of days Vasiliy plans to buy the drink.
Then follow *q* lines each containing one integer *m**i* (1<=≤<=*m**i*<=≤<=109) — the number of coins Vasiliy can spent on the *i*-th day. | Print *q* integers. The *i*-th of them should be equal to the number of shops where Vasiliy will be able to buy a bottle of the drink on the *i*-th day. | [
"5\n3 10 8 6 11\n4\n1\n10\n3\n11\n"
] | [
"0\n4\n1\n5\n"
] | On the first day, Vasiliy won't be able to buy a drink in any of the shops.
On the second day, Vasiliy can buy a drink in the shops 1, 2, 3 and 4.
On the third day, Vasiliy can buy a drink only in the shop number 1.
Finally, on the last day Vasiliy can buy a drink in any shop. | 1,000 | [
{
"input": "5\n3 10 8 6 11\n4\n1\n10\n3\n11",
"output": "0\n4\n1\n5"
},
{
"input": "5\n868 987 714 168 123\n10\n424\n192\n795\n873\n117\n914\n735\n158\n631\n471",
"output": "2\n2\n3\n4\n0\n4\n3\n1\n2\n2"
},
{
"input": "3\n435 482 309\n7\n245\n241\n909\n745\n980\n29\n521",
"output": "0\n0\n3\n3\n3\n0\n3"
},
{
"input": "1\n653\n9\n903\n980\n80\n770\n965\n874\n381\n657\n969",
"output": "1\n1\n0\n1\n1\n1\n0\n1\n1"
},
{
"input": "12\n35345 58181 32223 84621 35905 73863 99537 30666 67771 39229 36847 29038\n23\n55052824\n82504840\n35160556\n78141700\n73401989\n86305919\n39430705\n31939373\n23501765\n4406029\n61436920\n14295390\n34275309\n28028753\n85724689\n70158847\n2396455\n66994588\n84024224\n30175981\n65622319\n76517111\n76605341",
"output": "12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12\n12"
},
{
"input": "4\n698 193 1584 76192\n4\n553640\n310518\n274280\n429192",
"output": "4\n4\n4\n4"
},
{
"input": "1\n1\n1\n1000000000",
"output": "1"
},
{
"input": "1\n1\n1\n100005",
"output": "1"
},
{
"input": "3\n1 2 3\n1\n100005",
"output": "3"
},
{
"input": "2\n1 2\n3\n100004\n100005\n100006",
"output": "2\n2\n2"
},
{
"input": "3\n1 1 1\n1\n1",
"output": "3"
},
{
"input": "1\n1\n1\n1",
"output": "1"
},
{
"input": "3\n1 2 3\n1\n100000",
"output": "3"
},
{
"input": "5\n1 1 1 1 10\n2\n1\n10",
"output": "4\n5"
},
{
"input": "5\n3 10 8 6 11\n1\n10000000",
"output": "5"
}
] | 1,693,066,205 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 10 | 2,000 | 27,033,600 | numberofshops = int(input())
allprices = input()
allprices = allprices.split()
drinkdays = int(input())
for x in range (0, drinkdays):
globals()['budget%s' % x] = input()
driinnnng = int(0)
for y in range(0, drinkdays):
for z in range(0,numberofshops):
if (int(allprices[z]) <= int(globals()['budget%s' % y])):
driinnnng += 1
print(driinnnng)
driinnnng = int(0) | Title: Interesting drink
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasiliy likes to rest after a hard work, so you may often meet him in some bar nearby. As all programmers do, he loves the famous drink "Beecola", which can be bought in *n* different shops in the city. It's known that the price of one bottle in the shop *i* is equal to *x**i* coins.
Vasiliy plans to buy his favorite drink for *q* consecutive days. He knows, that on the *i*-th day he will be able to spent *m**i* coins. Now, for each of the days he want to know in how many different shops he can buy a bottle of "Beecola".
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=100<=000) — the number of shops in the city that sell Vasiliy's favourite drink.
The second line contains *n* integers *x**i* (1<=≤<=*x**i*<=≤<=100<=000) — prices of the bottles of the drink in the *i*-th shop.
The third line contains a single integer *q* (1<=≤<=*q*<=≤<=100<=000) — the number of days Vasiliy plans to buy the drink.
Then follow *q* lines each containing one integer *m**i* (1<=≤<=*m**i*<=≤<=109) — the number of coins Vasiliy can spent on the *i*-th day.
Output Specification:
Print *q* integers. The *i*-th of them should be equal to the number of shops where Vasiliy will be able to buy a bottle of the drink on the *i*-th day.
Demo Input:
['5\n3 10 8 6 11\n4\n1\n10\n3\n11\n']
Demo Output:
['0\n4\n1\n5\n']
Note:
On the first day, Vasiliy won't be able to buy a drink in any of the shops.
On the second day, Vasiliy can buy a drink in the shops 1, 2, 3 and 4.
On the third day, Vasiliy can buy a drink only in the shop number 1.
Finally, on the last day Vasiliy can buy a drink in any shop. | ```python
numberofshops = int(input())
allprices = input()
allprices = allprices.split()
drinkdays = int(input())
for x in range (0, drinkdays):
globals()['budget%s' % x] = input()
driinnnng = int(0)
for y in range(0, drinkdays):
for z in range(0,numberofshops):
if (int(allprices[z]) <= int(globals()['budget%s' % y])):
driinnnng += 1
print(driinnnng)
driinnnng = int(0)
``` | 0 | |
169 | A | Chores | PROGRAMMING | 800 | [
"sortings"
] | null | null | Petya and Vasya are brothers. Today is a special day for them as their parents left them home alone and commissioned them to do *n* chores. Each chore is characterized by a single parameter — its complexity. The complexity of the *i*-th chore equals *h**i*.
As Petya is older, he wants to take the chores with complexity larger than some value *x* (*h**i*<=><=*x*) to leave to Vasya the chores with complexity less than or equal to *x* (*h**i*<=≤<=*x*). The brothers have already decided that Petya will do exactly *a* chores and Vasya will do exactly *b* chores (*a*<=+<=*b*<==<=*n*).
In how many ways can they choose an integer *x* so that Petya got exactly *a* chores and Vasya got exactly *b* chores? | The first input line contains three integers *n*,<=*a* and *b* (2<=≤<=*n*<=≤<=2000; *a*,<=*b*<=≥<=1; *a*<=+<=*b*<==<=*n*) — the total number of chores, the number of Petya's chores and the number of Vasya's chores.
The next line contains a sequence of integers *h*1,<=*h*2,<=...,<=*h**n* (1<=≤<=*h**i*<=≤<=109), *h**i* is the complexity of the *i*-th chore. The numbers in the given sequence are not necessarily different.
All numbers on the lines are separated by single spaces. | Print the required number of ways to choose an integer value of *x*. If there are no such ways, print 0. | [
"5 2 3\n6 2 3 100 1\n",
"7 3 4\n1 1 9 1 1 1 1\n"
] | [
"3\n",
"0\n"
] | In the first sample the possible values of *x* are 3, 4 or 5.
In the second sample it is impossible to find such *x*, that Petya got 3 chores and Vasya got 4. | 500 | [
{
"input": "5 2 3\n6 2 3 100 1",
"output": "3"
},
{
"input": "7 3 4\n1 1 9 1 1 1 1",
"output": "0"
},
{
"input": "2 1 1\n10 2",
"output": "8"
},
{
"input": "2 1 1\n7 7",
"output": "0"
},
{
"input": "2 1 1\n1 1000000000",
"output": "999999999"
},
{
"input": "3 1 2\n6 5 5",
"output": "1"
},
{
"input": "3 2 1\n10 10 8",
"output": "2"
},
{
"input": "8 3 5\n42 55 61 72 83 10 22 33",
"output": "6"
},
{
"input": "10 5 5\n1 2 3 4 5 999999999 999999998 999999997 999999996 999999995",
"output": "999999990"
},
{
"input": "4 1 3\n10 8 7 3",
"output": "2"
},
{
"input": "4 2 2\n402 10 10 402",
"output": "392"
},
{
"input": "4 1 3\n10 402 402 10",
"output": "0"
},
{
"input": "4 3 1\n100 100 200 200",
"output": "0"
},
{
"input": "150 10 140\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 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 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": "0"
},
{
"input": "102 101 1\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 1 1",
"output": "0"
}
] | 1,629,726,048 | 2,147,483,647 | Python 3 | OK | TESTS | 29 | 77 | 6,963,200 | n,a,b = map(int,input().split())
l = list(map(int,input().split()))
l.sort()
a = l[b]-l[b-1]
if(a>0):
print(a)
else:
print(0) | Title: Chores
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya and Vasya are brothers. Today is a special day for them as their parents left them home alone and commissioned them to do *n* chores. Each chore is characterized by a single parameter — its complexity. The complexity of the *i*-th chore equals *h**i*.
As Petya is older, he wants to take the chores with complexity larger than some value *x* (*h**i*<=><=*x*) to leave to Vasya the chores with complexity less than or equal to *x* (*h**i*<=≤<=*x*). The brothers have already decided that Petya will do exactly *a* chores and Vasya will do exactly *b* chores (*a*<=+<=*b*<==<=*n*).
In how many ways can they choose an integer *x* so that Petya got exactly *a* chores and Vasya got exactly *b* chores?
Input Specification:
The first input line contains three integers *n*,<=*a* and *b* (2<=≤<=*n*<=≤<=2000; *a*,<=*b*<=≥<=1; *a*<=+<=*b*<==<=*n*) — the total number of chores, the number of Petya's chores and the number of Vasya's chores.
The next line contains a sequence of integers *h*1,<=*h*2,<=...,<=*h**n* (1<=≤<=*h**i*<=≤<=109), *h**i* is the complexity of the *i*-th chore. The numbers in the given sequence are not necessarily different.
All numbers on the lines are separated by single spaces.
Output Specification:
Print the required number of ways to choose an integer value of *x*. If there are no such ways, print 0.
Demo Input:
['5 2 3\n6 2 3 100 1\n', '7 3 4\n1 1 9 1 1 1 1\n']
Demo Output:
['3\n', '0\n']
Note:
In the first sample the possible values of *x* are 3, 4 or 5.
In the second sample it is impossible to find such *x*, that Petya got 3 chores and Vasya got 4. | ```python
n,a,b = map(int,input().split())
l = list(map(int,input().split()))
l.sort()
a = l[b]-l[b-1]
if(a>0):
print(a)
else:
print(0)
``` | 3 | |
254 | A | Cards with Numbers | PROGRAMMING | 1,200 | [
"constructive algorithms",
"sortings"
] | null | null | Petya has got 2*n* cards, each card contains some integer. The numbers on the cards can be the same. Let's index all cards by consecutive integers from 1 to 2*n*. We'll denote the number that is written on a card with number *i*, as *a**i*. In order to play one entertaining game with his friends, Petya needs to split the cards into pairs so that each pair had equal numbers on the cards. Help Petya do that. | The first line contains integer *n* (1<=≤<=*n*<=≤<=3·105). The second line contains the sequence of 2*n* positive integers *a*1,<=*a*2,<=...,<=*a*2*n* (1<=≤<=*a**i*<=≤<=5000) — the numbers that are written on the cards. The numbers on the line are separated by single spaces. | If it is impossible to divide the cards into pairs so that cards in each pair had the same numbers, print on a single line integer -1. But if the required partition exists, then print *n* pairs of integers, a pair per line — the indices of the cards that form the pairs.
Separate the numbers on the lines by spaces. You can print the pairs and the numbers in the pairs in any order. If there are multiple solutions, print any of them. | [
"3\n20 30 10 30 20 10\n",
"1\n1 2\n"
] | [
"4 2\n1 5\n6 3\n",
"-1"
] | none | 500 | [
{
"input": "3\n20 30 10 30 20 10",
"output": "4 2\n1 5\n6 3"
},
{
"input": "1\n1 2",
"output": "-1"
},
{
"input": "5\n2 2 2 2 2 1 2 2 1 2",
"output": "2 1\n3 4\n7 5\n6 9\n10 8"
},
{
"input": "5\n2 1 2 2 1 1 1 1 1 2",
"output": "3 1\n2 5\n7 6\n8 9\n10 4"
},
{
"input": "5\n1 2 2 2 1 2 2 1 2 1",
"output": "3 2\n1 5\n6 4\n7 9\n10 8"
},
{
"input": "5\n3 3 1 1 1 3 2 3 1 2",
"output": "2 1\n3 4\n8 6\n5 9\n10 7"
},
{
"input": "5\n1 1 3 1 3 3 3 1 1 1",
"output": "2 1\n3 5\n7 6\n4 8\n10 9"
},
{
"input": "5\n3 1 1 1 2 3 3 3 2 1",
"output": "3 2\n1 6\n8 7\n5 9\n10 4"
},
{
"input": "5\n3 3 2 2 3 3 1 3 1 3",
"output": "2 1\n3 4\n6 5\n7 9\n10 8"
},
{
"input": "5\n4 1 3 1 4 1 2 2 3 1",
"output": "4 2\n1 5\n8 7\n3 9\n10 6"
},
{
"input": "100\n8 6 7 8 7 9 1 7 3 3 5 8 7 8 5 4 8 4 8 1 2 8 3 7 8 7 6 5 7 9 6 10 7 6 7 8 6 8 9 5 1 5 6 1 4 8 4 8 7 2 6 2 6 6 2 8 2 8 7 1 5 4 4 6 4 9 7 5 1 8 1 3 9 2 3 2 4 7 6 10 5 3 4 10 8 9 6 7 2 7 10 1 8 10 4 1 1 1 2 7 5 4 9 10 6 8 3 1 10 9 9 6 1 5 8 6 6 3 3 4 10 10 8 9 7 10 9 3 7 6 3 2 10 8 5 8 5 5 5 10 8 5 7 6 10 7 7 9 10 10 9 9 3 6 5 6 8 1 9 8 2 4 8 8 6 8 10 2 3 5 2 6 8 4 8 6 4 5 10 8 1 10 5 2 5 6 8 2 6 8 1 3 4 5 7 5 6 9 2 8",
"output": "4 1\n3 5\n10 9\n8 13\n14 12\n11 15\n18 16\n17 19\n20 7\n22 25\n26 24\n2 27\n30 6\n29 33\n34 31\n36 38\n40 28\n37 43\n44 41\n45 47\n48 46\n35 49\n50 21\n51 53\n55 52\n56 58\n61 42\n62 63\n64 54\n39 66\n67 59\n60 69\n72 23\n57 74\n77 65\n32 80\n81 68\n75 82\n85 70\n73 86\n87 79\n78 88\n89 76\n84 91\n92 71\n83 95\n97 96\n90 100\n104 94\n93 106\n108 98\n103 110\n112 105\n101 114\n117 116\n107 118\n120 102\n109 121\n123 115\n111 124\n126 122\n119 128\n129 125\n99 132\n136 134\n135 137\n139 138\n133 140\n144 130..."
},
{
"input": "100\n7 3 8 8 1 9 6 6 3 3 8 2 7 9 9 10 2 10 4 4 9 3 6 5 2 6 3 6 3 5 2 3 8 2 5 10 3 9 7 2 1 6 7 4 8 3 9 10 9 4 3 3 7 1 4 2 2 5 6 6 1 7 9 1 8 1 2 2 5 9 7 7 6 4 6 10 1 1 8 1 5 6 4 9 5 4 4 10 6 4 5 1 9 1 7 8 6 10 3 2 4 7 10 4 8 10 6 7 8 4 1 3 8 3 2 1 9 4 2 4 3 1 6 8 6 2 2 5 6 8 6 10 1 6 4 2 7 3 6 10 6 5 6 6 3 9 4 6 4 1 5 4 4 2 8 4 10 3 7 6 6 10 2 5 5 6 1 6 1 9 9 1 10 5 10 1 1 5 7 5 2 1 4 2 3 3 3 5 1 8 10 3 3 5 9 6 3 6 8 1",
"output": "4 3\n7 8\n9 2\n1 13\n14 6\n12 17\n18 16\n19 20\n21 15\n10 22\n26 23\n27 29\n30 24\n25 31\n33 11\n32 37\n40 34\n5 41\n42 28\n39 43\n47 38\n36 48\n50 44\n46 51\n57 56\n35 58\n60 59\n54 61\n62 53\n49 63\n65 45\n64 66\n68 67\n71 72\n74 55\n73 75\n78 77\n69 81\n84 70\n83 86\n88 76\n82 89\n90 87\n85 91\n92 80\n79 96\n99 52\n95 102\n103 98\n101 104\n107 97\n105 109\n111 94\n112 114\n115 100\n93 117\n118 110\n116 122\n124 113\n123 125\n126 119\n129 131\n132 106\n120 135\n136 127\n108 137\n138 121\n134 139\n142 128..."
},
{
"input": "100\n6 3 6 8 8 4 3 7 10 3 1 3 9 5 10 10 6 7 6 6 2 3 8 8 7 6 4 9 6 7 4 4 10 4 7 3 2 7 10 8 6 7 9 1 3 5 3 7 9 1 1 7 1 1 7 7 8 3 2 7 4 8 7 8 10 3 1 7 2 7 9 8 8 8 5 2 8 1 2 7 8 7 8 8 5 10 10 4 9 10 8 7 8 8 7 7 3 6 4 3 4 8 10 8 6 3 7 1 8 6 3 3 7 10 3 9 3 5 10 9 9 2 8 7 2 3 2 1 10 9 6 2 8 7 2 2 5 3 10 6 7 2 1 1 5 10 7 5 4 9 7 7 8 1 1 3 3 7 10 5 9 8 6 8 2 2 1 7 8 9 6 2 2 6 2 9 10 2 10 9 6 3 3 10 6 5 3 6 6 3 6 10 8 7 4 8 6 3 4 7",
"output": "-1"
},
{
"input": "1\n2 2",
"output": "2 1"
},
{
"input": "2\n1 2 4 7",
"output": "-1"
}
] | 1,628,259,165 | 2,147,483,647 | PyPy 3 | RUNTIME_ERROR | TESTS | 0 | 124 | 22,220,800 | import sys
import math
from collections import Counter
# n = int(input())
# a = list(map(int, input().split()))
n = int(input())
a = [[i, int(c)] for (i, c) in enumerate(input().split())]
a.sort(key = lambda u : u[1])
possible = True
res = []
for i in range(1, 2 * n , 2) :
if a[i][1] != a[i - 1][1] :
possible = False
break
else :
res.append([a[i][0] + 1, a[i - 1][0] + 1])
if possible :
for i in res :
print(i[0], i[1])
else :
print(-1)
| Title: Cards with Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya has got 2*n* cards, each card contains some integer. The numbers on the cards can be the same. Let's index all cards by consecutive integers from 1 to 2*n*. We'll denote the number that is written on a card with number *i*, as *a**i*. In order to play one entertaining game with his friends, Petya needs to split the cards into pairs so that each pair had equal numbers on the cards. Help Petya do that.
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=3·105). The second line contains the sequence of 2*n* positive integers *a*1,<=*a*2,<=...,<=*a*2*n* (1<=≤<=*a**i*<=≤<=5000) — the numbers that are written on the cards. The numbers on the line are separated by single spaces.
Output Specification:
If it is impossible to divide the cards into pairs so that cards in each pair had the same numbers, print on a single line integer -1. But if the required partition exists, then print *n* pairs of integers, a pair per line — the indices of the cards that form the pairs.
Separate the numbers on the lines by spaces. You can print the pairs and the numbers in the pairs in any order. If there are multiple solutions, print any of them.
Demo Input:
['3\n20 30 10 30 20 10\n', '1\n1 2\n']
Demo Output:
['4 2\n1 5\n6 3\n', '-1']
Note:
none | ```python
import sys
import math
from collections import Counter
# n = int(input())
# a = list(map(int, input().split()))
n = int(input())
a = [[i, int(c)] for (i, c) in enumerate(input().split())]
a.sort(key = lambda u : u[1])
possible = True
res = []
for i in range(1, 2 * n , 2) :
if a[i][1] != a[i - 1][1] :
possible = False
break
else :
res.append([a[i][0] + 1, a[i - 1][0] + 1])
if possible :
for i in res :
print(i[0], i[1])
else :
print(-1)
``` | -1 | |
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"
}
] | 1,481,291,742 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 92 | 0 | n=int(input())
k=[]
l=[int(i) for i in input().split()]
for i in l:
i=i%2
k.append(i)
if l.count(0)>l.count(1):
print(l.index(1)+1)
else:
print(k.index(0)+1)
| 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
n=int(input())
k=[]
l=[int(i) for i in input().split()]
for i in l:
i=i%2
k.append(i)
if l.count(0)>l.count(1):
print(l.index(1)+1)
else:
print(k.index(0)+1)
``` | 0 |
681 | B | Economy Game | PROGRAMMING | 1,300 | [
"brute force"
] | null | null | Kolya is developing an economy simulator game. His most favourite part of the development process is in-game testing. Once he was entertained by the testing so much, that he found out his game-coin score become equal to 0.
Kolya remembers that at the beginning of the game his game-coin score was equal to *n* and that he have bought only some houses (for 1<=234<=567 game-coins each), cars (for 123<=456 game-coins each) and computers (for 1<=234 game-coins each).
Kolya is now interested, whether he could have spent all of his initial *n* game-coins buying only houses, cars and computers or there is a bug in the game. Formally, is there a triple of non-negative integers *a*, *b* and *c* such that *a*<=×<=1<=234<=567<=+<=*b*<=×<=123<=456<=+<=*c*<=×<=1<=234<==<=*n*?
Please help Kolya answer this question. | The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=109) — Kolya's initial game-coin score. | Print "YES" (without quotes) if it's possible that Kolya spent all of his initial *n* coins buying only houses, cars and computers. Otherwise print "NO" (without quotes). | [
"1359257\n",
"17851817\n"
] | [
"YES",
"NO"
] | In the first sample, one of the possible solutions is to buy one house, one car and one computer, spending 1 234 567 + 123 456 + 1234 = 1 359 257 game-coins in total. | 1,000 | [
{
"input": "1359257",
"output": "YES"
},
{
"input": "17851817",
"output": "NO"
},
{
"input": "1000000000",
"output": "YES"
},
{
"input": "17851818",
"output": "YES"
},
{
"input": "438734347",
"output": "YES"
},
{
"input": "43873430",
"output": "YES"
},
{
"input": "999999987",
"output": "YES"
},
{
"input": "27406117",
"output": "NO"
},
{
"input": "27404883",
"output": "NO"
},
{
"input": "27403649",
"output": "NO"
},
{
"input": "27402415",
"output": "NO"
},
{
"input": "27401181",
"output": "NO"
},
{
"input": "999999999",
"output": "YES"
},
{
"input": "999999244",
"output": "YES"
},
{
"input": "999129999",
"output": "YES"
},
{
"input": "17159199",
"output": "NO"
},
{
"input": "13606913",
"output": "NO"
},
{
"input": "14841529",
"output": "NO"
},
{
"input": "915968473",
"output": "YES"
},
{
"input": "980698615",
"output": "YES"
},
{
"input": "912331505",
"output": "YES"
},
{
"input": "917261049",
"output": "YES"
},
{
"input": "999999997",
"output": "YES"
},
{
"input": "12345",
"output": "NO"
},
{
"input": "1234",
"output": "YES"
},
{
"input": "124690",
"output": "YES"
},
{
"input": "1359257",
"output": "YES"
},
{
"input": "1358023",
"output": "YES"
},
{
"input": "1234",
"output": "YES"
},
{
"input": "1234567",
"output": "YES"
},
{
"input": "124690",
"output": "YES"
},
{
"input": "1358023",
"output": "YES"
},
{
"input": "123456",
"output": "YES"
},
{
"input": "2592590",
"output": "YES"
},
{
"input": "999999998",
"output": "YES"
},
{
"input": "1356789",
"output": "NO"
},
{
"input": "12345670",
"output": "YES"
},
{
"input": "11",
"output": "NO"
},
{
"input": "1480800",
"output": "YES"
},
{
"input": "908000000",
"output": "YES"
},
{
"input": "3000",
"output": "NO"
},
{
"input": "1235801",
"output": "YES"
},
{
"input": "991919191",
"output": "YES"
},
{
"input": "25613715",
"output": "YES"
},
{
"input": "13580237",
"output": "YES"
},
{
"input": "14814804",
"output": "YES"
},
{
"input": "11403961",
"output": "YES"
},
{
"input": "999999989",
"output": "YES"
},
{
"input": "1237035",
"output": "YES"
},
{
"input": "81134231",
"output": "YES"
},
{
"input": "1236",
"output": "NO"
},
{
"input": "1359250",
"output": "YES"
},
{
"input": "100",
"output": "NO"
},
{
"input": "987654321",
"output": "YES"
},
{
"input": "122222",
"output": "NO"
},
{
"input": "123458",
"output": "NO"
},
{
"input": "20987639",
"output": "YES"
},
{
"input": "999973333",
"output": "YES"
},
{
"input": "253082",
"output": "YES"
},
{
"input": "1235",
"output": "NO"
},
{
"input": "803219200",
"output": "YES"
},
{
"input": "100000000",
"output": "YES"
},
{
"input": "1485181",
"output": "YES"
}
] | 1,679,529,612 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 0 | 30 | 0 | valor = int(input())
result = "NO"
for num in range(0, valor+1, 1234567):
for val in range(0, valor-num+1, 123456):
if (valor-num-val) % 1234 == 0:
result = "YES"
exit()
print(result)
| Title: Economy Game
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Kolya is developing an economy simulator game. His most favourite part of the development process is in-game testing. Once he was entertained by the testing so much, that he found out his game-coin score become equal to 0.
Kolya remembers that at the beginning of the game his game-coin score was equal to *n* and that he have bought only some houses (for 1<=234<=567 game-coins each), cars (for 123<=456 game-coins each) and computers (for 1<=234 game-coins each).
Kolya is now interested, whether he could have spent all of his initial *n* game-coins buying only houses, cars and computers or there is a bug in the game. Formally, is there a triple of non-negative integers *a*, *b* and *c* such that *a*<=×<=1<=234<=567<=+<=*b*<=×<=123<=456<=+<=*c*<=×<=1<=234<==<=*n*?
Please help Kolya answer this question.
Input Specification:
The first line of the input contains a single integer *n* (1<=≤<=*n*<=≤<=109) — Kolya's initial game-coin score.
Output Specification:
Print "YES" (without quotes) if it's possible that Kolya spent all of his initial *n* coins buying only houses, cars and computers. Otherwise print "NO" (without quotes).
Demo Input:
['1359257\n', '17851817\n']
Demo Output:
['YES', 'NO']
Note:
In the first sample, one of the possible solutions is to buy one house, one car and one computer, spending 1 234 567 + 123 456 + 1234 = 1 359 257 game-coins in total. | ```python
valor = int(input())
result = "NO"
for num in range(0, valor+1, 1234567):
for val in range(0, valor-num+1, 123456):
if (valor-num-val) % 1234 == 0:
result = "YES"
exit()
print(result)
``` | 0 | |
0 | none | none | none | 0 | [
"none"
] | null | null | You are given two squares, one with sides parallel to the coordinate axes, and another one with sides at 45 degrees to the coordinate axes. Find whether the two squares intersect.
The interior of the square is considered to be part of the square, i.e. if one square is completely inside another, they intersect. If the two squares only share one common point, they are also considered to intersect. | The input data consists of two lines, one for each square, both containing 4 pairs of integers. Each pair represents coordinates of one vertex of the square. Coordinates within each line are either in clockwise or counterclockwise order.
The first line contains the coordinates of the square with sides parallel to the coordinate axes, the second line contains the coordinates of the square at 45 degrees.
All the values are integer and between $-100$ and $100$. | Print "Yes" if squares intersect, otherwise print "No".
You can print each letter in any case (upper or lower). | [
"0 0 6 0 6 6 0 6\n1 3 3 5 5 3 3 1\n",
"0 0 6 0 6 6 0 6\n7 3 9 5 11 3 9 1\n",
"6 0 6 6 0 6 0 0\n7 4 4 7 7 10 10 7\n"
] | [
"YES\n",
"NO\n",
"YES\n"
] | In the first example the second square lies entirely within the first square, so they do intersect.
In the second sample squares do not have any points in common.
Here are images corresponding to the samples: | 0 | [
{
"input": "0 0 6 0 6 6 0 6\n1 3 3 5 5 3 3 1",
"output": "YES"
},
{
"input": "0 0 6 0 6 6 0 6\n7 3 9 5 11 3 9 1",
"output": "NO"
},
{
"input": "6 0 6 6 0 6 0 0\n7 4 4 7 7 10 10 7",
"output": "YES"
},
{
"input": "0 0 6 0 6 6 0 6\n8 4 4 8 8 12 12 8",
"output": "YES"
},
{
"input": "2 2 4 2 4 4 2 4\n0 3 3 6 6 3 3 0",
"output": "YES"
},
{
"input": "-5 -5 5 -5 5 5 -5 5\n-5 7 0 2 5 7 0 12",
"output": "YES"
},
{
"input": "-5 -5 5 -5 5 5 -5 5\n-5 12 0 7 5 12 0 17",
"output": "NO"
},
{
"input": "-5 -5 5 -5 5 5 -5 5\n6 0 0 6 -6 0 0 -6",
"output": "YES"
},
{
"input": "-100 -100 100 -100 100 100 -100 100\n-100 0 0 -100 100 0 0 100",
"output": "YES"
},
{
"input": "92 1 92 98 -5 98 -5 1\n44 60 56 48 44 36 32 48",
"output": "YES"
},
{
"input": "-12 -54 -12 33 -99 33 -99 -54\n-77 -40 -86 -31 -77 -22 -68 -31",
"output": "YES"
},
{
"input": "3 45 19 45 19 61 3 61\n-29 45 -13 29 3 45 -13 61",
"output": "YES"
},
{
"input": "79 -19 79 15 45 15 45 -19\n-1 24 -29 52 -1 80 27 52",
"output": "NO"
},
{
"input": "75 -57 75 -21 39 -21 39 -57\n10 -42 -32 0 10 42 52 0",
"output": "NO"
},
{
"input": "-11 53 9 53 9 73 -11 73\n-10 9 -43 42 -10 75 23 42",
"output": "YES"
},
{
"input": "-10 -36 -10 27 -73 27 -73 -36\n44 -28 71 -55 44 -82 17 -55",
"output": "NO"
},
{
"input": "-63 -15 6 -15 6 54 -63 54\n15 -13 -8 10 15 33 38 10",
"output": "YES"
},
{
"input": "47 15 51 15 51 19 47 19\n19 0 -27 46 19 92 65 46",
"output": "NO"
},
{
"input": "87 -5 87 79 3 79 3 -5\n36 36 78 -6 36 -48 -6 -6",
"output": "YES"
},
{
"input": "-4 56 10 56 10 70 -4 70\n-11 47 -35 71 -11 95 13 71",
"output": "YES"
},
{
"input": "-41 6 -41 8 -43 8 -43 6\n-7 27 43 -23 -7 -73 -57 -23",
"output": "NO"
},
{
"input": "44 -58 44 7 -21 7 -21 -58\n22 19 47 -6 22 -31 -3 -6",
"output": "YES"
},
{
"input": "-37 -63 49 -63 49 23 -37 23\n-52 68 -21 37 -52 6 -83 37",
"output": "YES"
},
{
"input": "93 20 93 55 58 55 58 20\n61 -17 39 5 61 27 83 5",
"output": "YES"
},
{
"input": "-7 4 -7 58 -61 58 -61 4\n-28 45 -17 34 -28 23 -39 34",
"output": "YES"
},
{
"input": "24 -79 87 -79 87 -16 24 -16\n-59 21 -85 47 -59 73 -33 47",
"output": "NO"
},
{
"input": "-68 -15 6 -15 6 59 -68 59\n48 -18 57 -27 48 -36 39 -27",
"output": "NO"
},
{
"input": "25 1 25 91 -65 91 -65 1\n24 3 15 12 24 21 33 12",
"output": "YES"
},
{
"input": "55 24 73 24 73 42 55 42\n49 17 10 56 49 95 88 56",
"output": "YES"
},
{
"input": "69 -65 69 -28 32 -28 32 -65\n-1 50 43 6 -1 -38 -45 6",
"output": "NO"
},
{
"input": "86 -26 86 18 42 18 42 -26\n3 -22 -40 21 3 64 46 21",
"output": "YES"
},
{
"input": "52 -47 52 -30 35 -30 35 -47\n49 -22 64 -37 49 -52 34 -37",
"output": "YES"
},
{
"input": "27 -59 27 9 -41 9 -41 -59\n-10 -17 2 -29 -10 -41 -22 -29",
"output": "YES"
},
{
"input": "-90 2 0 2 0 92 -90 92\n-66 31 -86 51 -66 71 -46 51",
"output": "YES"
},
{
"input": "-93 -86 -85 -86 -85 -78 -93 -78\n-13 61 0 48 -13 35 -26 48",
"output": "NO"
},
{
"input": "-3 -45 85 -45 85 43 -3 43\n-22 0 -66 44 -22 88 22 44",
"output": "YES"
},
{
"input": "-27 -73 72 -73 72 26 -27 26\n58 11 100 -31 58 -73 16 -31",
"output": "YES"
},
{
"input": "-40 -31 8 -31 8 17 -40 17\n0 18 -35 53 0 88 35 53",
"output": "NO"
},
{
"input": "-15 -63 -15 7 -85 7 -85 -63\n-35 -40 -33 -42 -35 -44 -37 -42",
"output": "YES"
},
{
"input": "-100 -100 -100 100 100 100 100 -100\n-100 0 0 100 100 0 0 -100",
"output": "YES"
},
{
"input": "67 33 67 67 33 67 33 33\n43 11 9 45 43 79 77 45",
"output": "YES"
},
{
"input": "14 8 9 8 9 3 14 3\n-2 -13 14 3 30 -13 14 -29",
"output": "YES"
},
{
"input": "4 3 7 3 7 6 4 6\n7 29 20 16 7 3 -6 16",
"output": "YES"
},
{
"input": "14 30 3 30 3 19 14 19\n19 -13 11 -5 19 3 27 -5",
"output": "NO"
},
{
"input": "-54 3 -50 3 -50 -1 -54 -1\n3 -50 -6 -41 -15 -50 -6 -59",
"output": "NO"
},
{
"input": "3 8 3 -10 21 -10 21 8\n-9 2 -21 -10 -9 -22 3 -10",
"output": "YES"
},
{
"input": "-35 3 -21 3 -21 -11 -35 -11\n-8 -10 3 -21 -8 -32 -19 -21",
"output": "NO"
},
{
"input": "-5 -23 -5 -31 3 -31 3 -23\n-7 -23 -2 -28 3 -23 -2 -18",
"output": "YES"
},
{
"input": "3 20 10 20 10 13 3 13\n3 20 21 38 39 20 21 2",
"output": "YES"
},
{
"input": "25 3 16 3 16 12 25 12\n21 -2 16 -7 11 -2 16 3",
"output": "YES"
},
{
"input": "-1 18 -1 3 14 3 14 18\n14 3 19 8 14 13 9 8",
"output": "YES"
},
{
"input": "-44 -17 -64 -17 -64 3 -44 3\n-56 15 -44 27 -32 15 -44 3",
"output": "YES"
},
{
"input": "17 3 2 3 2 18 17 18\n22 23 2 3 -18 23 2 43",
"output": "YES"
},
{
"input": "3 -22 3 -36 -11 -36 -11 -22\n11 -44 19 -36 11 -28 3 -36",
"output": "YES"
},
{
"input": "3 45 3 48 0 48 0 45\n13 38 4 47 13 56 22 47",
"output": "NO"
},
{
"input": "3 -10 2 -10 2 -9 3 -9\n38 -10 20 -28 2 -10 20 8",
"output": "YES"
},
{
"input": "-66 3 -47 3 -47 22 -66 22\n-52 -2 -45 5 -52 12 -59 5",
"output": "YES"
},
{
"input": "3 37 -1 37 -1 41 3 41\n6 31 9 34 6 37 3 34",
"output": "NO"
},
{
"input": "13 1 15 1 15 3 13 3\n13 19 21 11 13 3 5 11",
"output": "YES"
},
{
"input": "20 8 3 8 3 -9 20 -9\n2 -11 3 -10 2 -9 1 -10",
"output": "NO"
},
{
"input": "3 41 3 21 -17 21 -17 41\n26 12 10 28 26 44 42 28",
"output": "NO"
},
{
"input": "11 11 11 3 3 3 3 11\n-12 26 -27 11 -12 -4 3 11",
"output": "YES"
},
{
"input": "-29 3 -29 12 -38 12 -38 3\n-35 9 -29 15 -23 9 -29 3",
"output": "YES"
},
{
"input": "3 -32 1 -32 1 -30 3 -30\n4 -32 -16 -52 -36 -32 -16 -12",
"output": "YES"
},
{
"input": "-16 -10 -16 9 3 9 3 -10\n-8 -1 2 9 12 -1 2 -11",
"output": "YES"
},
{
"input": "3 -42 -5 -42 -5 -34 3 -34\n-8 -54 -19 -43 -8 -32 3 -43",
"output": "YES"
},
{
"input": "-47 3 -37 3 -37 -7 -47 -7\n-37 3 -33 -1 -37 -5 -41 -1",
"output": "YES"
},
{
"input": "10 3 12 3 12 5 10 5\n12 4 20 12 12 20 4 12",
"output": "YES"
},
{
"input": "3 -41 -9 -41 -9 -53 3 -53\n18 -16 38 -36 18 -56 -2 -36",
"output": "YES"
},
{
"input": "3 40 2 40 2 41 3 41\n22 39 13 48 4 39 13 30",
"output": "NO"
},
{
"input": "21 26 21 44 3 44 3 26\n-20 38 -32 26 -20 14 -8 26",
"output": "NO"
},
{
"input": "0 7 3 7 3 10 0 10\n3 9 -17 29 -37 9 -17 -11",
"output": "YES"
},
{
"input": "3 21 3 18 6 18 6 21\n-27 18 -11 2 5 18 -11 34",
"output": "YES"
},
{
"input": "-29 13 -39 13 -39 3 -29 3\n-36 -4 -50 -18 -36 -32 -22 -18",
"output": "NO"
},
{
"input": "3 -26 -2 -26 -2 -21 3 -21\n-5 -37 -16 -26 -5 -15 6 -26",
"output": "YES"
},
{
"input": "3 9 -1 9 -1 13 3 13\n-9 17 -1 9 -9 1 -17 9",
"output": "YES"
},
{
"input": "48 8 43 8 43 3 48 3\n31 -4 43 8 55 -4 43 -16",
"output": "YES"
},
{
"input": "-3 1 3 1 3 -5 -3 -5\n20 -22 3 -5 20 12 37 -5",
"output": "YES"
},
{
"input": "14 3 14 -16 -5 -16 -5 3\n14 2 15 1 14 0 13 1",
"output": "YES"
},
{
"input": "-10 12 -10 -1 3 -1 3 12\n1 10 -2 7 -5 10 -2 13",
"output": "YES"
},
{
"input": "39 21 21 21 21 3 39 3\n27 3 47 -17 27 -37 7 -17",
"output": "YES"
},
{
"input": "3 1 3 17 -13 17 -13 1\n17 20 10 27 3 20 10 13",
"output": "NO"
},
{
"input": "15 -18 3 -18 3 -6 15 -6\n29 -1 16 -14 3 -1 16 12",
"output": "YES"
},
{
"input": "41 -6 41 3 32 3 32 -6\n33 3 35 5 33 7 31 5",
"output": "YES"
},
{
"input": "7 35 3 35 3 39 7 39\n23 15 3 35 23 55 43 35",
"output": "YES"
},
{
"input": "19 19 35 19 35 3 19 3\n25 -9 16 -18 7 -9 16 0",
"output": "NO"
},
{
"input": "-20 3 -20 9 -26 9 -26 3\n-19 4 -21 2 -19 0 -17 2",
"output": "YES"
},
{
"input": "13 3 22 3 22 -6 13 -6\n26 3 22 -1 18 3 22 7",
"output": "YES"
},
{
"input": "-4 -8 -4 -15 3 -15 3 -8\n-10 5 -27 -12 -10 -29 7 -12",
"output": "YES"
},
{
"input": "3 15 7 15 7 19 3 19\n-12 30 -23 19 -12 8 -1 19",
"output": "NO"
},
{
"input": "-12 3 5 3 5 -14 -12 -14\n-14 22 5 3 24 22 5 41",
"output": "YES"
},
{
"input": "-37 3 -17 3 -17 -17 -37 -17\n-9 -41 9 -23 -9 -5 -27 -23",
"output": "YES"
},
{
"input": "3 57 3 45 -9 45 -9 57\n8 50 21 37 8 24 -5 37",
"output": "YES"
},
{
"input": "42 3 42 -6 33 -6 33 3\n42 4 41 3 40 4 41 5",
"output": "YES"
},
{
"input": "3 59 3 45 -11 45 -11 59\n-2 50 -8 44 -2 38 4 44",
"output": "YES"
},
{
"input": "-51 3 -39 3 -39 15 -51 15\n-39 14 -53 0 -39 -14 -25 0",
"output": "YES"
},
{
"input": "-7 -15 -7 3 11 3 11 -15\n15 -1 22 -8 15 -15 8 -8",
"output": "YES"
},
{
"input": "3 -39 14 -39 14 -50 3 -50\n17 -39 5 -27 -7 -39 5 -51",
"output": "YES"
},
{
"input": "91 -27 91 29 35 29 35 -27\n59 39 95 3 59 -33 23 3",
"output": "YES"
},
{
"input": "-81 -60 -31 -60 -31 -10 -81 -10\n-58 -68 -95 -31 -58 6 -21 -31",
"output": "YES"
},
{
"input": "78 -59 78 -2 21 -2 21 -59\n48 1 86 -37 48 -75 10 -37",
"output": "YES"
},
{
"input": "-38 -26 32 -26 32 44 -38 44\n2 -27 -44 19 2 65 48 19",
"output": "YES"
},
{
"input": "73 -54 73 -4 23 -4 23 -54\n47 1 77 -29 47 -59 17 -29",
"output": "YES"
},
{
"input": "-6 -25 46 -25 46 27 -6 27\n21 -43 -21 -1 21 41 63 -1",
"output": "YES"
},
{
"input": "-17 -91 -17 -27 -81 -27 -81 -91\n-48 -21 -12 -57 -48 -93 -84 -57",
"output": "YES"
},
{
"input": "-7 16 43 16 43 66 -7 66\n18 -7 -27 38 18 83 63 38",
"output": "YES"
},
{
"input": "-46 11 16 11 16 73 -46 73\n-18 -8 -67 41 -18 90 31 41",
"output": "YES"
},
{
"input": "-33 -64 25 -64 25 -6 -33 -6\n-5 -74 -51 -28 -5 18 41 -28",
"output": "YES"
},
{
"input": "99 -100 100 -100 100 -99 99 -99\n99 -99 100 -98 99 -97 98 -98",
"output": "YES"
},
{
"input": "-100 -100 -100 -99 -99 -99 -99 -100\n-10 -10 -9 -9 -10 -8 -11 -9",
"output": "NO"
},
{
"input": "-4 3 -3 3 -3 4 -4 4\n0 -4 4 0 0 4 -4 0",
"output": "NO"
},
{
"input": "0 0 10 0 10 10 0 10\n11 9 13 7 15 9 13 11",
"output": "NO"
},
{
"input": "1 1 1 6 6 6 6 1\n5 8 8 11 11 8 8 5",
"output": "NO"
},
{
"input": "99 99 99 100 100 100 100 99\n-100 0 0 100 100 0 0 -100",
"output": "NO"
},
{
"input": "0 0 0 2 2 2 2 0\n5 1 9 5 5 9 1 5",
"output": "NO"
},
{
"input": "3 2 3 3 4 3 4 2\n0 4 4 0 0 -4 -4 0",
"output": "NO"
},
{
"input": "0 0 2 0 2 2 0 2\n4 1 7 4 4 7 1 4",
"output": "NO"
},
{
"input": "3 6 3 8 5 8 5 6\n2 9 4 11 6 9 4 7",
"output": "YES"
},
{
"input": "0 0 10 0 10 10 0 10\n-1 5 5 -1 11 5 5 11",
"output": "YES"
},
{
"input": "0 0 1 0 1 1 0 1\n3 0 6 3 3 6 0 3",
"output": "NO"
},
{
"input": "3 7 4 7 4 6 3 6\n0 0 10 10 20 0 10 -10",
"output": "NO"
},
{
"input": "0 0 0 1 1 1 1 0\n0 3 3 6 6 3 3 0",
"output": "NO"
},
{
"input": "0 0 0 4 4 4 4 0\n3 6 7 10 11 6 7 2",
"output": "NO"
},
{
"input": "0 0 0 1 1 1 1 0\n0 10 10 0 20 10 10 20",
"output": "NO"
}
] | 1,529,181,130 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 6 | 62 | 0 | def main():
sq1, sq2 = list(map(int, input().split())), list(map(int, input().split()))
#sq1, sq2 = list(map(int, "0 0 2 0 2 2 0 2".split())), list(map(int, "1 -1 3 1 1 3 -1 1".split()))
def test(sqr1, sqr2):
x1, y1 = sorted([sqr1[0], sqr1[2]]), sorted([sqr1[1], sqr1[5]])
if x1[0] == x1[1]:
x1, y1 = sorted([sqr1[0], sqr1[4]]), sorted([sqr1[1], sqr1[3]])
c2 = [(sqr2[0] + sqr2[4]) // 2, (sqr2[1] + sqr2[5]) // 2]
if c2[0] >= x1[0] and c2[0] <= x1[1] and c2[1] >= y1[0] and c2[1] <= y1[1]:
return True
for i in range(4):
if sqr2[2 * i] >= x1[0] and sqr2[2 * i] <= x1[1] and sqr2[2 * i + 1] >= y1[0] and sqr2[2 * i] <= y1[1]:
return True
return False
if test(sq1, sq2):
print("Yes")
return 0
for i in range(4):
sq1[2 * i], sq1[2 * i + 1] = sq1[2 * i] + sq1[2 * i + 1], - sq1[2 * i] + sq1[2 * i + 1]
sq2[2 * i], sq2[2 * i + 1] = sq2[2 * i] + sq2[2 * i + 1], - sq2[2 * i] + sq2[2 * i + 1]
if test(sq2, sq1):
print("Yes")
return 0
print("No")
return 0
main()
| Title: none
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given two squares, one with sides parallel to the coordinate axes, and another one with sides at 45 degrees to the coordinate axes. Find whether the two squares intersect.
The interior of the square is considered to be part of the square, i.e. if one square is completely inside another, they intersect. If the two squares only share one common point, they are also considered to intersect.
Input Specification:
The input data consists of two lines, one for each square, both containing 4 pairs of integers. Each pair represents coordinates of one vertex of the square. Coordinates within each line are either in clockwise or counterclockwise order.
The first line contains the coordinates of the square with sides parallel to the coordinate axes, the second line contains the coordinates of the square at 45 degrees.
All the values are integer and between $-100$ and $100$.
Output Specification:
Print "Yes" if squares intersect, otherwise print "No".
You can print each letter in any case (upper or lower).
Demo Input:
['0 0 6 0 6 6 0 6\n1 3 3 5 5 3 3 1\n', '0 0 6 0 6 6 0 6\n7 3 9 5 11 3 9 1\n', '6 0 6 6 0 6 0 0\n7 4 4 7 7 10 10 7\n']
Demo Output:
['YES\n', 'NO\n', 'YES\n']
Note:
In the first example the second square lies entirely within the first square, so they do intersect.
In the second sample squares do not have any points in common.
Here are images corresponding to the samples: | ```python
def main():
sq1, sq2 = list(map(int, input().split())), list(map(int, input().split()))
#sq1, sq2 = list(map(int, "0 0 2 0 2 2 0 2".split())), list(map(int, "1 -1 3 1 1 3 -1 1".split()))
def test(sqr1, sqr2):
x1, y1 = sorted([sqr1[0], sqr1[2]]), sorted([sqr1[1], sqr1[5]])
if x1[0] == x1[1]:
x1, y1 = sorted([sqr1[0], sqr1[4]]), sorted([sqr1[1], sqr1[3]])
c2 = [(sqr2[0] + sqr2[4]) // 2, (sqr2[1] + sqr2[5]) // 2]
if c2[0] >= x1[0] and c2[0] <= x1[1] and c2[1] >= y1[0] and c2[1] <= y1[1]:
return True
for i in range(4):
if sqr2[2 * i] >= x1[0] and sqr2[2 * i] <= x1[1] and sqr2[2 * i + 1] >= y1[0] and sqr2[2 * i] <= y1[1]:
return True
return False
if test(sq1, sq2):
print("Yes")
return 0
for i in range(4):
sq1[2 * i], sq1[2 * i + 1] = sq1[2 * i] + sq1[2 * i + 1], - sq1[2 * i] + sq1[2 * i + 1]
sq2[2 * i], sq2[2 * i + 1] = sq2[2 * i] + sq2[2 * i + 1], - sq2[2 * i] + sq2[2 * i + 1]
if test(sq2, sq1):
print("Yes")
return 0
print("No")
return 0
main()
``` | 0 | |
595 | A | Vitaly and Night | PROGRAMMING | 800 | [
"constructive algorithms",
"implementation"
] | null | null | One day Vitaly was going home late at night and wondering: how many people aren't sleeping at that moment? To estimate, Vitaly decided to look which windows are lit in the house he was passing by at that moment.
Vitaly sees a building of *n* floors and 2·*m* windows on each floor. On each floor there are *m* flats numbered from 1 to *m*, and two consecutive windows correspond to each flat. If we number the windows from 1 to 2·*m* from left to right, then the *j*-th flat of the *i*-th floor has windows 2·*j*<=-<=1 and 2·*j* in the corresponding row of windows (as usual, floors are enumerated from the bottom). Vitaly thinks that people in the flat aren't sleeping at that moment if at least one of the windows corresponding to this flat has lights on.
Given the information about the windows of the given house, your task is to calculate the number of flats where, according to Vitaly, people aren't sleeping. | The first line of the input contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of floors in the house and the number of flats on each floor respectively.
Next *n* lines describe the floors from top to bottom and contain 2·*m* characters each. If the *i*-th window of the given floor has lights on, then the *i*-th character of this line is '1', otherwise it is '0'. | Print a single integer — the number of flats that have lights on in at least one window, that is, the flats where, according to Vitaly, people aren't sleeping. | [
"2 2\n0 0 0 1\n1 0 1 1\n",
"1 3\n1 1 0 1 0 0\n"
] | [
"3\n",
"2\n"
] | In the first test case the house has two floors, two flats on each floor. That is, in total there are 4 flats. The light isn't on only on the second floor in the left flat. That is, in both rooms of the flat the light is off.
In the second test case the house has one floor and the first floor has three flats. The light is on in the leftmost flat (in both windows) and in the middle flat (in one window). In the right flat the light is off. | 500 | [
{
"input": "2 2\n0 0 0 1\n1 0 1 1",
"output": "3"
},
{
"input": "1 3\n1 1 0 1 0 0",
"output": "2"
},
{
"input": "3 3\n1 1 1 1 1 1\n1 1 0 1 1 0\n1 0 0 0 1 1",
"output": "8"
},
{
"input": "1 5\n1 0 1 1 1 0 1 1 1 1",
"output": "5"
},
{
"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 0 1 1 1 1 0 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 0 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 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": "99"
},
{
"input": "1 100\n0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 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 1 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 1 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 1 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 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0",
"output": "6"
},
{
"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 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 0",
"output": "0"
},
{
"input": "100 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 0\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n0 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 0\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 0\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n0 1\n1 1\n1 1\n1 0\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1\n1 1",
"output": "100"
},
{
"input": "100 1\n0 0\n0 0\n0 1\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\n1 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 1\n0 0\n0 0\n0 0\n1 0\n0 0\n0 0\n0 0\n1 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 0\n0 1\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 1\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\n1 0",
"output": "8"
},
{
"input": "100 1\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 0",
"output": "0"
},
{
"input": "1 1\n0 0",
"output": "0"
},
{
"input": "1 1\n0 1",
"output": "1"
},
{
"input": "1 1\n1 0",
"output": "1"
},
{
"input": "1 1\n1 1",
"output": "1"
}
] | 1,641,282,820 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 2 | 30 | 0 | # import sys
# sys.stdout = open('DSA/Stacks/output.txt', 'w')
# sys.stdin = open('DSA/Stacks/input.txt', 'r')
n, m = map(int, input().split())
cc=0
for _ in range(n):
ll = list(map(int, input().split()))
cc+=ll.count(1)
print((cc//2)+1) | Title: Vitaly and Night
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
One day Vitaly was going home late at night and wondering: how many people aren't sleeping at that moment? To estimate, Vitaly decided to look which windows are lit in the house he was passing by at that moment.
Vitaly sees a building of *n* floors and 2·*m* windows on each floor. On each floor there are *m* flats numbered from 1 to *m*, and two consecutive windows correspond to each flat. If we number the windows from 1 to 2·*m* from left to right, then the *j*-th flat of the *i*-th floor has windows 2·*j*<=-<=1 and 2·*j* in the corresponding row of windows (as usual, floors are enumerated from the bottom). Vitaly thinks that people in the flat aren't sleeping at that moment if at least one of the windows corresponding to this flat has lights on.
Given the information about the windows of the given house, your task is to calculate the number of flats where, according to Vitaly, people aren't sleeping.
Input Specification:
The first line of the input contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of floors in the house and the number of flats on each floor respectively.
Next *n* lines describe the floors from top to bottom and contain 2·*m* characters each. If the *i*-th window of the given floor has lights on, then the *i*-th character of this line is '1', otherwise it is '0'.
Output Specification:
Print a single integer — the number of flats that have lights on in at least one window, that is, the flats where, according to Vitaly, people aren't sleeping.
Demo Input:
['2 2\n0 0 0 1\n1 0 1 1\n', '1 3\n1 1 0 1 0 0\n']
Demo Output:
['3\n', '2\n']
Note:
In the first test case the house has two floors, two flats on each floor. That is, in total there are 4 flats. The light isn't on only on the second floor in the left flat. That is, in both rooms of the flat the light is off.
In the second test case the house has one floor and the first floor has three flats. The light is on in the leftmost flat (in both windows) and in the middle flat (in one window). In the right flat the light is off. | ```python
# import sys
# sys.stdout = open('DSA/Stacks/output.txt', 'w')
# sys.stdin = open('DSA/Stacks/input.txt', 'r')
n, m = map(int, input().split())
cc=0
for _ in range(n):
ll = list(map(int, input().split()))
cc+=ll.count(1)
print((cc//2)+1)
``` | 0 | |
912 | B | New Year's Eve | PROGRAMMING | 1,300 | [
"bitmasks",
"constructive algorithms",
"number theory"
] | null | null | Since Grisha behaved well last year, at New Year's Eve he was visited by Ded Moroz who brought an enormous bag of gifts with him! The bag contains *n* sweet candies from the good ol' bakery, each labeled from 1 to *n* corresponding to its tastiness. No two candies have the same tastiness.
The choice of candies has a direct effect on Grisha's happiness. One can assume that he should take the tastiest ones — but no, the holiday magic turns things upside down. It is the xor-sum of tastinesses that matters, not the ordinary sum!
A xor-sum of a sequence of integers *a*1,<=*a*2,<=...,<=*a**m* is defined as the bitwise XOR of all its elements: , here denotes the bitwise XOR operation; more about bitwise XOR can be found [here.](https://en.wikipedia.org/wiki/Bitwise_operation#XOR)
Ded Moroz warned Grisha he has more houses to visit, so Grisha can take no more than *k* candies from the bag. Help Grisha determine the largest xor-sum (largest xor-sum means maximum happiness!) he can obtain. | The sole string contains two integers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=1018). | Output one number — the largest possible xor-sum. | [
"4 3\n",
"6 6\n"
] | [
"7\n",
"7\n"
] | In the first sample case, one optimal answer is 1, 2 and 4, giving the xor-sum of 7.
In the second sample case, one can, for example, take all six candies and obtain the xor-sum of 7. | 1,000 | [
{
"input": "4 3",
"output": "7"
},
{
"input": "6 6",
"output": "7"
},
{
"input": "2 2",
"output": "3"
},
{
"input": "1022 10",
"output": "1023"
},
{
"input": "415853337373441 52",
"output": "562949953421311"
},
{
"input": "75 12",
"output": "127"
},
{
"input": "1000000000000000000 1000000000000000000",
"output": "1152921504606846975"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "1000000000000000000 2",
"output": "1152921504606846975"
},
{
"input": "49194939 22",
"output": "67108863"
},
{
"input": "228104606 17",
"output": "268435455"
},
{
"input": "817034381 7",
"output": "1073741823"
},
{
"input": "700976748 4",
"output": "1073741823"
},
{
"input": "879886415 9",
"output": "1073741823"
},
{
"input": "18007336 10353515",
"output": "33554431"
},
{
"input": "196917003 154783328",
"output": "268435455"
},
{
"input": "785846777 496205300",
"output": "1073741823"
},
{
"input": "964756444 503568330",
"output": "1073741823"
},
{
"input": "848698811 317703059",
"output": "1073741823"
},
{
"input": "676400020444788 1",
"output": "676400020444788"
},
{
"input": "502643198528213 1",
"output": "502643198528213"
},
{
"input": "815936580997298686 684083143940282566",
"output": "1152921504606846975"
},
{
"input": "816762824175382110 752185261508428780",
"output": "1152921504606846975"
},
{
"input": "327942415253132295 222598158321260499",
"output": "576460752303423487"
},
{
"input": "328768654136248423 284493129147496637",
"output": "576460752303423487"
},
{
"input": "329594893019364551 25055600080496801",
"output": "576460752303423487"
},
{
"input": "921874985256864012 297786684518764536",
"output": "1152921504606846975"
},
{
"input": "922701224139980141 573634416190460758",
"output": "1152921504606846975"
},
{
"input": "433880815217730325 45629641110945892",
"output": "576460752303423487"
},
{
"input": "434707058395813749 215729375494216481",
"output": "576460752303423487"
},
{
"input": "435533301573897173 34078453236225189",
"output": "576460752303423487"
},
{
"input": "436359544751980597 199220719961060641",
"output": "576460752303423487"
},
{
"input": "437185783635096725 370972992240105630",
"output": "576460752303423487"
},
{
"input": "438012026813180149 111323110116193830",
"output": "576460752303423487"
},
{
"input": "438838269991263573 295468957052046146",
"output": "576460752303423487"
},
{
"input": "439664513169346997 46560240538186155",
"output": "576460752303423487"
},
{
"input": "440490752052463125 216165966013438147",
"output": "576460752303423487"
},
{
"input": "441316995230546549 401964286420555423",
"output": "576460752303423487"
},
{
"input": "952496582013329437 673506882352402278",
"output": "1152921504606846975"
},
{
"input": "1000000000000000000 1",
"output": "1000000000000000000"
},
{
"input": "2147483647 1",
"output": "2147483647"
},
{
"input": "2147483647 2",
"output": "2147483647"
},
{
"input": "2147483647 31",
"output": "2147483647"
},
{
"input": "8 2",
"output": "15"
},
{
"input": "3 3",
"output": "3"
},
{
"input": "4 1",
"output": "4"
},
{
"input": "10 2",
"output": "15"
},
{
"input": "288230376151711743 2",
"output": "288230376151711743"
},
{
"input": "5 2",
"output": "7"
},
{
"input": "576460752303423487 2",
"output": "576460752303423487"
},
{
"input": "36028797018963967 123",
"output": "36028797018963967"
},
{
"input": "1125899906842623 2",
"output": "1125899906842623"
},
{
"input": "576460752303423489 5",
"output": "1152921504606846975"
},
{
"input": "288230376151711743 3",
"output": "288230376151711743"
},
{
"input": "36028797018963967 345",
"output": "36028797018963967"
},
{
"input": "18014398509481984 30",
"output": "36028797018963967"
},
{
"input": "8 8",
"output": "15"
},
{
"input": "8 1",
"output": "8"
}
] | 1,590,143,929 | 2,147,483,647 | PyPy 3 | OK | TESTS | 58 | 140 | 0 | n, k = input().split()
n = int(n)
k = int(k)
if k == 1:
print(n)
else:
p = 0
while n != 0:
n //= 2
p += 1
print(int(2**p-1)) | Title: New Year's Eve
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Since Grisha behaved well last year, at New Year's Eve he was visited by Ded Moroz who brought an enormous bag of gifts with him! The bag contains *n* sweet candies from the good ol' bakery, each labeled from 1 to *n* corresponding to its tastiness. No two candies have the same tastiness.
The choice of candies has a direct effect on Grisha's happiness. One can assume that he should take the tastiest ones — but no, the holiday magic turns things upside down. It is the xor-sum of tastinesses that matters, not the ordinary sum!
A xor-sum of a sequence of integers *a*1,<=*a*2,<=...,<=*a**m* is defined as the bitwise XOR of all its elements: , here denotes the bitwise XOR operation; more about bitwise XOR can be found [here.](https://en.wikipedia.org/wiki/Bitwise_operation#XOR)
Ded Moroz warned Grisha he has more houses to visit, so Grisha can take no more than *k* candies from the bag. Help Grisha determine the largest xor-sum (largest xor-sum means maximum happiness!) he can obtain.
Input Specification:
The sole string contains two integers *n* and *k* (1<=≤<=*k*<=≤<=*n*<=≤<=1018).
Output Specification:
Output one number — the largest possible xor-sum.
Demo Input:
['4 3\n', '6 6\n']
Demo Output:
['7\n', '7\n']
Note:
In the first sample case, one optimal answer is 1, 2 and 4, giving the xor-sum of 7.
In the second sample case, one can, for example, take all six candies and obtain the xor-sum of 7. | ```python
n, k = input().split()
n = int(n)
k = int(k)
if k == 1:
print(n)
else:
p = 0
while n != 0:
n //= 2
p += 1
print(int(2**p-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"
}
] | 1,586,007,273 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 0 | 248 | 0 | forces = []
for _ in range(int(input())):
forces.append([int(num) for num in input().split()])
print(forces)
for dim in range(3):
if sum(map(lambda x: x[dim], forces)):
print("NO")
else:
print("YES") | 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
forces = []
for _ in range(int(input())):
forces.append([int(num) for num in input().split()])
print(forces)
for dim in range(3):
if sum(map(lambda x: x[dim], forces)):
print("NO")
else:
print("YES")
``` | 0 |
152 | A | Marks | PROGRAMMING | 900 | [
"implementation"
] | null | null | Vasya, or Mr. Vasily Petrov is a dean of a department in a local university. After the winter exams he got his hands on a group's gradebook.
Overall the group has *n* students. They received marks for *m* subjects. Each student got a mark from 1 to 9 (inclusive) for each subject.
Let's consider a student the best at some subject, if there is no student who got a higher mark for this subject. Let's consider a student successful, if there exists a subject he is the best at.
Your task is to find the number of successful students in the group. | The first input line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of students and the number of subjects, correspondingly. Next *n* lines each containing *m* characters describe the gradebook. Each character in the gradebook is a number from 1 to 9. Note that the marks in a rows are not sepatated by spaces. | Print the single number — the number of successful students in the given group. | [
"3 3\n223\n232\n112\n",
"3 5\n91728\n11828\n11111\n"
] | [
"2\n",
"3\n"
] | In the first sample test the student number 1 is the best at subjects 1 and 3, student 2 is the best at subjects 1 and 2, but student 3 isn't the best at any subject.
In the second sample test each student is the best at at least one subject. | 500 | [
{
"input": "3 3\n223\n232\n112",
"output": "2"
},
{
"input": "3 5\n91728\n11828\n11111",
"output": "3"
},
{
"input": "2 2\n48\n27",
"output": "1"
},
{
"input": "2 1\n4\n6",
"output": "1"
},
{
"input": "1 2\n57",
"output": "1"
},
{
"input": "1 1\n5",
"output": "1"
},
{
"input": "3 4\n2553\n6856\n5133",
"output": "2"
},
{
"input": "8 7\n6264676\n7854895\n3244128\n2465944\n8958761\n1378945\n3859353\n6615285",
"output": "6"
},
{
"input": "9 8\n61531121\n43529859\n18841327\n88683622\n98995641\n62741632\n57441743\n49396792\n63381994",
"output": "4"
},
{
"input": "10 20\n26855662887514171367\n48525577498621511535\n47683778377545341138\n47331616748732562762\n44876938191354974293\n24577238399664382695\n42724955594463126746\n79187344479926159359\n48349683283914388185\n82157191115518781898",
"output": "9"
},
{
"input": "20 15\n471187383859588\n652657222494199\n245695867594992\n726154672861295\n614617827782772\n862889444974692\n373977167653235\n645434268565473\n785993468314573\n722176861496755\n518276853323939\n723712762593348\n728935312568886\n373898548522463\n769777587165681\n247592995114377\n182375946483965\n497496542536127\n988239919677856\n859844339819143",
"output": "18"
},
{
"input": "13 9\n514562255\n322655246\n135162979\n733845982\n473117129\n513967187\n965649829\n799122777\n661249521\n298618978\n659352422\n747778378\n723261619",
"output": "11"
},
{
"input": "75 1\n2\n3\n8\n3\n2\n1\n3\n1\n5\n1\n5\n4\n8\n8\n4\n2\n5\n1\n7\n6\n3\n2\n2\n3\n5\n5\n2\n4\n7\n7\n9\n2\n9\n5\n1\n4\n9\n5\n2\n4\n6\n6\n3\n3\n9\n3\n3\n2\n3\n4\n2\n6\n9\n1\n1\n1\n1\n7\n2\n3\n2\n9\n7\n4\n9\n1\n7\n5\n6\n8\n3\n4\n3\n4\n6",
"output": "7"
},
{
"input": "92 3\n418\n665\n861\n766\n529\n416\n476\n676\n561\n995\n415\n185\n291\n176\n776\n631\n556\n488\n118\n188\n437\n496\n466\n131\n914\n118\n766\n365\n113\n897\n386\n639\n276\n946\n759\n169\n494\n837\n338\n351\n783\n311\n261\n862\n598\n132\n246\n982\n575\n364\n615\n347\n374\n368\n523\n132\n774\n161\n552\n492\n598\n474\n639\n681\n635\n342\n516\n483\n141\n197\n571\n336\n175\n596\n481\n327\n841\n133\n142\n146\n246\n396\n287\n582\n556\n996\n479\n814\n497\n363\n963\n162",
"output": "23"
},
{
"input": "100 1\n1\n6\n9\n1\n1\n5\n5\n4\n6\n9\n6\n1\n7\n8\n7\n3\n8\n8\n7\n6\n2\n1\n5\n8\n7\n3\n5\n4\n9\n7\n1\n2\n4\n1\n6\n5\n1\n3\n9\n4\n5\n8\n1\n2\n1\n9\n7\n3\n7\n1\n2\n2\n2\n2\n3\n9\n7\n2\n4\n7\n1\n6\n8\n1\n5\n6\n1\n1\n2\n9\n7\n4\n9\n1\n9\n4\n1\n3\n5\n2\n4\n4\n6\n5\n1\n4\n5\n8\n4\n7\n6\n5\n6\n9\n5\n8\n1\n5\n1\n6",
"output": "10"
},
{
"input": "100 2\n71\n87\n99\n47\n22\n87\n49\n73\n21\n12\n77\n43\n18\n41\n78\n62\n61\n16\n64\n89\n81\n54\n53\n92\n93\n94\n68\n93\n15\n68\n42\n93\n28\n19\n86\n16\n97\n17\n11\n43\n72\n76\n54\n95\n58\n53\n48\n45\n85\n85\n74\n21\n44\n51\n89\n75\n76\n17\n38\n62\n81\n22\n66\n59\n89\n85\n91\n87\n12\n97\n52\n87\n43\n89\n51\n58\n57\n98\n78\n68\n82\n41\n87\n29\n75\n72\n48\n14\n35\n71\n74\n91\n66\n67\n42\n98\n52\n54\n22\n41",
"output": "21"
},
{
"input": "5 20\n11111111111111111111\n11111111111111111111\n11111111111111111111\n99999999999999999999\n11111111111111111119",
"output": "2"
},
{
"input": "3 3\n111\n111\n999",
"output": "1"
},
{
"input": "3 3\n119\n181\n711",
"output": "3"
},
{
"input": "15 5\n91728\n11828\n11111\n91728\n11828\n11111\n91728\n11828\n11111\n91728\n11828\n11111\n91728\n11828\n11111",
"output": "15"
},
{
"input": "2 20\n22222222222222222222\n11111111111111111111",
"output": "1"
},
{
"input": "3 3\n233\n222\n111",
"output": "2"
},
{
"input": "4 15\n222222222222222\n111111111111119\n111111111111119\n111111111111111",
"output": "3"
},
{
"input": "4 1\n1\n9\n9\n9",
"output": "3"
},
{
"input": "3 3\n123\n321\n132",
"output": "3"
},
{
"input": "3 3\n113\n332\n322",
"output": "3"
},
{
"input": "2 100\n2222222222222222222222222222222222222222222222222222222222222222222222221222222222222222222222222222\n1111111111111111111111111111111111111111111111111111111111111111111111119111111111111111111111111111",
"output": "2"
},
{
"input": "3 3\n321\n231\n123",
"output": "3"
},
{
"input": "2 100\n1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111\n2222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222222",
"output": "1"
},
{
"input": "3 3\n221\n111\n111",
"output": "3"
}
] | 1,635,819,520 | 2,147,483,647 | PyPy 3 | RUNTIME_ERROR | TESTS | 0 | 92 | 19,763,200 | import numpy
t=int(input())
for i in range(1,t+1):
n,m=map(int,input().split())
L=[]
best=[]
for j in range(n):
L.append(map(int,input().split()))
L=numpy.array(L)
LT=numpy.transpose(L)
for k in LT:
ind=LT.index(max(k))
if ind not in LT:
best.append(ind)
print(len(best))
| Title: Marks
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Vasya, or Mr. Vasily Petrov is a dean of a department in a local university. After the winter exams he got his hands on a group's gradebook.
Overall the group has *n* students. They received marks for *m* subjects. Each student got a mark from 1 to 9 (inclusive) for each subject.
Let's consider a student the best at some subject, if there is no student who got a higher mark for this subject. Let's consider a student successful, if there exists a subject he is the best at.
Your task is to find the number of successful students in the group.
Input Specification:
The first input line contains two integers *n* and *m* (1<=≤<=*n*,<=*m*<=≤<=100) — the number of students and the number of subjects, correspondingly. Next *n* lines each containing *m* characters describe the gradebook. Each character in the gradebook is a number from 1 to 9. Note that the marks in a rows are not sepatated by spaces.
Output Specification:
Print the single number — the number of successful students in the given group.
Demo Input:
['3 3\n223\n232\n112\n', '3 5\n91728\n11828\n11111\n']
Demo Output:
['2\n', '3\n']
Note:
In the first sample test the student number 1 is the best at subjects 1 and 3, student 2 is the best at subjects 1 and 2, but student 3 isn't the best at any subject.
In the second sample test each student is the best at at least one subject. | ```python
import numpy
t=int(input())
for i in range(1,t+1):
n,m=map(int,input().split())
L=[]
best=[]
for j in range(n):
L.append(map(int,input().split()))
L=numpy.array(L)
LT=numpy.transpose(L)
for k in LT:
ind=LT.index(max(k))
if ind not in LT:
best.append(ind)
print(len(best))
``` | -1 | |
750 | A | New Year and Hurry | PROGRAMMING | 800 | [
"binary search",
"brute force",
"implementation",
"math"
] | null | null | Limak is going to participate in a contest on the last day of the 2016. The contest will start at 20:00 and will last four hours, exactly until midnight. There will be *n* problems, sorted by difficulty, i.e. problem 1 is the easiest and problem *n* is the hardest. Limak knows it will take him 5·*i* minutes to solve the *i*-th problem.
Limak's friends organize a New Year's Eve party and Limak wants to be there at midnight or earlier. He needs *k* minutes to get there from his house, where he will participate in the contest first.
How many problems can Limak solve if he wants to make it to the party? | The only line of the input contains two integers *n* and *k* (1<=≤<=*n*<=≤<=10, 1<=≤<=*k*<=≤<=240) — the number of the problems in the contest and the number of minutes Limak needs to get to the party from his house. | Print one integer, denoting the maximum possible number of problems Limak can solve so that he could get to the party at midnight or earlier. | [
"3 222\n",
"4 190\n",
"7 1\n"
] | [
"2\n",
"4\n",
"7\n"
] | In the first sample, there are 3 problems and Limak needs 222 minutes to get to the party. The three problems require 5, 10 and 15 minutes respectively. Limak can spend 5 + 10 = 15 minutes to solve first two problems. Then, at 20:15 he can leave his house to get to the party at 23:57 (after 222 minutes). In this scenario Limak would solve 2 problems. He doesn't have enough time to solve 3 problems so the answer is 2.
In the second sample, Limak can solve all 4 problems in 5 + 10 + 15 + 20 = 50 minutes. At 20:50 he will leave the house and go to the party. He will get there exactly at midnight.
In the third sample, Limak needs only 1 minute to get to the party. He has enough time to solve all 7 problems. | 500 | [
{
"input": "3 222",
"output": "2"
},
{
"input": "4 190",
"output": "4"
},
{
"input": "7 1",
"output": "7"
},
{
"input": "10 135",
"output": "6"
},
{
"input": "10 136",
"output": "5"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "1 240",
"output": "0"
},
{
"input": "10 1",
"output": "9"
},
{
"input": "10 240",
"output": "0"
},
{
"input": "9 240",
"output": "0"
},
{
"input": "9 1",
"output": "9"
},
{
"input": "9 235",
"output": "1"
},
{
"input": "9 236",
"output": "0"
},
{
"input": "5 225",
"output": "2"
},
{
"input": "5 226",
"output": "1"
},
{
"input": "4 210",
"output": "3"
},
{
"input": "4 211",
"output": "2"
},
{
"input": "4 191",
"output": "3"
},
{
"input": "10 165",
"output": "5"
},
{
"input": "10 166",
"output": "4"
},
{
"input": "8 100",
"output": "7"
},
{
"input": "8 101",
"output": "6"
},
{
"input": "8 60",
"output": "8"
},
{
"input": "8 61",
"output": "7"
},
{
"input": "10 15",
"output": "9"
},
{
"input": "10 16",
"output": "8"
},
{
"input": "4 100",
"output": "4"
},
{
"input": "4 101",
"output": "4"
},
{
"input": "7 167",
"output": "4"
},
{
"input": "10 164",
"output": "5"
},
{
"input": "9 170",
"output": "4"
},
{
"input": "8 160",
"output": "5"
},
{
"input": "1 100",
"output": "1"
},
{
"input": "8 123",
"output": "6"
},
{
"input": "2 99",
"output": "2"
},
{
"input": "10 88",
"output": "7"
},
{
"input": "1 235",
"output": "1"
},
{
"input": "1 1",
"output": "1"
},
{
"input": "4 240",
"output": "0"
},
{
"input": "1 55",
"output": "1"
},
{
"input": "1 240",
"output": "0"
},
{
"input": "3 240",
"output": "0"
},
{
"input": "10 240",
"output": "0"
},
{
"input": "2 240",
"output": "0"
},
{
"input": "10 1",
"output": "9"
},
{
"input": "9 1",
"output": "9"
},
{
"input": "2 236",
"output": "0"
},
{
"input": "10 2",
"output": "9"
},
{
"input": "3 239",
"output": "0"
},
{
"input": "1 237",
"output": "0"
},
{
"input": "7 8",
"output": "7"
},
{
"input": "10 235",
"output": "1"
}
] | 1,688,907,332 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 0 | 30 | 0 | def summ(x):
return ((1 + x) * x) // 2
a = [int(i) for i in input().split(" ")]
n, k = a[0], a[1]
del a
t = 240 - k
l = 0
r = n
mid = (l + r) // 2
while l < r:
if 5 * summ(mid) < t:
l = mid + 1
else:
r = mid
mid = (l + r) // 2
print(mid)
# s_n = ((a1 + an) * n) / 2
| Title: New Year and Hurry
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Limak is going to participate in a contest on the last day of the 2016. The contest will start at 20:00 and will last four hours, exactly until midnight. There will be *n* problems, sorted by difficulty, i.e. problem 1 is the easiest and problem *n* is the hardest. Limak knows it will take him 5·*i* minutes to solve the *i*-th problem.
Limak's friends organize a New Year's Eve party and Limak wants to be there at midnight or earlier. He needs *k* minutes to get there from his house, where he will participate in the contest first.
How many problems can Limak solve if he wants to make it to the party?
Input Specification:
The only line of the input contains two integers *n* and *k* (1<=≤<=*n*<=≤<=10, 1<=≤<=*k*<=≤<=240) — the number of the problems in the contest and the number of minutes Limak needs to get to the party from his house.
Output Specification:
Print one integer, denoting the maximum possible number of problems Limak can solve so that he could get to the party at midnight or earlier.
Demo Input:
['3 222\n', '4 190\n', '7 1\n']
Demo Output:
['2\n', '4\n', '7\n']
Note:
In the first sample, there are 3 problems and Limak needs 222 minutes to get to the party. The three problems require 5, 10 and 15 minutes respectively. Limak can spend 5 + 10 = 15 minutes to solve first two problems. Then, at 20:15 he can leave his house to get to the party at 23:57 (after 222 minutes). In this scenario Limak would solve 2 problems. He doesn't have enough time to solve 3 problems so the answer is 2.
In the second sample, Limak can solve all 4 problems in 5 + 10 + 15 + 20 = 50 minutes. At 20:50 he will leave the house and go to the party. He will get there exactly at midnight.
In the third sample, Limak needs only 1 minute to get to the party. He has enough time to solve all 7 problems. | ```python
def summ(x):
return ((1 + x) * x) // 2
a = [int(i) for i in input().split(" ")]
n, k = a[0], a[1]
del a
t = 240 - k
l = 0
r = n
mid = (l + r) // 2
while l < r:
if 5 * summ(mid) < t:
l = mid + 1
else:
r = mid
mid = (l + r) // 2
print(mid)
# s_n = ((a1 + an) * n) / 2
``` | 0 | |
600 | A | Extract Numbers | PROGRAMMING | 1,600 | [
"implementation",
"strings"
] | null | null | You are given string *s*. Let's call word any largest sequence of consecutive symbols without symbols ',' (comma) and ';' (semicolon). For example, there are four words in string "aba,123;1a;0": "aba", "123", "1a", "0". A word can be empty: for example, the string *s*=";;" contains three empty words separated by ';'.
You should find all words in the given string that are nonnegative INTEGER numbers without leading zeroes and build by them new string *a*. String *a* should contain all words that are numbers separating them by ',' (the order of numbers should remain the same as in the string *s*). By all other words you should build string *b* in the same way (the order of numbers should remain the same as in the string *s*).
Here strings "101", "0" are INTEGER numbers, but "01" and "1.0" are not.
For example, for the string aba,123;1a;0 the string *a* would be equal to "123,0" and string *b* would be equal to "aba,1a". | The only line of input contains the string *s* (1<=≤<=|*s*|<=≤<=105). The string contains only symbols '.' (ASCII 46), ',' (ASCII 44), ';' (ASCII 59), digits, lowercase and uppercase latin letters. | Print the string *a* to the first line and string *b* to the second line. Each string should be surrounded by quotes (ASCII 34).
If there are no words that are numbers print dash (ASCII 45) on the first line. If all words are numbers print dash on the second line. | [
"aba,123;1a;0\n",
"1;;01,a0,\n",
"1\n",
"a\n"
] | [
"\"123,0\"\n\"aba,1a\"\n",
"\"1\"\n\",01,a0,\"\n",
"\"1\"\n-\n",
"-\n\"a\"\n"
] | In the second example the string *s* contains five words: "1", "", "01", "a0", "". | 0 | [
{
"input": "aba,123;1a;0",
"output": "\"123,0\"\n\"aba,1a\""
},
{
"input": "1;;01,a0,",
"output": "\"1\"\n\",01,a0,\""
},
{
"input": "1",
"output": "\"1\"\n-"
},
{
"input": "a",
"output": "-\n\"a\""
},
{
"input": ",;,,;",
"output": "-\n\",,,,,\""
},
{
"input": "123;abacab,123;1,sadasfas,123213132g;02131313;aaa,0,012;0;03242;1",
"output": "\"123,123,1,0,0,1\"\n\"abacab,sadasfas,123213132g,02131313,aaa,012,03242\""
},
{
"input": ".",
"output": "-\n\".\""
},
{
"input": ";",
"output": "-\n\",\""
},
{
"input": "6;2,",
"output": "\"6,2\"\n\"\""
},
{
"input": "000",
"output": "-\n\"000\""
},
{
"input": "5345rhhr34t.k;k;k;k;k;5677;000000,000000;000098,0.70k;89.;;;",
"output": "\"5677\"\n\"5345rhhr34t.k,k,k,k,k,000000,000000,000098,0.70k,89.,,,\""
},
{
"input": "100.000",
"output": "-\n\"100.000\""
},
{
"input": ",,;,;,5345rh;hr;34t.k;k;k0,;,0,;k;k;5677.;000000,000000;000098,000.70k;89.;;;",
"output": "\"0\"\n\",,,,,,5345rh,hr,34t.k,k,k0,,,,k,k,5677.,000000,000000,000098,000.70k,89.,,,\""
},
{
"input": "01",
"output": "-\n\"01\""
},
{
"input": "ashasg,00000,00,;,hahaha,kheng",
"output": "-\n\"ashasg,00000,00,,,hahaha,kheng\""
},
{
"input": "00,0.0;00;0;,,0,0.0.0,,000,010;;",
"output": "\"0,0\"\n\"00,0.0,00,,,0.0.0,,000,010,,\""
},
{
"input": ",2",
"output": "\"2\"\n\"\""
},
{
"input": "123.123232,123.,.123,..,231.;0.,,.0;;123;123.1;.a",
"output": "\"123\"\n\"123.123232,123.,.123,..,231.,0.,,.0,,123.1,.a\""
},
{
"input": "123456789",
"output": "\"123456789\"\n-"
},
{
"input": "00",
"output": "-\n\"00\""
},
{
"input": "thisisahack",
"output": "-\n\"thisisahack\""
},
{
"input": "000.0039255805110943267,0.7362934823735448084,Y3x2yDItgcQYwqPy,0.4300802119053827563",
"output": "-\n\"000.0039255805110943267,0.7362934823735448084,Y3x2yDItgcQYwqPy,0.4300802119053827563\""
},
{
"input": "asbad,0000,00,;,",
"output": "-\n\"asbad,0000,00,,,\""
},
{
"input": "0000",
"output": "-\n\"0000\""
},
{
"input": "12345678912345",
"output": "\"12345678912345\"\n-"
}
] | 1,650,867,898 | 1,198 | Python 3 | OK | TESTS | 43 | 78 | 2,252,800 | import re
str = input()
lst = re.split('[,;]', str)
ans1 = []
ans2 = []
for s in lst:
if s.isdigit() and (s == '0' or s[0] != '0') and s[0] != '-':
ans1.append(s)
else:
ans2.append(s)
if len(ans1) == 0:
print('-')
else:
print("\"", end="")
print(','.join(ans1), end="")
print("\"")
if len(ans2) == 0:
print('-')
else:
print("\"", end="")
print(','.join(ans2), end="")
print("\"")
| Title: Extract Numbers
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given string *s*. Let's call word any largest sequence of consecutive symbols without symbols ',' (comma) and ';' (semicolon). For example, there are four words in string "aba,123;1a;0": "aba", "123", "1a", "0". A word can be empty: for example, the string *s*=";;" contains three empty words separated by ';'.
You should find all words in the given string that are nonnegative INTEGER numbers without leading zeroes and build by them new string *a*. String *a* should contain all words that are numbers separating them by ',' (the order of numbers should remain the same as in the string *s*). By all other words you should build string *b* in the same way (the order of numbers should remain the same as in the string *s*).
Here strings "101", "0" are INTEGER numbers, but "01" and "1.0" are not.
For example, for the string aba,123;1a;0 the string *a* would be equal to "123,0" and string *b* would be equal to "aba,1a".
Input Specification:
The only line of input contains the string *s* (1<=≤<=|*s*|<=≤<=105). The string contains only symbols '.' (ASCII 46), ',' (ASCII 44), ';' (ASCII 59), digits, lowercase and uppercase latin letters.
Output Specification:
Print the string *a* to the first line and string *b* to the second line. Each string should be surrounded by quotes (ASCII 34).
If there are no words that are numbers print dash (ASCII 45) on the first line. If all words are numbers print dash on the second line.
Demo Input:
['aba,123;1a;0\n', '1;;01,a0,\n', '1\n', 'a\n']
Demo Output:
['"123,0"\n"aba,1a"\n', '"1"\n",01,a0,"\n', '"1"\n-\n', '-\n"a"\n']
Note:
In the second example the string *s* contains five words: "1", "", "01", "a0", "". | ```python
import re
str = input()
lst = re.split('[,;]', str)
ans1 = []
ans2 = []
for s in lst:
if s.isdigit() and (s == '0' or s[0] != '0') and s[0] != '-':
ans1.append(s)
else:
ans2.append(s)
if len(ans1) == 0:
print('-')
else:
print("\"", end="")
print(','.join(ans1), end="")
print("\"")
if len(ans2) == 0:
print('-')
else:
print("\"", end="")
print(','.join(ans2), end="")
print("\"")
``` | 3 | |
126 | B | Password | PROGRAMMING | 1,700 | [
"binary search",
"dp",
"hashing",
"string suffix structures",
"strings"
] | null | null | Asterix, Obelix and their temporary buddies Suffix and Prefix has finally found the Harmony temple. However, its doors were firmly locked and even Obelix had no luck opening them.
A little later they found a string *s*, carved on a rock below the temple's gates. Asterix supposed that that's the password that opens the temple and read the string aloud. However, nothing happened. Then Asterix supposed that a password is some substring *t* of the string *s*.
Prefix supposed that the substring *t* is the beginning of the string *s*; Suffix supposed that the substring *t* should be the end of the string *s*; and Obelix supposed that *t* should be located somewhere inside the string *s*, that is, *t* is neither its beginning, nor its end.
Asterix chose the substring *t* so as to please all his companions. Besides, from all acceptable variants Asterix chose the longest one (as Asterix loves long strings). When Asterix read the substring *t* aloud, the temple doors opened.
You know the string *s*. Find the substring *t* or determine that such substring does not exist and all that's been written above is just a nice legend. | You are given the string *s* whose length can vary from 1 to 106 (inclusive), consisting of small Latin letters. | Print the string *t*. If a suitable *t* string does not exist, then print "Just a legend" without the quotes. | [
"fixprefixsuffix\n",
"abcdabc\n"
] | [
"fix",
"Just a legend"
] | none | 1,000 | [
{
"input": "fixprefixsuffix",
"output": "fix"
},
{
"input": "abcdabc",
"output": "Just a legend"
},
{
"input": "qwertyqwertyqwerty",
"output": "qwerty"
},
{
"input": "papapapap",
"output": "papap"
},
{
"input": "aaaaaaaaaa",
"output": "aaaaaaaa"
},
{
"input": "ghbdtn",
"output": "Just a legend"
},
{
"input": "a",
"output": "Just a legend"
},
{
"input": "aa",
"output": "Just a legend"
},
{
"input": "ab",
"output": "Just a legend"
},
{
"input": "aaa",
"output": "a"
},
{
"input": "aba",
"output": "Just a legend"
},
{
"input": "aab",
"output": "Just a legend"
},
{
"input": "abb",
"output": "Just a legend"
},
{
"input": "abc",
"output": "Just a legend"
},
{
"input": "aaabaabaaaaab",
"output": "Just a legend"
},
{
"input": "aabaaabaaaaab",
"output": "aab"
},
{
"input": "aaabaaaabab",
"output": "Just a legend"
},
{
"input": "abcabcabcabcabc",
"output": "abcabcabc"
},
{
"input": "aaaaabaaaa",
"output": "aaaa"
},
{
"input": "aaaabaaaaaaa",
"output": "aaaa"
},
{
"input": "ghghghgxghghghg",
"output": "ghghg"
},
{
"input": "kincenvizh",
"output": "Just a legend"
},
{
"input": "amcksgurlgqzqizdauqminfzshiweejkevbazyzylrrghumnvqeqqdedyopgtvxakqwpvxntxgrkrcxabhrgoxngrwrxrvcguuyw",
"output": "Just a legend"
},
{
"input": "kwuaizneqxfflhmyruotjlkqksinoanvkyvqptkkntnpjdyzicceelgooajdgpkneuhyvhdtmasiglplajxolxovlhkwuaizneqx",
"output": "Just a legend"
},
{
"input": "nfbdzgdlbjhrlvfryyjbvtsmzacxglcvukmyexdgpuiwvqbnfbdzgdlbjhrlvfryyjbtuomcwbwvlhefnfbdzgdlbjhrlvfryyjb",
"output": "nfbdzgdlbjhrlvfryyjb"
},
{
"input": "btbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgpmvbxbyszdugvmoyjeeqsywcvuqskcjotyhvdijyslgfvyujxthngnonasgnbzzygyikheelirdfsvuicbiazfdeqecbtbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgpccdtdteohtjjuicfjfcbzpynlqhecyqqrjpmexgfqywnfmusldgzvgnzdmuuujtkdfnlytzgstquwqpuccxbtbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgp",
"output": "btbdpnzdenxueteteytvkwnegodyhmdwhmrmbftrifytzudumzlacwytsuzefqfpjesdblxhpcsidgksisjdmhyxmmugrjmtfcgxmcgp"
},
{
"input": "abcazabca",
"output": "a"
}
] | 1,628,669,663 | 2,147,483,647 | PyPy 3 | TIME_LIMIT_EXCEEDED | TESTS | 24 | 2,000 | 29,798,400 | string=input()
l=len(string)
for i in range(l-2,0,-1):
if string[:i]==string[l-i:]:
s=string[:i]
if s in string[1:l-1]:
print(s)
break
else:
print("Just a legend") | Title: Password
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Asterix, Obelix and their temporary buddies Suffix and Prefix has finally found the Harmony temple. However, its doors were firmly locked and even Obelix had no luck opening them.
A little later they found a string *s*, carved on a rock below the temple's gates. Asterix supposed that that's the password that opens the temple and read the string aloud. However, nothing happened. Then Asterix supposed that a password is some substring *t* of the string *s*.
Prefix supposed that the substring *t* is the beginning of the string *s*; Suffix supposed that the substring *t* should be the end of the string *s*; and Obelix supposed that *t* should be located somewhere inside the string *s*, that is, *t* is neither its beginning, nor its end.
Asterix chose the substring *t* so as to please all his companions. Besides, from all acceptable variants Asterix chose the longest one (as Asterix loves long strings). When Asterix read the substring *t* aloud, the temple doors opened.
You know the string *s*. Find the substring *t* or determine that such substring does not exist and all that's been written above is just a nice legend.
Input Specification:
You are given the string *s* whose length can vary from 1 to 106 (inclusive), consisting of small Latin letters.
Output Specification:
Print the string *t*. If a suitable *t* string does not exist, then print "Just a legend" without the quotes.
Demo Input:
['fixprefixsuffix\n', 'abcdabc\n']
Demo Output:
['fix', 'Just a legend']
Note:
none | ```python
string=input()
l=len(string)
for i in range(l-2,0,-1):
if string[:i]==string[l-i:]:
s=string[:i]
if s in string[1:l-1]:
print(s)
break
else:
print("Just a legend")
``` | 0 | |
361 | A | Levko and Table | PROGRAMMING | 800 | [
"constructive algorithms",
"implementation"
] | null | null | Levko loves tables that consist of *n* rows and *n* columns very much. He especially loves beautiful tables. A table is beautiful to Levko if the sum of elements in each row and column of the table equals *k*.
Unfortunately, he doesn't know any such table. Your task is to help him to find at least one of them. | The single line contains two integers, *n* and *k* (1<=≤<=*n*<=≤<=100, 1<=≤<=*k*<=≤<=1000). | Print any beautiful table. Levko doesn't like too big numbers, so all elements of the table mustn't exceed 1000 in their absolute value.
If there are multiple suitable tables, you are allowed to print any of them. | [
"2 4\n",
"4 7\n"
] | [
"1 3\n3 1\n",
"2 1 0 4\n4 0 2 1\n1 3 3 0\n0 3 2 2\n"
] | In the first sample the sum in the first row is 1 + 3 = 4, in the second row — 3 + 1 = 4, in the first column — 1 + 3 = 4 and in the second column — 3 + 1 = 4. There are other beautiful tables for this sample.
In the second sample the sum of elements in each row and each column equals 7. Besides, there are other tables that meet the statement requirements. | 500 | [
{
"input": "2 4",
"output": "4 0 \n0 4 "
},
{
"input": "4 7",
"output": "7 0 0 0 \n0 7 0 0 \n0 0 7 0 \n0 0 0 7 "
},
{
"input": "1 8",
"output": "8 "
},
{
"input": "9 3",
"output": "3 0 0 0 0 0 0 0 0 \n0 3 0 0 0 0 0 0 0 \n0 0 3 0 0 0 0 0 0 \n0 0 0 3 0 0 0 0 0 \n0 0 0 0 3 0 0 0 0 \n0 0 0 0 0 3 0 0 0 \n0 0 0 0 0 0 3 0 0 \n0 0 0 0 0 0 0 3 0 \n0 0 0 0 0 0 0 0 3 "
},
{
"input": "31 581",
"output": "581 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 \n0 581 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 \n0 0 581 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 \n0 0 0 581 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 \n0 0 0 0 581 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 \n0 0 0 0 0 581 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 \n0 0 0 0 0 0 581 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 \n0 0 0 0 0 0 0 581 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0..."
},
{
"input": "100 1000",
"output": "1000 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 \n0 1000 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 \n0 0 1000 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 ..."
},
{
"input": "100 999",
"output": "999 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 \n0 999 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 \n0 0 999 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..."
},
{
"input": "99 998",
"output": "998 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 \n0 998 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 \n0 0 998 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..."
},
{
"input": "100 997",
"output": "997 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 \n0 997 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 \n0 0 997 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..."
},
{
"input": "81 111",
"output": "111 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 \n0 111 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 \n0 0 111 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 \n0 0 0 111 0 0..."
},
{
"input": "1 407",
"output": "407 "
},
{
"input": "54 341",
"output": "341 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 \n0 341 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 \n0 0 341 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 \n0 0 0 341 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 \n0 0 0 0 341 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..."
},
{
"input": "92 460",
"output": "460 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 \n0 460 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 \n0 0 460 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..."
},
{
"input": "34 47",
"output": "47 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 \n0 47 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 \n0 0 47 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 \n0 0 0 47 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 \n0 0 0 0 47 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 \n0 0 0 0 0 47 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 \n0 0 0 0 0 0 47 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 \n0 0 0 0 0 0 0 ..."
},
{
"input": "11 547",
"output": "547 0 0 0 0 0 0 0 0 0 0 \n0 547 0 0 0 0 0 0 0 0 0 \n0 0 547 0 0 0 0 0 0 0 0 \n0 0 0 547 0 0 0 0 0 0 0 \n0 0 0 0 547 0 0 0 0 0 0 \n0 0 0 0 0 547 0 0 0 0 0 \n0 0 0 0 0 0 547 0 0 0 0 \n0 0 0 0 0 0 0 547 0 0 0 \n0 0 0 0 0 0 0 0 547 0 0 \n0 0 0 0 0 0 0 0 0 547 0 \n0 0 0 0 0 0 0 0 0 0 547 "
},
{
"input": "100 1",
"output": "1 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 \n0 1 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 \n0 0 1 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..."
},
{
"input": "99 1",
"output": "1 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 \n0 1 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 \n0 0 1 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..."
},
{
"input": "99 2",
"output": "2 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 \n0 2 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 \n0 0 2 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..."
},
{
"input": "2 7",
"output": "7 0 \n0 7 "
},
{
"input": "100 100",
"output": "100 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 \n0 100 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 \n0 0 100 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..."
},
{
"input": "4 3",
"output": "3 0 0 0 \n0 3 0 0 \n0 0 3 0 \n0 0 0 3 "
},
{
"input": "3 2",
"output": "2 0 0 \n0 2 0 \n0 0 2 "
}
] | 1,669,616,046 | 2,147,483,647 | Python 3 | OK | TESTS | 22 | 62 | 0 | n, k = map(int, input().split())
l = [[0 for _ in range(n)] for _ in range(n)]
for i in range(n):
for j in range(n):
if i == j:
l[i][j] = k
for i in l:
print(*i) | Title: Levko and Table
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Levko loves tables that consist of *n* rows and *n* columns very much. He especially loves beautiful tables. A table is beautiful to Levko if the sum of elements in each row and column of the table equals *k*.
Unfortunately, he doesn't know any such table. Your task is to help him to find at least one of them.
Input Specification:
The single line contains two integers, *n* and *k* (1<=≤<=*n*<=≤<=100, 1<=≤<=*k*<=≤<=1000).
Output Specification:
Print any beautiful table. Levko doesn't like too big numbers, so all elements of the table mustn't exceed 1000 in their absolute value.
If there are multiple suitable tables, you are allowed to print any of them.
Demo Input:
['2 4\n', '4 7\n']
Demo Output:
['1 3\n3 1\n', '2 1 0 4\n4 0 2 1\n1 3 3 0\n0 3 2 2\n']
Note:
In the first sample the sum in the first row is 1 + 3 = 4, in the second row — 3 + 1 = 4, in the first column — 1 + 3 = 4 and in the second column — 3 + 1 = 4. There are other beautiful tables for this sample.
In the second sample the sum of elements in each row and each column equals 7. Besides, there are other tables that meet the statement requirements. | ```python
n, k = map(int, input().split())
l = [[0 for _ in range(n)] for _ in range(n)]
for i in range(n):
for j in range(n):
if i == j:
l[i][j] = k
for i in l:
print(*i)
``` | 3 | |
26 | B | Regular Bracket Sequence | PROGRAMMING | 1,400 | [
"greedy"
] | B. Regular Bracket Sequence | 5 | 256 | A bracket sequence is called regular if it is possible to obtain correct arithmetic expression by inserting characters «+» and «1» into this sequence. For example, sequences «(())()», «()» and «(()(()))» are regular, while «)(», «(()» and «(()))(» are not.
One day Johnny got bracket sequence. He decided to remove some of the brackets from it in order to obtain a regular bracket sequence. What is the maximum length of a regular bracket sequence which can be obtained? | Input consists of a single line with non-empty string of «(» and «)» characters. Its length does not exceed 106. | Output the maximum possible length of a regular bracket sequence. | [
"(()))(\n",
"((()())\n"
] | [
"4\n",
"6\n"
] | none | 1,000 | [
{
"input": "(()))(",
"output": "4"
},
{
"input": "((()())",
"output": "6"
},
{
"input": "(",
"output": "0"
},
{
"input": ")",
"output": "0"
},
{
"input": ")(()(",
"output": "2"
},
{
"input": "))))))(",
"output": "0"
},
{
"input": "()()(()(((",
"output": "6"
},
{
"input": "()))(()((((()(())",
"output": "10"
},
{
"input": "())))((()())())))))())",
"output": "14"
},
{
"input": ")))((((())(()((()((((()()())((",
"output": "16"
},
{
"input": "))()()((()()))())()(((((((())((((((((())()()((())(",
"output": "32"
},
{
"input": "))())))))))())))))()()))()()))))())))))()))))))))))))(()))())(()))))(()))))())))((((()()))))()))()))",
"output": "48"
}
] | 1,620,699,546 | 2,147,483,647 | PyPy 3 | OK | TESTS | 38 | 530 | 56,422,400 | s, stack, cnt = input(), [], 0
for i in range(len(s)):
if s[i] == '(': stack.append(s[i])
else:
if len(stack) > 0:
if stack.pop() != '(': cnt +=1
else: cnt += 1
print(len(s) - cnt - len(stack)) | Title: Regular Bracket Sequence
Time Limit: 5 seconds
Memory Limit: 256 megabytes
Problem Description:
A bracket sequence is called regular if it is possible to obtain correct arithmetic expression by inserting characters «+» and «1» into this sequence. For example, sequences «(())()», «()» and «(()(()))» are regular, while «)(», «(()» and «(()))(» are not.
One day Johnny got bracket sequence. He decided to remove some of the brackets from it in order to obtain a regular bracket sequence. What is the maximum length of a regular bracket sequence which can be obtained?
Input Specification:
Input consists of a single line with non-empty string of «(» and «)» characters. Its length does not exceed 106.
Output Specification:
Output the maximum possible length of a regular bracket sequence.
Demo Input:
['(()))(\n', '((()())\n']
Demo Output:
['4\n', '6\n']
Note:
none | ```python
s, stack, cnt = input(), [], 0
for i in range(len(s)):
if s[i] == '(': stack.append(s[i])
else:
if len(stack) > 0:
if stack.pop() != '(': cnt +=1
else: cnt += 1
print(len(s) - cnt - len(stack))
``` | 3.841905 |
49 | A | Sleuth | PROGRAMMING | 800 | [
"implementation"
] | A. Sleuth | 2 | 256 | Vasya plays the sleuth with his friends. The rules of the game are as follows: those who play for the first time, that is Vasya is the sleuth, he should investigate a "crime" and find out what is happening. He can ask any questions whatsoever that can be answered with "Yes" or "No". All the rest agree beforehand to answer the questions like that: if the question’s last letter is a vowel, they answer "Yes" and if the last letter is a consonant, they answer "No". Of course, the sleuth knows nothing about it and his task is to understand that.
Unfortunately, Vasya is not very smart. After 5 hours of endless stupid questions everybody except Vasya got bored. That’s why Vasya’s friends ask you to write a program that would give answers instead of them.
The English alphabet vowels are: A, E, I, O, U, Y
The English alphabet consonants are: B, C, D, F, G, H, J, K, L, M, N, P, Q, R, S, T, V, W, X, Z | The single line contains a question represented by a non-empty line consisting of large and small Latin letters, spaces and a question mark. The line length does not exceed 100. It is guaranteed that the question mark occurs exactly once in the line — as the last symbol and that the line contains at least one letter. | Print answer for the question in a single line: YES if the answer is "Yes", NO if the answer is "No".
Remember that in the reply to the question the last letter, not the last character counts. I. e. the spaces and the question mark do not count as letters. | [
"Is it a melon?\n",
"Is it an apple?\n",
"Is it a banana ?\n",
"Is it an apple and a banana simultaneouSLY?\n"
] | [
"NO\n",
"YES\n",
"YES\n",
"YES\n"
] | none | 500 | [
{
"input": "Is it a melon?",
"output": "NO"
},
{
"input": "Is it an apple?",
"output": "YES"
},
{
"input": " Is it a banana ?",
"output": "YES"
},
{
"input": "Is it an apple and a banana simultaneouSLY?",
"output": "YES"
},
{
"input": "oHtSbDwzHb?",
"output": "NO"
},
{
"input": "sZecYdUvZHrXx?",
"output": "NO"
},
{
"input": "uMtXK?",
"output": "NO"
},
{
"input": "U?",
"output": "YES"
},
{
"input": "aqFDkCUKeHMyvZFcAyWlMUSQTFomtaWjoKLVyxLCw vcufPBFbaljOuHWiDCROYTcmbgzbaqHXKPOYEbuEtRqqoxBbOETCsQzhw?",
"output": "NO"
},
{
"input": "dJcNqQiFXzcbsj fItCpBLyXOnrSBPebwyFHlxUJHqCUzzCmcAvMiKL NunwOXnKeIxUZmBVwiCUfPkjRAkTPbkYCmwRRnDSLaz?",
"output": "NO"
},
{
"input": "gxzXbdcAQMuFKuuiPohtMgeypr wpDIoDSyOYTdvylcg SoEBZjnMHHYZGEqKgCgBeTbyTwyGuPZxkxsnSczotBdYyfcQsOVDVC?",
"output": "NO"
},
{
"input": "FQXBisXaJFMiHFQlXjixBDMaQuIbyqSBKGsBfTmBKCjszlGVZxEOqYYqRTUkGpSDDAoOXyXcQbHcPaegeOUBNeSD JiKOdECPOF?",
"output": "NO"
},
{
"input": "YhCuZnrWUBEed?",
"output": "NO"
},
{
"input": "hh?",
"output": "NO"
},
{
"input": "whU?",
"output": "YES"
},
{
"input": "fgwg?",
"output": "NO"
},
{
"input": "GlEmEPKrYcOnBNJUIFjszWUyVdvWw DGDjoCMtRJUburkPToCyDrOtMr?",
"output": "NO"
},
{
"input": "n?",
"output": "NO"
},
{
"input": "BueDOlxgzeNlxrzRrMbKiQdmGujEKmGxclvaPpTuHmTqBp?",
"output": "NO"
},
{
"input": "iehvZNQXDGCuVmJPOEysLyUryTdfaIxIuTzTadDbqRQGoCLXkxnyfWSGoLXebNnQQNTqAQJebbyYvHOfpUnXeWdjx?",
"output": "NO"
},
{
"input": " J ?",
"output": "NO"
},
{
"input": " j ?",
"output": "NO"
},
{
"input": " o ?",
"output": "YES"
},
{
"input": " T ?",
"output": "NO"
},
{
"input": " q ?",
"output": "NO"
},
{
"input": " j ?",
"output": "NO"
},
{
"input": " c ?",
"output": "NO"
},
{
"input": " B ?",
"output": "NO"
},
{
"input": "LuhxDHVwMPTtUIUMIQTuQETgXCOQPsfdFlyHvpfOVedjUTpGLAZGOHloIjJJtOLAlHPivzA?",
"output": "YES"
},
{
"input": "wmztmzFfwbGyOmNHENUFMTsFEMWYA?",
"output": "YES"
},
{
"input": "wGsfZCSwN PEUhNUrLfABrxA?",
"output": "YES"
},
{
"input": "mCDHENXjYbgMdBimAdPnewaHfpGWowjWrVAdvWczjw iDcUbyzMsmsnwbviiKiAyGVA?",
"output": "YES"
},
{
"input": "ARIWnwqFqxsQXsXXzHqvFjxOCttAGPUzDtWzsenPYdNXuFOIUGYZsLLK IaoxiyjBBRThoelwdPTkuCQfcBLUEJpCPIrVZlvUWA?",
"output": "YES"
},
{
"input": " PslvVpgpN BXkMFBEVXsyZFIQbBEFxGkYTeXKrOdcmhbiTUatYRUoYAayrchqbksswIlfIjerZPqptvCGnMUhyrQSvwltRhFzA?",
"output": "YES"
},
{
"input": "HpBkttwSjBXDmyleGiRWNUMPaAIE uzTrp KJDzaUiCdsMYOoWKHoUhWUoecCPmACymMUUbGav UMRpCytPETwNFAObZJA?",
"output": "YES"
}
] | 1,575,958,107 | 2,147,483,647 | PyPy 3 | OK | TESTS | 35 | 280 | 0 | import sys
vowel="AEIOUYaeiouy"
s=input()
for i in range(len(s)-1,-1,-1):
if(s[i]!='?' and s[i]!=' '):
if(s[i] in vowel):
print("YES")
else:
print("NO")
sys.exit(0) | Title: Sleuth
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Vasya plays the sleuth with his friends. The rules of the game are as follows: those who play for the first time, that is Vasya is the sleuth, he should investigate a "crime" and find out what is happening. He can ask any questions whatsoever that can be answered with "Yes" or "No". All the rest agree beforehand to answer the questions like that: if the question’s last letter is a vowel, they answer "Yes" and if the last letter is a consonant, they answer "No". Of course, the sleuth knows nothing about it and his task is to understand that.
Unfortunately, Vasya is not very smart. After 5 hours of endless stupid questions everybody except Vasya got bored. That’s why Vasya’s friends ask you to write a program that would give answers instead of them.
The English alphabet vowels are: A, E, I, O, U, Y
The English alphabet consonants are: B, C, D, F, G, H, J, K, L, M, N, P, Q, R, S, T, V, W, X, Z
Input Specification:
The single line contains a question represented by a non-empty line consisting of large and small Latin letters, spaces and a question mark. The line length does not exceed 100. It is guaranteed that the question mark occurs exactly once in the line — as the last symbol and that the line contains at least one letter.
Output Specification:
Print answer for the question in a single line: YES if the answer is "Yes", NO if the answer is "No".
Remember that in the reply to the question the last letter, not the last character counts. I. e. the spaces and the question mark do not count as letters.
Demo Input:
['Is it a melon?\n', 'Is it an apple?\n', 'Is it a banana ?\n', 'Is it an apple and a banana simultaneouSLY?\n']
Demo Output:
['NO\n', 'YES\n', 'YES\n', 'YES\n']
Note:
none | ```python
import sys
vowel="AEIOUYaeiouy"
s=input()
for i in range(len(s)-1,-1,-1):
if(s[i]!='?' and s[i]!=' '):
if(s[i] in vowel):
print("YES")
else:
print("NO")
sys.exit(0)
``` | 3.93 |
96 | A | Football | PROGRAMMING | 900 | [
"implementation",
"strings"
] | A. Football | 2 | 256 | Petya loves football very much. One day, as he was watching a football match, he was writing the players' current positions on a piece of paper. To simplify the situation he depicted it as a string consisting of zeroes and ones. A zero corresponds to players of one team; a one corresponds to players of another team. If there are at least 7 players of some team standing one after another, then the situation is considered dangerous. For example, the situation 00100110111111101 is dangerous and 11110111011101 is not. You are given the current situation. Determine whether it is dangerous or not. | The first input line contains a non-empty string consisting of characters "0" and "1", which represents players. The length of the string does not exceed 100 characters. There's at least one player from each team present on the field. | Print "YES" if the situation is dangerous. Otherwise, print "NO". | [
"001001\n",
"1000000001\n"
] | [
"NO\n",
"YES\n"
] | none | 500 | [
{
"input": "001001",
"output": "NO"
},
{
"input": "1000000001",
"output": "YES"
},
{
"input": "00100110111111101",
"output": "YES"
},
{
"input": "11110111111111111",
"output": "YES"
},
{
"input": "01",
"output": "NO"
},
{
"input": "10100101",
"output": "NO"
},
{
"input": "1010010100000000010",
"output": "YES"
},
{
"input": "101010101",
"output": "NO"
},
{
"input": "000000000100000000000110101100000",
"output": "YES"
},
{
"input": "100001000000110101100000",
"output": "NO"
},
{
"input": "100001000011010110000",
"output": "NO"
},
{
"input": "010",
"output": "NO"
},
{
"input": "10101011111111111111111111111100",
"output": "YES"
},
{
"input": "1001101100",
"output": "NO"
},
{
"input": "1001101010",
"output": "NO"
},
{
"input": "1111100111",
"output": "NO"
},
{
"input": "00110110001110001111",
"output": "NO"
},
{
"input": "11110001001111110001",
"output": "NO"
},
{
"input": "10001111001011111101",
"output": "NO"
},
{
"input": "10000010100000001000110001010100001001001010011",
"output": "YES"
},
{
"input": "01111011111010111100101100001011001010111110000010",
"output": "NO"
},
{
"input": "00100000100100101110011001011011101110110110010100",
"output": "NO"
},
{
"input": "10110100110001001011110101110010100010000000000100101010111110111110100011",
"output": "YES"
},
{
"input": "00011101010101111001011011001101101011111101000010100000111000011100101011",
"output": "NO"
},
{
"input": "01110000110100110101110100111000101101011101011110110100100111100001110111",
"output": "NO"
},
{
"input": "11110110011000100111100111101101011111110100010101011011111101110110110111",
"output": "YES"
},
{
"input": "100100010101110010001011001110100011100010011110100101100011010001001010001001101111001100",
"output": "NO"
},
{
"input": "111110010001011010010011111100110110001111000010100011011100111101111101110010101111011110000001010",
"output": "NO"
},
{
"input": "111110111100010100000100001010111011101011000111011011011010110010100010000101011111000011010011110",
"output": "NO"
},
{
"input": "1011110110111010110111111010010010100011111011110000011000110010011110111010110100011010100010111000",
"output": "NO"
},
{
"input": "0010100111100010110110000011100111110100111110001010000100111111111010111100101101010101001011010110",
"output": "YES"
},
{
"input": "1111010100010100101011101100101101110011000010100010000001111100010011100101010001101111000001011000",
"output": "NO"
},
{
"input": "0101100011001110001110100111100011010101011000000000110110010010111100101111010111100011101100100101",
"output": "YES"
},
{
"input": "0001101110011101110000000010011111101001101111100001001010110000110001100000010001111011011110001101",
"output": "YES"
},
{
"input": "1000010000100000100010000100001000010000100001000010000100001000010000100001000010000100001000010000",
"output": "NO"
},
{
"input": "1000000000100000000010000000001000000000100000000010000000001000000000100000000010000000001000000000",
"output": "YES"
},
{
"input": "0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001",
"output": "YES"
},
{
"input": "1111111111111111111111111111111111111111011111111111111111111111111111111111111111111111111111111111",
"output": "YES"
},
{
"input": "10100101000",
"output": "NO"
},
{
"input": "11110111011101",
"output": "NO"
},
{
"input": "10000000",
"output": "YES"
},
{
"input": "00000001",
"output": "YES"
},
{
"input": "01111111",
"output": "YES"
},
{
"input": "11111110",
"output": "YES"
}
] | 1,689,816,137 | 2,147,483,647 | PyPy 3-64 | WRONG_ANSWER | TESTS | 2 | 92 | 0 | def func(position):
streak = 0
for index in range(1, len(position)):
if int(position[index-1]) == int(position[index]):
streak += 1
else:
streak = 0
if streak >= 7:
return "YES"
return "NO"
position = input()
print(func(position))
| Title: Football
Time Limit: 2 seconds
Memory Limit: 256 megabytes
Problem Description:
Petya loves football very much. One day, as he was watching a football match, he was writing the players' current positions on a piece of paper. To simplify the situation he depicted it as a string consisting of zeroes and ones. A zero corresponds to players of one team; a one corresponds to players of another team. If there are at least 7 players of some team standing one after another, then the situation is considered dangerous. For example, the situation 00100110111111101 is dangerous and 11110111011101 is not. You are given the current situation. Determine whether it is dangerous or not.
Input Specification:
The first input line contains a non-empty string consisting of characters "0" and "1", which represents players. The length of the string does not exceed 100 characters. There's at least one player from each team present on the field.
Output Specification:
Print "YES" if the situation is dangerous. Otherwise, print "NO".
Demo Input:
['001001\n', '1000000001\n']
Demo Output:
['NO\n', 'YES\n']
Note:
none | ```python
def func(position):
streak = 0
for index in range(1, len(position)):
if int(position[index-1]) == int(position[index]):
streak += 1
else:
streak = 0
if streak >= 7:
return "YES"
return "NO"
position = input()
print(func(position))
``` | 0 |
279 | B | Books | PROGRAMMING | 1,400 | [
"binary search",
"brute force",
"implementation",
"two pointers"
] | null | null | When Valera has got some free time, he goes to the library to read some books. Today he's got *t* free minutes to read. That's why Valera took *n* books in the library and for each book he estimated the time he is going to need to read it. Let's number the books by integers from 1 to *n*. Valera needs *a**i* minutes to read the *i*-th book.
Valera decided to choose an arbitrary book with number *i* and read the books one by one, starting from this book. In other words, he will first read book number *i*, then book number *i*<=+<=1, then book number *i*<=+<=2 and so on. He continues the process until he either runs out of the free time or finishes reading the *n*-th book. Valera reads each book up to the end, that is, he doesn't start reading the book if he doesn't have enough free time to finish reading it.
Print the maximum number of books Valera can read. | The first line contains two integers *n* and *t* (1<=≤<=*n*<=≤<=105; 1<=≤<=*t*<=≤<=109) — the number of books and the number of free minutes Valera's got. The second line contains a sequence of *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=104), where number *a**i* shows the number of minutes that the boy needs to read the *i*-th book. | Print a single integer — the maximum number of books Valera can read. | [
"4 5\n3 1 2 1\n",
"3 3\n2 2 3\n"
] | [
"3\n",
"1\n"
] | none | 1,000 | [
{
"input": "4 5\n3 1 2 1",
"output": "3"
},
{
"input": "3 3\n2 2 3",
"output": "1"
},
{
"input": "1 3\n5",
"output": "0"
},
{
"input": "1 10\n4",
"output": "1"
},
{
"input": "2 10\n6 4",
"output": "2"
},
{
"input": "6 10\n2 3 4 2 1 1",
"output": "4"
},
{
"input": "7 13\n6 8 14 9 4 11 10",
"output": "2"
},
{
"input": "10 15\n10 9 1 1 5 10 5 3 7 2",
"output": "3"
},
{
"input": "20 30\n8 1 2 6 9 4 1 9 9 10 4 7 8 9 5 7 1 8 7 4",
"output": "6"
},
{
"input": "30 60\n16 13 22 38 13 35 17 17 20 38 12 19 9 22 20 3 35 34 34 21 35 40 22 3 27 19 12 4 8 19",
"output": "4"
},
{
"input": "100 100\n75 92 18 6 81 67 7 92 100 65 82 32 50 67 85 31 80 91 84 63 39 52 92 81 1 98 24 12 43 48 17 86 51 72 48 95 45 50 12 66 19 79 49 89 34 1 97 75 20 33 96 27 42 23 73 71 93 1 85 19 66 14 17 61 20 39 36 33 42 61 56 64 23 91 80 99 40 74 13 18 98 85 74 39 62 84 46 74 50 23 38 11 79 14 9 25 66 100 25 52",
"output": "3"
},
{
"input": "10 1\n4418 7528 8170 1736 1317 3205 8183 4995 8039 4708",
"output": "0"
},
{
"input": "50 2\n124 214 63 73 996 760 38 571 451 300 970 1 706 937 837 494 619 88 851 411 957 990 842 613 821 649 627 34 693 678 734 116 816 985 705 940 499 493 922 967 854 439 112 644 961 438 189 572 655 550",
"output": "1"
}
] | 1,689,752,285 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 7 | 62 | 0 | a,b=list(map(int,input().split()))
list1=list(map(int,input().split()))
sum=0
count=0
for x in list1:
if x<=b:
sum=x
b-=x
count+=1
print(count) | Title: Books
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
When Valera has got some free time, he goes to the library to read some books. Today he's got *t* free minutes to read. That's why Valera took *n* books in the library and for each book he estimated the time he is going to need to read it. Let's number the books by integers from 1 to *n*. Valera needs *a**i* minutes to read the *i*-th book.
Valera decided to choose an arbitrary book with number *i* and read the books one by one, starting from this book. In other words, he will first read book number *i*, then book number *i*<=+<=1, then book number *i*<=+<=2 and so on. He continues the process until he either runs out of the free time or finishes reading the *n*-th book. Valera reads each book up to the end, that is, he doesn't start reading the book if he doesn't have enough free time to finish reading it.
Print the maximum number of books Valera can read.
Input Specification:
The first line contains two integers *n* and *t* (1<=≤<=*n*<=≤<=105; 1<=≤<=*t*<=≤<=109) — the number of books and the number of free minutes Valera's got. The second line contains a sequence of *n* integers *a*1,<=*a*2,<=...,<=*a**n* (1<=≤<=*a**i*<=≤<=104), where number *a**i* shows the number of minutes that the boy needs to read the *i*-th book.
Output Specification:
Print a single integer — the maximum number of books Valera can read.
Demo Input:
['4 5\n3 1 2 1\n', '3 3\n2 2 3\n']
Demo Output:
['3\n', '1\n']
Note:
none | ```python
a,b=list(map(int,input().split()))
list1=list(map(int,input().split()))
sum=0
count=0
for x in list1:
if x<=b:
sum=x
b-=x
count+=1
print(count)
``` | 0 | |
735 | A | Ostap and Grasshopper | PROGRAMMING | 800 | [
"implementation",
"strings"
] | null | null | On the way to Rio de Janeiro Ostap kills time playing with a grasshopper he took with him in a special box. Ostap builds a line of length *n* such that some cells of this line are empty and some contain obstacles. Then, he places his grasshopper to one of the empty cells and a small insect in another empty cell. The grasshopper wants to eat the insect.
Ostap knows that grasshopper is able to jump to any empty cell that is exactly *k* cells away from the current (to the left or to the right). Note that it doesn't matter whether intermediate cells are empty or not as the grasshopper makes a jump over them. For example, if *k*<==<=1 the grasshopper can jump to a neighboring cell only, and if *k*<==<=2 the grasshopper can jump over a single cell.
Your goal is to determine whether there is a sequence of jumps such that grasshopper will get from his initial position to the cell with an insect. | The first line of the input contains two integers *n* and *k* (2<=≤<=*n*<=≤<=100, 1<=≤<=*k*<=≤<=*n*<=-<=1) — the number of cells in the line and the length of one grasshopper's jump.
The second line contains a string of length *n* consisting of characters '.', '#', 'G' and 'T'. Character '.' means that the corresponding cell is empty, character '#' means that the corresponding cell contains an obstacle and grasshopper can't jump there. Character 'G' means that the grasshopper starts at this position and, finally, 'T' means that the target insect is located at this cell. It's guaranteed that characters 'G' and 'T' appear in this line exactly once. | If there exists a sequence of jumps (each jump of length *k*), such that the grasshopper can get from his initial position to the cell with the insect, print "YES" (without quotes) in the only line of the input. Otherwise, print "NO" (without quotes). | [
"5 2\n#G#T#\n",
"6 1\nT....G\n",
"7 3\nT..#..G\n",
"6 2\n..GT..\n"
] | [
"YES\n",
"YES\n",
"NO\n",
"NO\n"
] | In the first sample, the grasshopper can make one jump to the right in order to get from cell 2 to cell 4.
In the second sample, the grasshopper is only able to jump to neighboring cells but the way to the insect is free — he can get there by jumping left 5 times.
In the third sample, the grasshopper can't make a single jump.
In the fourth sample, the grasshopper can only jump to the cells with odd indices, thus he won't be able to reach the insect. | 500 | [
{
"input": "5 2\n#G#T#",
"output": "YES"
},
{
"input": "6 1\nT....G",
"output": "YES"
},
{
"input": "7 3\nT..#..G",
"output": "NO"
},
{
"input": "6 2\n..GT..",
"output": "NO"
},
{
"input": "2 1\nGT",
"output": "YES"
},
{
"input": "100 5\nG####.####.####.####.####.####.####.####.####.####.####.####.####.####.####.####.####.####.####T####",
"output": "YES"
},
{
"input": "100 5\nG####.####.####.####.####.####.####.####.####.####.####.####.####.#########.####.####.####.####T####",
"output": "NO"
},
{
"input": "2 1\nTG",
"output": "YES"
},
{
"input": "99 1\n...T.............................................................................................G.",
"output": "YES"
},
{
"input": "100 2\nG............#.....#...........#....#...........##............#............#......................T.",
"output": "NO"
},
{
"input": "100 1\n#.#.#.##..#..##.#....##.##.##.#....####..##.#.##..GT..##...###.#.##.#..#..##.###..#.####..#.#.##..##",
"output": "YES"
},
{
"input": "100 2\n..#####.#.#.......#.#.#...##..####..###..#.#######GT####.#.#...##...##.#..###....##.#.#..#.###....#.",
"output": "NO"
},
{
"input": "100 3\nG..................................................................................................T",
"output": "YES"
},
{
"input": "100 3\nG..................................................................................................T",
"output": "YES"
},
{
"input": "100 3\nG..................................#......#......#.......#.#..........#........#......#..........#.T",
"output": "NO"
},
{
"input": "100 3\nG..............#..........#...#..............#.#.....................#......#........#.........#...T",
"output": "NO"
},
{
"input": "100 3\nG##################################################################################################T",
"output": "NO"
},
{
"input": "100 33\nG..................................................................................................T",
"output": "YES"
},
{
"input": "100 33\nG..................................................................................................T",
"output": "YES"
},
{
"input": "100 33\nG.........#........#..........#..............#.................#............................#.#....T",
"output": "YES"
},
{
"input": "100 33\nG.......#..................#..............................#............................#..........T.",
"output": "NO"
},
{
"input": "100 33\nG#..........##...#.#.....................#.#.#.........##..#...........#....#...........##...#..###T",
"output": "YES"
},
{
"input": "100 33\nG..#.#..#..####......#......##...##...#.##........#...#...#.##....###..#...###..##.#.....#......#.T.",
"output": "NO"
},
{
"input": "100 33\nG#....#..#..##.##..#.##.#......#.#.##..##.#.#.##.##....#.#.....####..##...#....##..##..........#...T",
"output": "NO"
},
{
"input": "100 33\nG#######.#..##.##.#...#..#.###.#.##.##.#..#.###..####.##.#.##....####...##..####.#..##.##.##.#....#T",
"output": "NO"
},
{
"input": "100 33\nG#####.#.##.###########.##..##..#######..########..###.###..#.####.######.############..####..#####T",
"output": "NO"
},
{
"input": "100 99\nT..................................................................................................G",
"output": "YES"
},
{
"input": "100 99\nT..................................................................................................G",
"output": "YES"
},
{
"input": "100 99\nT.#...............................#............#..............................##...................G",
"output": "YES"
},
{
"input": "100 99\nT..#....#.##...##########.#.#.#.#...####..#.....#..##..#######.######..#.....###..###...#.......#.#G",
"output": "YES"
},
{
"input": "100 99\nG##################################################################################################T",
"output": "YES"
},
{
"input": "100 9\nT..................................................................................................G",
"output": "YES"
},
{
"input": "100 9\nT.................................................................................................G.",
"output": "NO"
},
{
"input": "100 9\nT................................................................................................G..",
"output": "NO"
},
{
"input": "100 1\nG..................................................................................................T",
"output": "YES"
},
{
"input": "100 1\nT..................................................................................................G",
"output": "YES"
},
{
"input": "100 1\n##########G.........T###############################################################################",
"output": "YES"
},
{
"input": "100 1\n#################################################################################################G.T",
"output": "YES"
},
{
"input": "100 17\n##########G################.################.################.################T#####################",
"output": "YES"
},
{
"input": "100 17\n####.#..#.G######.#########.##..##########.#.################.################T######.####.#########",
"output": "YES"
},
{
"input": "100 17\n.########.G##.####.#.######.###############..#.###########.##.#####.##.#####.#T.###..###.########.##",
"output": "YES"
},
{
"input": "100 1\nG.............................................#....................................................T",
"output": "NO"
},
{
"input": "100 1\nT.#................................................................................................G",
"output": "NO"
},
{
"input": "100 1\n##########G....#....T###############################################################################",
"output": "NO"
},
{
"input": "100 1\n#################################################################################################G#T",
"output": "NO"
},
{
"input": "100 17\nG################.#################################.################T###############################",
"output": "NO"
},
{
"input": "100 17\nG################.###############..###.######.#######.###.#######.##T######################.###.####",
"output": "NO"
},
{
"input": "100 17\nG####.##.##.#####.####....##.####.#########.##.#..#.###############.T############.#########.#.####.#",
"output": "NO"
},
{
"input": "48 1\nT..............................................G",
"output": "YES"
},
{
"input": "23 1\nT.....................G",
"output": "YES"
},
{
"input": "49 1\nG...............................................T",
"output": "YES"
},
{
"input": "3 1\nTG#",
"output": "YES"
},
{
"input": "6 2\n..TG..",
"output": "NO"
},
{
"input": "14 3\n...G.....#..T.",
"output": "NO"
},
{
"input": "5 4\n##GT#",
"output": "NO"
},
{
"input": "6 2\nT#..G.",
"output": "YES"
},
{
"input": "5 2\nT.G.#",
"output": "YES"
},
{
"input": "6 1\nT...G#",
"output": "YES"
},
{
"input": "5 1\nTG###",
"output": "YES"
},
{
"input": "5 4\n.G..T",
"output": "NO"
},
{
"input": "7 2\nT#...#G",
"output": "YES"
},
{
"input": "7 1\n##TG###",
"output": "YES"
},
{
"input": "7 1\n###GT##",
"output": "YES"
},
{
"input": "5 2\nG..T.",
"output": "NO"
},
{
"input": "5 1\nG.T##",
"output": "YES"
},
{
"input": "6 2\nG.T###",
"output": "YES"
},
{
"input": "6 2\nG#T###",
"output": "YES"
},
{
"input": "10 2\n####T..G..",
"output": "NO"
},
{
"input": "3 1\nGT#",
"output": "YES"
},
{
"input": "4 1\nTG##",
"output": "YES"
},
{
"input": "6 1\n.G..T.",
"output": "YES"
},
{
"input": "10 3\n......G..T",
"output": "YES"
},
{
"input": "3 2\nG.T",
"output": "YES"
},
{
"input": "4 1\n#G.T",
"output": "YES"
},
{
"input": "5 2\nT#G##",
"output": "YES"
},
{
"input": "4 2\nG#.T",
"output": "NO"
},
{
"input": "4 1\nGT##",
"output": "YES"
}
] | 1,593,274,107 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 11 | 93 | 6,963,200 | line_size, steps = map(int, input().split())
line = input()
grasshopper = line.index('G')
target = line.index('T')
_from, _to = min(grasshopper, target), max(grasshopper, target)
jumps = [i for i in range(_from, _to + 1, steps)]
gap = abs(grasshopper - target)
def is_clear_line(jumps, line) :
return len([line[cell] for cell in jumps[1: -1] if line[cell] == '.']) == len(jumps[1: -1])
if gap >= steps and is_clear_line(jumps, line) :
print("YES")
else :
print("NO")
| Title: Ostap and Grasshopper
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
On the way to Rio de Janeiro Ostap kills time playing with a grasshopper he took with him in a special box. Ostap builds a line of length *n* such that some cells of this line are empty and some contain obstacles. Then, he places his grasshopper to one of the empty cells and a small insect in another empty cell. The grasshopper wants to eat the insect.
Ostap knows that grasshopper is able to jump to any empty cell that is exactly *k* cells away from the current (to the left or to the right). Note that it doesn't matter whether intermediate cells are empty or not as the grasshopper makes a jump over them. For example, if *k*<==<=1 the grasshopper can jump to a neighboring cell only, and if *k*<==<=2 the grasshopper can jump over a single cell.
Your goal is to determine whether there is a sequence of jumps such that grasshopper will get from his initial position to the cell with an insect.
Input Specification:
The first line of the input contains two integers *n* and *k* (2<=≤<=*n*<=≤<=100, 1<=≤<=*k*<=≤<=*n*<=-<=1) — the number of cells in the line and the length of one grasshopper's jump.
The second line contains a string of length *n* consisting of characters '.', '#', 'G' and 'T'. Character '.' means that the corresponding cell is empty, character '#' means that the corresponding cell contains an obstacle and grasshopper can't jump there. Character 'G' means that the grasshopper starts at this position and, finally, 'T' means that the target insect is located at this cell. It's guaranteed that characters 'G' and 'T' appear in this line exactly once.
Output Specification:
If there exists a sequence of jumps (each jump of length *k*), such that the grasshopper can get from his initial position to the cell with the insect, print "YES" (without quotes) in the only line of the input. Otherwise, print "NO" (without quotes).
Demo Input:
['5 2\n#G#T#\n', '6 1\nT....G\n', '7 3\nT..#..G\n', '6 2\n..GT..\n']
Demo Output:
['YES\n', 'YES\n', 'NO\n', 'NO\n']
Note:
In the first sample, the grasshopper can make one jump to the right in order to get from cell 2 to cell 4.
In the second sample, the grasshopper is only able to jump to neighboring cells but the way to the insect is free — he can get there by jumping left 5 times.
In the third sample, the grasshopper can't make a single jump.
In the fourth sample, the grasshopper can only jump to the cells with odd indices, thus he won't be able to reach the insect. | ```python
line_size, steps = map(int, input().split())
line = input()
grasshopper = line.index('G')
target = line.index('T')
_from, _to = min(grasshopper, target), max(grasshopper, target)
jumps = [i for i in range(_from, _to + 1, steps)]
gap = abs(grasshopper - target)
def is_clear_line(jumps, line) :
return len([line[cell] for cell in jumps[1: -1] if line[cell] == '.']) == len(jumps[1: -1])
if gap >= steps and is_clear_line(jumps, line) :
print("YES")
else :
print("NO")
``` | 0 | |
1,004 | A | Sonya and Hotels | PROGRAMMING | 900 | [
"implementation"
] | null | null | Sonya decided that having her own hotel business is the best way of earning money because she can profit and rest wherever she wants.
The country where Sonya lives is an endless line. There is a city in each integer coordinate on this line. She has $n$ hotels, where the $i$-th hotel is located in the city with coordinate $x_i$. Sonya is a smart girl, so she does not open two or more hotels in the same city.
Sonya understands that her business needs to be expanded by opening new hotels, so she decides to build one more. She wants to make the minimum distance from this hotel to all others to be equal to $d$. The girl understands that there are many possible locations to construct such a hotel. Thus she wants to know the number of possible coordinates of the cities where she can build a new hotel.
Because Sonya is lounging in a jacuzzi in one of her hotels, she is asking you to find the number of cities where she can build a new hotel so that the minimum distance from the original $n$ hotels to the new one is equal to $d$. | The first line contains two integers $n$ and $d$ ($1\leq n\leq 100$, $1\leq d\leq 10^9$) — the number of Sonya's hotels and the needed minimum distance from a new hotel to all others.
The second line contains $n$ different integers in strictly increasing order $x_1, x_2, \ldots, x_n$ ($-10^9\leq x_i\leq 10^9$) — coordinates of Sonya's hotels. | Print the number of cities where Sonya can build a new hotel so that the minimum distance from this hotel to all others is equal to $d$. | [
"4 3\n-3 2 9 16\n",
"5 2\n4 8 11 18 19\n"
] | [
"6\n",
"5\n"
] | In the first example, there are $6$ possible cities where Sonya can build a hotel. These cities have coordinates $-6$, $5$, $6$, $12$, $13$, and $19$.
In the second example, there are $5$ possible cities where Sonya can build a hotel. These cities have coordinates $2$, $6$, $13$, $16$, and $21$. | 500 | [
{
"input": "4 3\n-3 2 9 16",
"output": "6"
},
{
"input": "5 2\n4 8 11 18 19",
"output": "5"
},
{
"input": "10 10\n-67 -59 -49 -38 -8 20 41 59 74 83",
"output": "8"
},
{
"input": "10 10\n0 20 48 58 81 95 111 137 147 159",
"output": "9"
},
{
"input": "100 1\n0 1 2 3 4 5 7 8 10 11 12 13 14 15 16 17 19 21 22 23 24 25 26 27 28 30 32 33 36 39 40 41 42 46 48 53 54 55 59 60 61 63 65 68 70 71 74 75 76 79 80 81 82 84 88 89 90 91 93 94 96 97 98 100 101 102 105 106 107 108 109 110 111 113 114 115 116 117 118 120 121 122 125 126 128 131 132 133 134 135 137 138 139 140 143 144 146 147 148 149",
"output": "47"
},
{
"input": "1 1000000000\n-1000000000",
"output": "2"
},
{
"input": "2 1000000000\n-1000000000 1000000000",
"output": "3"
},
{
"input": "100 2\n1 3 5 6 8 9 12 13 14 17 18 21 22 23 24 25 26 27 29 30 34 35 36 39 41 44 46 48 52 53 55 56 57 59 61 63 64 66 68 69 70 71 72 73 75 76 77 79 80 81 82 87 88 91 92 93 94 95 96 97 99 100 102 103 104 106 109 110 111 112 113 114 115 117 118 119 120 122 124 125 127 128 129 130 131 132 133 134 136 137 139 140 141 142 143 145 146 148 149 150",
"output": "6"
},
{
"input": "100 3\n0 1 3 6 7 8 9 10 13 14 16 17 18 20 21 22 24 26 27 30 33 34 35 36 37 39 42 43 44 45 46 48 53 54 55 56 57 58 61 63 64 65 67 69 70 72 73 76 77 78 79 81 82 83 85 86 87 88 90 92 93 95 96 97 98 99 100 101 104 105 108 109 110 113 114 115 116 118 120 121 123 124 125 128 130 131 132 133 134 135 136 137 139 140 141 142 146 147 148 150",
"output": "2"
},
{
"input": "1 1000000000\n1000000000",
"output": "2"
},
{
"input": "10 2\n-93 -62 -53 -42 -38 11 57 58 87 94",
"output": "17"
},
{
"input": "2 500000000\n-1000000000 1000000000",
"output": "4"
},
{
"input": "100 10\n-489 -476 -445 -432 -430 -421 -420 -418 -412 -411 -404 -383 -356 -300 -295 -293 -287 -276 -265 -263 -258 -251 -249 -246 -220 -219 -205 -186 -166 -157 -143 -137 -136 -130 -103 -86 -80 -69 -67 -55 -43 -41 -40 -26 -19 -9 16 29 41 42 54 76 84 97 98 99 101 115 134 151 157 167 169 185 197 204 208 226 227 232 234 249 259 266 281 282 293 298 300 306 308 313 319 328 331 340 341 344 356 362 366 380 390 399 409 411 419 444 455 498",
"output": "23"
},
{
"input": "1 1000000000\n999999999",
"output": "2"
},
{
"input": "1 1\n-5",
"output": "2"
},
{
"input": "2 1\n-1000000000 1000000000",
"output": "4"
},
{
"input": "1 2\n1",
"output": "2"
},
{
"input": "4 5\n0 20 40 60",
"output": "8"
},
{
"input": "1 1\n-10",
"output": "2"
},
{
"input": "1 1\n-1000000000",
"output": "2"
},
{
"input": "1 1000000000\n0",
"output": "2"
},
{
"input": "1 2\n-10",
"output": "2"
},
{
"input": "1 1\n2",
"output": "2"
},
{
"input": "1 5\n-100",
"output": "2"
},
{
"input": "2 1000000000\n999999999 1000000000",
"output": "2"
},
{
"input": "2 2\n0 5",
"output": "4"
},
{
"input": "1 2\n-5",
"output": "2"
},
{
"input": "1 1\n1",
"output": "2"
},
{
"input": "1 5\n-20",
"output": "2"
},
{
"input": "2 100000000\n-1000000000 1000000000",
"output": "4"
},
{
"input": "1 1000000000\n147483641",
"output": "2"
},
{
"input": "3 3\n1 8 9",
"output": "4"
},
{
"input": "2 1\n1 1000000000",
"output": "4"
},
{
"input": "1 2\n-4",
"output": "2"
},
{
"input": "2 1\n-1000000000 -1",
"output": "4"
}
] | 1,530,845,406 | 3,786 | Python 3 | RUNTIME_ERROR | TESTS | 0 | 108 | 409,600 | import math as ma
from sys import exit
from decimal import Decimal as dec
def li():
return list(map(int , input().split()))
def num():
return map(int , input().split())
def nu():
return int(input())
n=nu()
a=li()
f=[-1]*100001
z=[0]*n
c=0
for i in range(len(a)-1,0,-1):
if(f[a[i]]==-1):
c+=1
z[i]=c
f[a[i]]=1
else:
z[i] = c
f=[-1]*100001
xx=0
#print(z)
for i in range(n-1):
if(f[a[i]]==-1):
xx+=z[i+1]
f[a[i]]=1
print(xx) | Title: Sonya and Hotels
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Sonya decided that having her own hotel business is the best way of earning money because she can profit and rest wherever she wants.
The country where Sonya lives is an endless line. There is a city in each integer coordinate on this line. She has $n$ hotels, where the $i$-th hotel is located in the city with coordinate $x_i$. Sonya is a smart girl, so she does not open two or more hotels in the same city.
Sonya understands that her business needs to be expanded by opening new hotels, so she decides to build one more. She wants to make the minimum distance from this hotel to all others to be equal to $d$. The girl understands that there are many possible locations to construct such a hotel. Thus she wants to know the number of possible coordinates of the cities where she can build a new hotel.
Because Sonya is lounging in a jacuzzi in one of her hotels, she is asking you to find the number of cities where she can build a new hotel so that the minimum distance from the original $n$ hotels to the new one is equal to $d$.
Input Specification:
The first line contains two integers $n$ and $d$ ($1\leq n\leq 100$, $1\leq d\leq 10^9$) — the number of Sonya's hotels and the needed minimum distance from a new hotel to all others.
The second line contains $n$ different integers in strictly increasing order $x_1, x_2, \ldots, x_n$ ($-10^9\leq x_i\leq 10^9$) — coordinates of Sonya's hotels.
Output Specification:
Print the number of cities where Sonya can build a new hotel so that the minimum distance from this hotel to all others is equal to $d$.
Demo Input:
['4 3\n-3 2 9 16\n', '5 2\n4 8 11 18 19\n']
Demo Output:
['6\n', '5\n']
Note:
In the first example, there are $6$ possible cities where Sonya can build a hotel. These cities have coordinates $-6$, $5$, $6$, $12$, $13$, and $19$.
In the second example, there are $5$ possible cities where Sonya can build a hotel. These cities have coordinates $2$, $6$, $13$, $16$, and $21$. | ```python
import math as ma
from sys import exit
from decimal import Decimal as dec
def li():
return list(map(int , input().split()))
def num():
return map(int , input().split())
def nu():
return int(input())
n=nu()
a=li()
f=[-1]*100001
z=[0]*n
c=0
for i in range(len(a)-1,0,-1):
if(f[a[i]]==-1):
c+=1
z[i]=c
f[a[i]]=1
else:
z[i] = c
f=[-1]*100001
xx=0
#print(z)
for i in range(n-1):
if(f[a[i]]==-1):
xx+=z[i+1]
f[a[i]]=1
print(xx)
``` | -1 | |
479 | A | Expression | PROGRAMMING | 1,000 | [
"brute force",
"math"
] | null | null | Petya studies in a school and he adores Maths. His class has been studying arithmetic expressions. On the last class the teacher wrote three positive integers *a*, *b*, *c* on the blackboard. The task was to insert signs of operations '+' and '*', and probably brackets between the numbers so that the value of the resulting expression is as large as possible. Let's consider an example: assume that the teacher wrote numbers 1, 2 and 3 on the blackboard. Here are some ways of placing signs and brackets:
- 1+2*3=7 - 1*(2+3)=5 - 1*2*3=6 - (1+2)*3=9
Note that you can insert operation signs only between *a* and *b*, and between *b* and *c*, that is, you cannot swap integers. For instance, in the given sample you cannot get expression (1+3)*2.
It's easy to see that the maximum value that you can obtain is 9.
Your task is: given *a*, *b* and *c* print the maximum value that you can get. | The input contains three integers *a*, *b* and *c*, each on a single line (1<=≤<=*a*,<=*b*,<=*c*<=≤<=10). | Print the maximum value of the expression that you can obtain. | [
"1\n2\n3\n",
"2\n10\n3\n"
] | [
"9\n",
"60\n"
] | none | 500 | [
{
"input": "1\n2\n3",
"output": "9"
},
{
"input": "2\n10\n3",
"output": "60"
},
{
"input": "1\n1\n1",
"output": "3"
},
{
"input": "1\n2\n1",
"output": "4"
},
{
"input": "10\n10\n10",
"output": "1000"
},
{
"input": "5\n1\n3",
"output": "20"
},
{
"input": "3\n1\n5",
"output": "20"
},
{
"input": "6\n7\n1",
"output": "48"
},
{
"input": "1\n8\n3",
"output": "27"
},
{
"input": "9\n7\n2",
"output": "126"
},
{
"input": "1\n1\n10",
"output": "20"
},
{
"input": "9\n1\n1",
"output": "18"
},
{
"input": "10\n5\n6",
"output": "300"
},
{
"input": "8\n9\n7",
"output": "504"
},
{
"input": "4\n2\n10",
"output": "80"
},
{
"input": "2\n8\n3",
"output": "48"
},
{
"input": "3\n5\n7",
"output": "105"
},
{
"input": "1\n10\n1",
"output": "12"
},
{
"input": "2\n2\n2",
"output": "8"
},
{
"input": "5\n6\n1",
"output": "35"
},
{
"input": "10\n1\n1",
"output": "20"
},
{
"input": "1\n6\n1",
"output": "8"
},
{
"input": "1\n9\n1",
"output": "11"
},
{
"input": "2\n1\n2",
"output": "6"
},
{
"input": "2\n6\n1",
"output": "14"
},
{
"input": "9\n2\n1",
"output": "27"
},
{
"input": "1\n9\n2",
"output": "20"
},
{
"input": "1\n3\n1",
"output": "5"
},
{
"input": "2\n1\n1",
"output": "4"
}
] | 1,690,539,758 | 2,147,483,647 | Python 3 | OK | TESTS | 29 | 46 | 0 | a = int(input())
b = int(input())
c = int(input())
if a == 1 and c == 1:
d = a+b+c
elif a==1:
d = (a+b)*c
elif c==1:
d = a*(b+c)
elif b == 1:
if a<c:
d = (a+b)*c
else:
d = a*(b+c)
else:
d = a*b*c
print(d) | Title: Expression
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya studies in a school and he adores Maths. His class has been studying arithmetic expressions. On the last class the teacher wrote three positive integers *a*, *b*, *c* on the blackboard. The task was to insert signs of operations '+' and '*', and probably brackets between the numbers so that the value of the resulting expression is as large as possible. Let's consider an example: assume that the teacher wrote numbers 1, 2 and 3 on the blackboard. Here are some ways of placing signs and brackets:
- 1+2*3=7 - 1*(2+3)=5 - 1*2*3=6 - (1+2)*3=9
Note that you can insert operation signs only between *a* and *b*, and between *b* and *c*, that is, you cannot swap integers. For instance, in the given sample you cannot get expression (1+3)*2.
It's easy to see that the maximum value that you can obtain is 9.
Your task is: given *a*, *b* and *c* print the maximum value that you can get.
Input Specification:
The input contains three integers *a*, *b* and *c*, each on a single line (1<=≤<=*a*,<=*b*,<=*c*<=≤<=10).
Output Specification:
Print the maximum value of the expression that you can obtain.
Demo Input:
['1\n2\n3\n', '2\n10\n3\n']
Demo Output:
['9\n', '60\n']
Note:
none | ```python
a = int(input())
b = int(input())
c = int(input())
if a == 1 and c == 1:
d = a+b+c
elif a==1:
d = (a+b)*c
elif c==1:
d = a*(b+c)
elif b == 1:
if a<c:
d = (a+b)*c
else:
d = a*(b+c)
else:
d = a*b*c
print(d)
``` | 3 | |
913 | A | Modular Exponentiation | PROGRAMMING | 900 | [
"implementation",
"math"
] | null | null | The following problem is well-known: given integers *n* and *m*, calculate
where 2*n*<==<=2·2·...·2 (*n* factors), and denotes the remainder of division of *x* by *y*.
You are asked to solve the "reverse" problem. Given integers *n* and *m*, calculate | The first line contains a single integer *n* (1<=≤<=*n*<=≤<=108).
The second line contains a single integer *m* (1<=≤<=*m*<=≤<=108). | Output a single integer — the value of . | [
"4\n42\n",
"1\n58\n",
"98765432\n23456789\n"
] | [
"10\n",
"0\n",
"23456789\n"
] | In the first example, the remainder of division of 42 by 2<sup class="upper-index">4</sup> = 16 is equal to 10.
In the second example, 58 is divisible by 2<sup class="upper-index">1</sup> = 2 without remainder, and the answer is 0. | 500 | [
{
"input": "4\n42",
"output": "10"
},
{
"input": "1\n58",
"output": "0"
},
{
"input": "98765432\n23456789",
"output": "23456789"
},
{
"input": "8\n88127381",
"output": "149"
},
{
"input": "32\n92831989",
"output": "92831989"
},
{
"input": "92831989\n25",
"output": "25"
},
{
"input": "100000000\n100000000",
"output": "100000000"
},
{
"input": "7\n1234",
"output": "82"
},
{
"input": "1\n1",
"output": "1"
},
{
"input": "1\n100000000",
"output": "0"
},
{
"input": "100000000\n1",
"output": "1"
},
{
"input": "1\n2",
"output": "0"
},
{
"input": "2\n1",
"output": "1"
},
{
"input": "2\n2",
"output": "2"
},
{
"input": "2\n3",
"output": "3"
},
{
"input": "2\n4",
"output": "0"
},
{
"input": "2\n5",
"output": "1"
},
{
"input": "25\n33554432",
"output": "0"
},
{
"input": "26\n33554432",
"output": "33554432"
},
{
"input": "25\n67108864",
"output": "0"
},
{
"input": "26\n67108864",
"output": "0"
},
{
"input": "25\n92831989",
"output": "25723125"
},
{
"input": "26\n92831989",
"output": "25723125"
},
{
"input": "27\n92831989",
"output": "92831989"
},
{
"input": "29\n92831989",
"output": "92831989"
},
{
"input": "30\n92831989",
"output": "92831989"
},
{
"input": "31\n92831989",
"output": "92831989"
},
{
"input": "99812399\n93172892",
"output": "93172892"
},
{
"input": "67108864\n12345678",
"output": "12345678"
},
{
"input": "3\n98391849",
"output": "1"
},
{
"input": "13\n1231232",
"output": "2432"
},
{
"input": "18\n9842194",
"output": "142866"
},
{
"input": "24\n71237177",
"output": "4128313"
},
{
"input": "11\n65535",
"output": "2047"
},
{
"input": "11\n65536",
"output": "0"
},
{
"input": "12\n123",
"output": "123"
},
{
"input": "123456\n12",
"output": "12"
},
{
"input": "88\n888",
"output": "888"
},
{
"input": "888\n88",
"output": "88"
},
{
"input": "8888\n8888",
"output": "8888"
},
{
"input": "64\n128",
"output": "128"
},
{
"input": "128\n64",
"output": "64"
},
{
"input": "60\n9999999",
"output": "9999999"
},
{
"input": "200\n100000",
"output": "100000"
},
{
"input": "3\n8",
"output": "0"
},
{
"input": "10000000\n25024886",
"output": "25024886"
},
{
"input": "100\n100000",
"output": "100000"
},
{
"input": "99999999\n100000000",
"output": "100000000"
},
{
"input": "70\n12345678",
"output": "12345678"
}
] | 1,594,348,946 | 2,147,483,647 | PyPy 3 | OK | TESTS | 49 | 155 | 33,280,000 | n=int(input())
m=int(input())
x=2**n
ans=(m%x)
print(ans)
| Title: Modular Exponentiation
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The following problem is well-known: given integers *n* and *m*, calculate
where 2*n*<==<=2·2·...·2 (*n* factors), and denotes the remainder of division of *x* by *y*.
You are asked to solve the "reverse" problem. Given integers *n* and *m*, calculate
Input Specification:
The first line contains a single integer *n* (1<=≤<=*n*<=≤<=108).
The second line contains a single integer *m* (1<=≤<=*m*<=≤<=108).
Output Specification:
Output a single integer — the value of .
Demo Input:
['4\n42\n', '1\n58\n', '98765432\n23456789\n']
Demo Output:
['10\n', '0\n', '23456789\n']
Note:
In the first example, the remainder of division of 42 by 2<sup class="upper-index">4</sup> = 16 is equal to 10.
In the second example, 58 is divisible by 2<sup class="upper-index">1</sup> = 2 without remainder, and the answer is 0. | ```python
n=int(input())
m=int(input())
x=2**n
ans=(m%x)
print(ans)
``` | 3 | |
731 | A | Night at the Museum | PROGRAMMING | 800 | [
"implementation",
"strings"
] | null | null | Grigoriy, like the hero of one famous comedy film, found a job as a night security guard at the museum. At first night he received embosser and was to take stock of the whole exposition.
Embosser is a special devise that allows to "print" the text of a plastic tape. Text is printed sequentially, character by character. The device consists of a wheel with a lowercase English letters written in a circle, static pointer to the current letter and a button that print the chosen letter. At one move it's allowed to rotate the alphabetic wheel one step clockwise or counterclockwise. Initially, static pointer points to letter 'a'. Other letters are located as shown on the picture:
After Grigoriy add new item to the base he has to print its name on the plastic tape and attach it to the corresponding exhibit. It's not required to return the wheel to its initial position with pointer on the letter 'a'.
Our hero is afraid that some exhibits may become alive and start to attack him, so he wants to print the names as fast as possible. Help him, for the given string find the minimum number of rotations of the wheel required to print it. | The only line of input contains the name of some exhibit — the non-empty string consisting of no more than 100 characters. It's guaranteed that the string consists of only lowercase English letters. | Print one integer — the minimum number of rotations of the wheel, required to print the name given in the input. | [
"zeus\n",
"map\n",
"ares\n"
] | [
"18\n",
"35\n",
"34\n"
] | To print the string from the first sample it would be optimal to perform the following sequence of rotations:
1. from 'a' to 'z' (1 rotation counterclockwise), 1. from 'z' to 'e' (5 clockwise rotations), 1. from 'e' to 'u' (10 rotations counterclockwise), 1. from 'u' to 's' (2 counterclockwise rotations). | 500 | [
{
"input": "zeus",
"output": "18"
},
{
"input": "map",
"output": "35"
},
{
"input": "ares",
"output": "34"
},
{
"input": "l",
"output": "11"
},
{
"input": "abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuv",
"output": "99"
},
{
"input": "gngvi",
"output": "44"
},
{
"input": "aaaaa",
"output": "0"
},
{
"input": "a",
"output": "0"
},
{
"input": "z",
"output": "1"
},
{
"input": "vyadeehhikklnoqrs",
"output": "28"
},
{
"input": "jjiihhhhgggfedcccbazyxx",
"output": "21"
},
{
"input": "fyyptqqxuciqvwdewyppjdzur",
"output": "117"
},
{
"input": "fqcnzmzmbobmancqcoalzmanaobpdse",
"output": "368"
},
{
"input": "zzzzzaaaaaaazzzzzzaaaaaaazzzzzzaaaazzzza",
"output": "8"
},
{
"input": "aucnwhfixuruefkypvrvnvznwtjgwlghoqtisbkhuwxmgzuljvqhmnwzisnsgjhivnjmbknptxatdkelhzkhsuxzrmlcpeoyukiy",
"output": "644"
},
{
"input": "sssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssssss",
"output": "8"
},
{
"input": "nypjygrdtpzpigzyrisqeqfriwgwlengnezppgttgtndbrryjdl",
"output": "421"
},
{
"input": "pnllnnmmmmoqqqqqrrtssssuuvtsrpopqoonllmonnnpppopnonoopooqpnopppqppqstuuuwwwwvxzxzzaa",
"output": "84"
},
{
"input": "btaoahqgxnfsdmzsjxgvdwjukcvereqeskrdufqfqgzqfsftdqcthtkcnaipftcnco",
"output": "666"
},
{
"input": "eeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeerrrrrrrrrrrrrrrrwwwwwwwwww",
"output": "22"
},
{
"input": "uyknzcrwjyzmscqucclvacmorepdgmnyhmakmmnygqwglrxkxhkpansbmruwxdeoprxzmpsvwackopujxbbkpwyeggsvjykpxh",
"output": "643"
},
{
"input": "gzwpooohffcxwtpjgfzwtooiccxsrrokezutoojdzwsrmmhecaxwrojcbyrqlfdwwrliiib",
"output": "245"
},
{
"input": "dbvnkktasjdwqsrzfwwtmjgbcxggdxsoeilecihduypktkkbwfbruxzzhlttrssicgdwqruddwrlbtxgmhdbatzvdxbbro",
"output": "468"
},
{
"input": "mdtvowlktxzzbuaeiuebfeorgbdczauxsovbucactkvyvemsknsjfhifqgycqredzchipmkvzbxdjkcbyukomjlzvxzoswumned",
"output": "523"
},
{
"input": "kkkkkkkaaaaxxaaaaaaaxxxxxxxxaaaaaaxaaaaaaaaaakkkkkkkkkaaaaaaannnnnxxxxkkkkkkkkaannnnnnna",
"output": "130"
},
{
"input": "dffiknqqrsvwzcdgjkmpqtuwxadfhkkkmpqrtwxyadfggjmpppsuuwyyzcdgghhknnpsvvvwwwyabccffiloqruwwyyzabeeehh",
"output": "163"
},
{
"input": "qpppmmkjihgecbyvvsppnnnkjiffeebaaywutrrqpmkjhgddbzzzywtssssqnmmljheddbbaxvusrqonmlifedbbzyywwtqnkheb",
"output": "155"
},
{
"input": "wvvwwwvvwxxxyyyxxwwvwwvuttttttuvvwxxwxxyxxwwwwwvvuttssrssstsssssrqpqqppqrssrsrrssrssssrrsrqqrrqpppqp",
"output": "57"
},
{
"input": "dqcpcobpcobnznamznamzlykxkxlxlylzmaobnaobpbnanbpcoaobnboaoboanzlymzmykylymylzlylymanboanaocqdqesfrfs",
"output": "1236"
},
{
"input": "nnnnnnnnnnnnnnnnnnnnaaaaaaaaaaaaaaaaaaaakkkkkkkkkkkkkkkkkkkkkkaaaaaaaaaaaaaaaaaaaaxxxxxxxxxxxxxxxxxx",
"output": "49"
},
{
"input": "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "0"
},
{
"input": "cgilqsuwzaffilptwwbgmnttyyejkorxzflqvzbddhmnrvxchijpuwaeiimosxyycejlpquuwbfkpvbgijkqvxybdjjjptxcfkqt",
"output": "331"
},
{
"input": "ufsepwgtzgtgjssxaitgpailuvgqweoppszjwhoxdhhhpwwdorwfrdjwcdekxiktwziqwbkvbknrtvajpyeqbjvhiikxxaejjpte",
"output": "692"
},
{
"input": "uhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuhuh",
"output": "1293"
},
{
"input": "vvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvgggggggggggggggggggggggggggggggggggggggggggggggggg",
"output": "16"
},
{
"input": "lyidmjyzbszgiwkxhhpnnthfwcvvstueionspfrvqgkvngmwyhezlosrpdnbvtcjjxxsykixwnepbumaacdzadlqhnjlcejovple",
"output": "616"
},
{
"input": "etzqqbaveffalkdguunfmyyrzkccnxmlluxeasqmopxzfvlkbhipqdwjgrttoemruohgwukfisdhznqyvhswbbypoxgtxyappcrl",
"output": "605"
},
{
"input": "lizussgedcbdjhrbeskhgatyozvwwekanlggcstijrniivupmcoofbaxfqrxddyzzptwxcftlhajsmmkkriarrqtkoauhcqefyud",
"output": "549"
},
{
"input": "dvjuvgfdogpknmbowlsfjzcimnygbtjiucyeeroqwhmzwpjqxlbjkqawrdtmvxbiqufllfuqibxvmtdrwaqkjblxqjpwzmhwqore",
"output": "688"
},
{
"input": "eeycuijtbgynmiczjfslwobmnkpgodfgvujvduyfeqchuaoktqrrairkkmmsjahltfcxwtpzzyddxrqfxabfoocmpuviinrjitsc",
"output": "604"
},
{
"input": "cgglnakewwvzoytaghksebrhjdbcdegssuzilrcppayxtgxopybbwshvyqnzhdsifkuwghourmeottrgjwdqpihbklvfzxpomqsa",
"output": "572"
},
{
"input": "aexullmxncckzryymfnuugdklaffevabqqztelpvojecljnhqldazdcaamubpenwxikysxxjjctvbndprsolzehywmgnvkgqvrfp",
"output": "609"
},
{
"input": "psnoieutsvvcwfhtnnphhxkwigzsbzyjmdiyl",
"output": "223"
},
{
"input": "aa",
"output": "0"
}
] | 1,663,816,541 | 2,147,483,647 | Python 3 | OK | TESTS | 44 | 46 | 0 | #!/usr/bin/env python3
# coding:utf-8
if __name__ == "__main__":
n = input()
t = "a"
s = 0
for item in n:
delta = abs(ord(item) - ord(t))
if delta >= 13:
delta = 26 - delta
s += delta
t = item
print(s)
| Title: Night at the Museum
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Grigoriy, like the hero of one famous comedy film, found a job as a night security guard at the museum. At first night he received embosser and was to take stock of the whole exposition.
Embosser is a special devise that allows to "print" the text of a plastic tape. Text is printed sequentially, character by character. The device consists of a wheel with a lowercase English letters written in a circle, static pointer to the current letter and a button that print the chosen letter. At one move it's allowed to rotate the alphabetic wheel one step clockwise or counterclockwise. Initially, static pointer points to letter 'a'. Other letters are located as shown on the picture:
After Grigoriy add new item to the base he has to print its name on the plastic tape and attach it to the corresponding exhibit. It's not required to return the wheel to its initial position with pointer on the letter 'a'.
Our hero is afraid that some exhibits may become alive and start to attack him, so he wants to print the names as fast as possible. Help him, for the given string find the minimum number of rotations of the wheel required to print it.
Input Specification:
The only line of input contains the name of some exhibit — the non-empty string consisting of no more than 100 characters. It's guaranteed that the string consists of only lowercase English letters.
Output Specification:
Print one integer — the minimum number of rotations of the wheel, required to print the name given in the input.
Demo Input:
['zeus\n', 'map\n', 'ares\n']
Demo Output:
['18\n', '35\n', '34\n']
Note:
To print the string from the first sample it would be optimal to perform the following sequence of rotations:
1. from 'a' to 'z' (1 rotation counterclockwise), 1. from 'z' to 'e' (5 clockwise rotations), 1. from 'e' to 'u' (10 rotations counterclockwise), 1. from 'u' to 's' (2 counterclockwise rotations). | ```python
#!/usr/bin/env python3
# coding:utf-8
if __name__ == "__main__":
n = input()
t = "a"
s = 0
for item in n:
delta = abs(ord(item) - ord(t))
if delta >= 13:
delta = 26 - delta
s += delta
t = item
print(s)
``` | 3 | |
612 | A | The Text Splitting | PROGRAMMING | 1,300 | [
"brute force",
"implementation",
"strings"
] | null | null | You are given the string *s* of length *n* and the numbers *p*,<=*q*. Split the string *s* to pieces of length *p* and *q*.
For example, the string "Hello" for *p*<==<=2, *q*<==<=3 can be split to the two strings "Hel" and "lo" or to the two strings "He" and "llo".
Note it is allowed to split the string *s* to the strings only of length *p* or to the strings only of length *q* (see the second sample test). | The first line contains three positive integers *n*,<=*p*,<=*q* (1<=≤<=*p*,<=*q*<=≤<=*n*<=≤<=100).
The second line contains the string *s* consists of lowercase and uppercase latin letters and digits. | If it's impossible to split the string *s* to the strings of length *p* and *q* print the only number "-1".
Otherwise in the first line print integer *k* — the number of strings in partition of *s*.
Each of the next *k* lines should contain the strings in partition. Each string should be of the length *p* or *q*. The string should be in order of their appearing in string *s* — from left to right.
If there are several solutions print any of them. | [
"5 2 3\nHello\n",
"10 9 5\nCodeforces\n",
"6 4 5\nPrivet\n",
"8 1 1\nabacabac\n"
] | [
"2\nHe\nllo\n",
"2\nCodef\norces\n",
"-1\n",
"8\na\nb\na\nc\na\nb\na\nc\n"
] | none | 0 | [
{
"input": "5 2 3\nHello",
"output": "2\nHe\nllo"
},
{
"input": "10 9 5\nCodeforces",
"output": "2\nCodef\norces"
},
{
"input": "6 4 5\nPrivet",
"output": "-1"
},
{
"input": "8 1 1\nabacabac",
"output": "8\na\nb\na\nc\na\nb\na\nc"
},
{
"input": "1 1 1\n1",
"output": "1\n1"
},
{
"input": "10 8 1\nuTl9w4lcdo",
"output": "10\nu\nT\nl\n9\nw\n4\nl\nc\nd\no"
},
{
"input": "20 6 4\nfmFRpk2NrzSvnQC9gB61",
"output": "5\nfmFR\npk2N\nrzSv\nnQC9\ngB61"
},
{
"input": "30 23 6\nWXDjl9kitaDTY673R5xyTlbL9gqeQ6",
"output": "5\nWXDjl9\nkitaDT\nY673R5\nxyTlbL\n9gqeQ6"
},
{
"input": "40 14 3\nSOHBIkWEv7ScrkHgMtFFxP9G7JQLYXFoH1sJDAde",
"output": "6\nSOHBIkWEv7Scrk\nHgMtFFxP9G7JQL\nYXF\noH1\nsJD\nAde"
},
{
"input": "50 16 3\nXCgVJUu4aMQ7HMxZjNxe3XARNiahK303g9y7NV8oN6tWdyXrlu",
"output": "8\nXCgVJUu4aMQ7HMxZ\njNxe3XARNiahK303\ng9y\n7NV\n8oN\n6tW\ndyX\nrlu"
},
{
"input": "60 52 8\nhae0PYwXcW2ziQCOSci5VaElHLZCZI81ULSHgpyG3fuZaP0fHjN4hCKogONj",
"output": "2\nhae0PYwXcW2ziQCOSci5VaElHLZCZI81ULSHgpyG3fuZaP0fHjN4\nhCKogONj"
},
{
"input": "70 50 5\n1BH1ECq7hjzooQOZdbiYHTAgATcP5mxI7kLI9rqA9AriWc9kE5KoLa1zmuTDFsd2ClAPPY",
"output": "14\n1BH1E\nCq7hj\nzooQO\nZdbiY\nHTAgA\nTcP5m\nxI7kL\nI9rqA\n9AriW\nc9kE5\nKoLa1\nzmuTD\nFsd2C\nlAPPY"
},
{
"input": "80 51 8\no2mpu1FCofuiLQb472qczCNHfVzz5TfJtVMrzgN3ff7FwlAY0fQ0ROhWmIX2bggodORNA76bHMjA5yyc",
"output": "10\no2mpu1FC\nofuiLQb4\n72qczCNH\nfVzz5TfJ\ntVMrzgN3\nff7FwlAY\n0fQ0ROhW\nmIX2bggo\ndORNA76b\nHMjA5yyc"
},
{
"input": "90 12 7\nclcImtsw176FFOA6OHGFxtEfEyhFh5bH4iktV0Y8onIcn0soTwiiHUFRWC6Ow36tT5bsQjgrVSTcB8fAVoe7dJIWkE",
"output": "10\nclcImtsw176F\nFOA6OHGFxtEf\nEyhFh5bH4ikt\nV0Y8onIcn0so\nTwiiHUF\nRWC6Ow3\n6tT5bsQ\njgrVSTc\nB8fAVoe\n7dJIWkE"
},
{
"input": "100 25 5\n2SRB9mRpXMRND5zQjeRxc4GhUBlEQSmLgnUtB9xTKoC5QM9uptc8dKwB88XRJy02r7edEtN2C6D60EjzK1EHPJcWNj6fbF8kECeB",
"output": "20\n2SRB9\nmRpXM\nRND5z\nQjeRx\nc4GhU\nBlEQS\nmLgnU\ntB9xT\nKoC5Q\nM9upt\nc8dKw\nB88XR\nJy02r\n7edEt\nN2C6D\n60Ejz\nK1EHP\nJcWNj\n6fbF8\nkECeB"
},
{
"input": "100 97 74\nxL8yd8lENYnXZs28xleyci4SxqsjZqkYzkEbQXfLQ4l4gKf9QQ9xjBjeZ0f9xQySf5psDUDkJEtPLsa62n4CLc6lF6E2yEqvt4EJ",
"output": "-1"
},
{
"input": "51 25 11\nwpk5wqrB6d3qE1slUrzJwMFafnnOu8aESlvTEb7Pp42FDG2iGQn",
"output": "-1"
},
{
"input": "70 13 37\nfzL91QIJvNoZRP4A9aNRT2GTksd8jEb1713pnWFaCGKHQ1oYvlTHXIl95lqyZRKJ1UPYvT",
"output": "-1"
},
{
"input": "10 3 1\nXQ2vXLPShy",
"output": "10\nX\nQ\n2\nv\nX\nL\nP\nS\nh\ny"
},
{
"input": "4 2 3\naaaa",
"output": "2\naa\naa"
},
{
"input": "100 1 1\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaabbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbb",
"output": "100\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb"
},
{
"input": "99 2 4\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "-1"
},
{
"input": "11 2 3\nhavanahavan",
"output": "4\nha\nvan\naha\nvan"
},
{
"input": "100 2 2\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "50\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa\naa"
},
{
"input": "17 3 5\ngopstopmipodoshli",
"output": "5\ngop\nsto\npmi\npod\noshli"
},
{
"input": "5 4 3\nfoyku",
"output": "-1"
},
{
"input": "99 2 2\n123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789",
"output": "-1"
},
{
"input": "99 2 2\nrecursionishellrecursionishellrecursionishellrecursionishellrecursionishellrecursionishelldontuseit",
"output": "-1"
},
{
"input": "11 2 3\nqibwnnvqqgo",
"output": "4\nqi\nbwn\nnvq\nqgo"
},
{
"input": "4 4 3\nhhhh",
"output": "1\nhhhh"
},
{
"input": "99 2 2\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "-1"
},
{
"input": "99 2 5\nhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhh",
"output": "21\nhh\nhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh\nhhhhh"
},
{
"input": "10 5 9\nCodeforces",
"output": "2\nCodef\norces"
},
{
"input": "10 5 9\naaaaaaaaaa",
"output": "2\naaaaa\naaaaa"
},
{
"input": "11 3 2\nmlmqpohwtsf",
"output": "5\nmlm\nqp\noh\nwt\nsf"
},
{
"input": "3 3 2\nzyx",
"output": "1\nzyx"
},
{
"input": "100 3 3\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "-1"
},
{
"input": "4 2 3\nzyxw",
"output": "2\nzy\nxw"
},
{
"input": "3 2 3\nejt",
"output": "1\nejt"
},
{
"input": "5 2 4\nzyxwv",
"output": "-1"
},
{
"input": "100 1 1\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "100\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na\na"
},
{
"input": "100 5 4\naaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa",
"output": "25\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa\naaaa"
},
{
"input": "3 2 2\nzyx",
"output": "-1"
},
{
"input": "99 2 2\nhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhhh",
"output": "-1"
},
{
"input": "26 8 9\nabcabcabcabcabcabcabcabcab",
"output": "3\nabcabcab\ncabcabcab\ncabcabcab"
},
{
"input": "6 3 5\naaaaaa",
"output": "2\naaa\naaa"
},
{
"input": "3 2 3\nzyx",
"output": "1\nzyx"
},
{
"input": "5 5 2\naaaaa",
"output": "1\naaaaa"
},
{
"input": "4 3 2\nzyxw",
"output": "2\nzy\nxw"
},
{
"input": "5 4 3\nzyxwv",
"output": "-1"
},
{
"input": "95 3 29\nabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcab",
"output": "23\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabc\nabcabcabcabcabcabcabcabcabcab"
},
{
"input": "3 2 2\naaa",
"output": "-1"
},
{
"input": "91 62 3\nfjzhkfwzoabaauvbkuzaahkozofaophaafhfpuhobufawkzbavaazwavwppfwapkapaofbfjwaavajojgjguahphofj",
"output": "-1"
},
{
"input": "99 2 2\nabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabc",
"output": "-1"
},
{
"input": "56 13 5\nabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcab",
"output": "8\nabcabcabcabca\nbcabcabcabcab\ncabca\nbcabc\nabcab\ncabca\nbcabc\nabcab"
},
{
"input": "79 7 31\nabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabca",
"output": "-1"
},
{
"input": "92 79 6\nxlvplpckwnhmctoethhslkcyashqtsoeltriddglfwtgkfvkvgytygbcyohrvcxvosdioqvackxiuifmkgdngvbbudcb",
"output": "-1"
},
{
"input": "48 16 13\nibhfinipihcbsqnvtgsbkobepmwymlyfmlfgblvhlfhyojsy",
"output": "3\nibhfinipihcbsqnv\ntgsbkobepmwymlyf\nmlfgblvhlfhyojsy"
},
{
"input": "16 3 7\naaaaaaaaaaaaaaaa",
"output": "4\naaa\naaa\naaa\naaaaaaa"
},
{
"input": "11 10 3\naaaaaaaaaaa",
"output": "-1"
},
{
"input": "11 8 8\naaaaaaaaaaa",
"output": "-1"
},
{
"input": "11 7 3\naaaaaaaaaaa",
"output": "-1"
},
{
"input": "41 3 4\nabcabcabcabcabcabcabcabcabcabcabcabcabcab",
"output": "11\nabc\nabc\nabc\nabca\nbcab\ncabc\nabca\nbcab\ncabc\nabca\nbcab"
},
{
"input": "11 3 2\naaaaaaaaaaa",
"output": "5\naaa\naa\naa\naa\naa"
},
{
"input": "14 9 4\nabcdefghijklmn",
"output": "-1"
},
{
"input": "9 9 5\n123456789",
"output": "1\n123456789"
},
{
"input": "92 10 41\nmeotryyfneonmnrvfnhqlehlxtvpracifpadcofecvbikoitrlgeftiqofpvacgocrdiquhatlqosqvtduenaqkwrnnw",
"output": "3\nmeotryyfne\nonmnrvfnhqlehlxtvpracifpadcofecvbikoitrlg\neftiqofpvacgocrdiquhatlqosqvtduenaqkwrnnw"
},
{
"input": "17 16 3\ndxyhgtsxtuyljmclj",
"output": "-1"
},
{
"input": "82 13 30\nfmtwumakkejtolxqxrnydhqoufwtdwldfxcfjrndauqcarhbwmdwxsxfbqjsfspuxobywhcrvlndsdmkqd",
"output": "5\nfmtwumakkejto\nlxqxrnydhqouf\nwtdwldfxcfjrn\ndauqcarhbwmdw\nxsxfbqjsfspuxobywhcrvlndsdmkqd"
},
{
"input": "95 3 3\nihnfqcswushyoirjxlxxnwqtwtaowounkumxukwpacxwatimhhhoggqwkkspcplvyndfukbxickcixidgxkjtnpkoeiwlor",
"output": "-1"
},
{
"input": "7 5 3\nzyxwvut",
"output": "-1"
},
{
"input": "17 16 4\nctvfhkiakagcilrdw",
"output": "-1"
}
] | 1,451,057,511 | 1,910 | Python 3 | WRONG_ANSWER | TESTS | 8 | 46 | 0 | n,p,q = map(int,input().split())
ip=str(input())
if n%(p+q)==0:
k=(n//(p+q))
print(2*k)
for l in range(k):
print(ip[l*p:(l+1)*p])
for m in range(k):
print(ip[(k*p)+(m*q):(k*p)+(m+1)*q])
else:
if n%p!=0 and n%q!=0:
print('-1')
else:
if n%p==0:
print(n//p)
for j in range(n//p):
print(ip[j*p:(j+1)*p])
else:
print(n//q)
for k in range(n//q):
print(ip[k*q:(k+1)*q])
| Title: The Text Splitting
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given the string *s* of length *n* and the numbers *p*,<=*q*. Split the string *s* to pieces of length *p* and *q*.
For example, the string "Hello" for *p*<==<=2, *q*<==<=3 can be split to the two strings "Hel" and "lo" or to the two strings "He" and "llo".
Note it is allowed to split the string *s* to the strings only of length *p* or to the strings only of length *q* (see the second sample test).
Input Specification:
The first line contains three positive integers *n*,<=*p*,<=*q* (1<=≤<=*p*,<=*q*<=≤<=*n*<=≤<=100).
The second line contains the string *s* consists of lowercase and uppercase latin letters and digits.
Output Specification:
If it's impossible to split the string *s* to the strings of length *p* and *q* print the only number "-1".
Otherwise in the first line print integer *k* — the number of strings in partition of *s*.
Each of the next *k* lines should contain the strings in partition. Each string should be of the length *p* or *q*. The string should be in order of their appearing in string *s* — from left to right.
If there are several solutions print any of them.
Demo Input:
['5 2 3\nHello\n', '10 9 5\nCodeforces\n', '6 4 5\nPrivet\n', '8 1 1\nabacabac\n']
Demo Output:
['2\nHe\nllo\n', '2\nCodef\norces\n', '-1\n', '8\na\nb\na\nc\na\nb\na\nc\n']
Note:
none | ```python
n,p,q = map(int,input().split())
ip=str(input())
if n%(p+q)==0:
k=(n//(p+q))
print(2*k)
for l in range(k):
print(ip[l*p:(l+1)*p])
for m in range(k):
print(ip[(k*p)+(m*q):(k*p)+(m+1)*q])
else:
if n%p!=0 and n%q!=0:
print('-1')
else:
if n%p==0:
print(n//p)
for j in range(n//p):
print(ip[j*p:(j+1)*p])
else:
print(n//q)
for k in range(n//q):
print(ip[k*q:(k+1)*q])
``` | 0 | |
490 | A | Team Olympiad | PROGRAMMING | 800 | [
"greedy",
"implementation",
"sortings"
] | null | null | The School №0 of the capital of Berland has *n* children studying in it. All the children in this school are gifted: some of them are good at programming, some are good at maths, others are good at PE (Physical Education). Hence, for each child we know value *t**i*:
- *t**i*<==<=1, if the *i*-th child is good at programming, - *t**i*<==<=2, if the *i*-th child is good at maths, - *t**i*<==<=3, if the *i*-th child is good at PE
Each child happens to be good at exactly one of these three subjects.
The Team Scientific Decathlon Olympias requires teams of three students. The school teachers decided that the teams will be composed of three children that are good at different subjects. That is, each team must have one mathematician, one programmer and one sportsman. Of course, each child can be a member of no more than one team.
What is the maximum number of teams that the school will be able to present at the Olympiad? How should the teams be formed for that? | The first line contains integer *n* (1<=≤<=*n*<=≤<=5000) — the number of children in the school. The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=3), where *t**i* describes the skill of the *i*-th child. | In the first line output integer *w* — the largest possible number of teams.
Then print *w* lines, containing three numbers in each line. Each triple represents the indexes of the children forming the team. You can print both the teams, and the numbers in the triplets in any order. The children are numbered from 1 to *n* in the order of their appearance in the input. Each child must participate in no more than one team. If there are several solutions, print any of them.
If no teams can be compiled, print the only line with value *w* equal to 0. | [
"7\n1 3 1 3 2 1 2\n",
"4\n2 1 1 2\n"
] | [
"2\n3 5 2\n6 7 4\n",
"0\n"
] | none | 500 | [
{
"input": "7\n1 3 1 3 2 1 2",
"output": "2\n3 5 2\n6 7 4"
},
{
"input": "4\n2 1 1 2",
"output": "0"
},
{
"input": "1\n2",
"output": "0"
},
{
"input": "2\n3 1",
"output": "0"
},
{
"input": "3\n2 1 2",
"output": "0"
},
{
"input": "3\n1 2 3",
"output": "1\n1 2 3"
},
{
"input": "12\n3 3 3 3 3 3 3 3 1 3 3 2",
"output": "1\n9 12 2"
},
{
"input": "60\n3 3 1 2 2 1 3 1 1 1 3 2 2 2 3 3 1 3 2 3 2 2 1 3 3 2 3 1 2 2 2 1 3 2 1 1 3 3 1 1 1 3 1 2 1 1 3 3 3 2 3 2 3 2 2 2 1 1 1 2",
"output": "20\n6 60 1\n17 44 20\n3 5 33\n36 21 42\n59 14 2\n58 26 49\n9 29 48\n23 19 24\n10 30 37\n41 54 15\n45 31 27\n57 55 38\n39 12 25\n35 34 11\n32 52 7\n8 50 18\n43 4 53\n46 56 51\n40 22 16\n28 13 47"
},
{
"input": "12\n3 1 1 1 1 1 1 2 1 1 1 1",
"output": "1\n3 8 1"
},
{
"input": "22\n2 2 2 2 2 2 2 2 2 2 3 2 2 2 2 2 2 1 2 2 2 2",
"output": "1\n18 2 11"
},
{
"input": "138\n2 3 2 2 2 2 2 2 2 2 1 2 1 2 2 2 1 2 1 2 2 1 2 2 2 2 2 2 2 2 2 2 2 1 2 3 2 2 2 1 2 3 2 2 2 3 1 3 2 3 2 3 2 2 2 2 3 2 2 2 2 2 1 2 2 3 2 2 3 2 1 2 2 2 2 2 3 1 2 2 2 2 2 3 2 2 3 2 2 2 2 2 1 1 2 3 2 2 2 2 3 2 2 2 2 2 1 2 1 2 2 2 2 2 1 2 3 2 3 2 2 2 1 2 2 2 1 2 2 2 2 1 2 2 2 2 1 3",
"output": "18\n13 91 84\n34 90 48\n11 39 77\n78 129 50\n137 68 119\n132 122 138\n19 12 96\n40 7 2\n22 88 69\n107 73 46\n115 15 52\n127 106 87\n93 92 66\n71 112 117\n63 124 42\n17 70 101\n109 121 57\n123 25 36"
},
{
"input": "203\n2 2 1 2 1 2 2 2 1 2 2 1 1 3 1 2 1 2 1 1 2 3 1 1 2 3 3 2 2 2 1 2 1 1 1 1 1 3 1 1 2 1 1 2 2 2 1 2 2 2 1 2 3 2 1 1 2 2 1 2 1 2 2 1 1 2 2 2 1 1 2 2 1 2 1 2 2 3 2 1 2 1 1 1 1 1 1 1 1 1 1 2 2 1 1 2 2 2 2 1 1 1 1 1 1 1 2 2 2 2 2 1 1 1 2 2 2 1 2 2 1 3 2 1 1 1 2 1 1 2 1 1 2 2 2 1 1 2 2 2 1 2 1 3 2 1 2 2 2 1 1 1 2 2 2 1 2 1 1 2 2 2 2 2 1 1 2 1 2 2 1 1 1 1 1 1 2 2 3 1 1 2 3 1 1 1 1 1 1 2 2 1 1 1 2 2 3 2 1 3 1 1 1",
"output": "13\n188 72 14\n137 4 197\n158 76 122\n152 142 26\n104 119 179\n40 63 38\n12 1 78\n17 30 27\n189 60 53\n166 190 144\n129 7 183\n83 41 22\n121 81 200"
},
{
"input": "220\n1 1 3 1 3 1 1 3 1 3 3 3 3 1 3 3 1 3 3 3 3 3 1 1 1 3 1 1 1 3 2 3 3 3 1 1 3 3 1 1 3 3 3 3 1 3 3 1 1 1 2 3 1 1 1 2 3 3 3 2 3 1 1 3 1 1 1 3 2 1 3 2 3 1 1 3 3 3 1 3 1 1 1 3 3 2 1 3 2 1 1 3 3 1 1 1 2 1 1 3 2 1 2 1 1 1 3 1 3 3 1 2 3 3 3 3 1 3 1 1 1 1 2 3 1 1 1 1 1 1 3 2 3 1 3 1 3 1 1 3 1 3 1 3 1 3 1 3 3 2 3 1 3 3 1 3 3 3 3 1 1 3 3 3 3 1 1 3 3 3 2 1 1 1 3 3 1 3 3 3 1 1 1 3 1 3 3 1 1 1 2 3 1 1 3 1 1 1 1 2 3 1 1 2 3 3 1 3 1 3 3 3 3 1 3 2 3 1 1 3",
"output": "20\n198 89 20\n141 56 131\n166 204 19\n160 132 142\n111 112 195\n45 216 92\n6 31 109\n14 150 170\n199 60 18\n173 123 140\n134 69 156\n82 191 85\n126 200 80\n24 97 46\n62 86 149\n214 101 26\n79 171 78\n125 72 118\n172 103 162\n219 51 64"
},
{
"input": "61\n2 3 1 3 2 2 2 3 1 3 2 3 1 2 1 1 2 2 2 2 3 2 3 1 2 1 3 1 3 2 1 1 3 2 1 3 3 3 1 3 3 1 1 3 1 3 2 2 1 2 2 2 1 3 2 3 1 3 3 1 1",
"output": "20\n9 55 2\n24 34 27\n3 5 37\n35 17 41\n61 11 4\n60 19 54\n15 20 59\n26 14 29\n16 22 38\n43 50 12\n49 25 36\n57 51 40\n39 6 33\n32 30 10\n31 48 8\n13 47 23\n45 1 58\n53 52 56\n42 18 21\n28 7 44"
},
{
"input": "5\n1 2 2 3 3",
"output": "1\n1 3 4"
}
] | 1,693,000,673 | 2,147,483,647 | Python 3 | TIME_LIMIT_EXCEEDED | TESTS | 18 | 1,000 | 0 | n = int(input())
l = list(map(int, input().split()))
p_i, p_n = [], []
for i in range(len(l)):
for j in range(i, len(l)):
if (l[j] not in p_n) and (j+1 not in p_i):
p_i.append(j+1); p_n.append(l[j])
if len(p_n) == 3:
p_n.clear()
break
print(len(p_i)//3)
for i in range(0, len(p_i), 3):
if len(p_i[i:i+3]) == 3:
print(*p_i[i:i+3])
else:
break | Title: Team Olympiad
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The School №0 of the capital of Berland has *n* children studying in it. All the children in this school are gifted: some of them are good at programming, some are good at maths, others are good at PE (Physical Education). Hence, for each child we know value *t**i*:
- *t**i*<==<=1, if the *i*-th child is good at programming, - *t**i*<==<=2, if the *i*-th child is good at maths, - *t**i*<==<=3, if the *i*-th child is good at PE
Each child happens to be good at exactly one of these three subjects.
The Team Scientific Decathlon Olympias requires teams of three students. The school teachers decided that the teams will be composed of three children that are good at different subjects. That is, each team must have one mathematician, one programmer and one sportsman. Of course, each child can be a member of no more than one team.
What is the maximum number of teams that the school will be able to present at the Olympiad? How should the teams be formed for that?
Input Specification:
The first line contains integer *n* (1<=≤<=*n*<=≤<=5000) — the number of children in the school. The second line contains *n* integers *t*1,<=*t*2,<=...,<=*t**n* (1<=≤<=*t**i*<=≤<=3), where *t**i* describes the skill of the *i*-th child.
Output Specification:
In the first line output integer *w* — the largest possible number of teams.
Then print *w* lines, containing three numbers in each line. Each triple represents the indexes of the children forming the team. You can print both the teams, and the numbers in the triplets in any order. The children are numbered from 1 to *n* in the order of their appearance in the input. Each child must participate in no more than one team. If there are several solutions, print any of them.
If no teams can be compiled, print the only line with value *w* equal to 0.
Demo Input:
['7\n1 3 1 3 2 1 2\n', '4\n2 1 1 2\n']
Demo Output:
['2\n3 5 2\n6 7 4\n', '0\n']
Note:
none | ```python
n = int(input())
l = list(map(int, input().split()))
p_i, p_n = [], []
for i in range(len(l)):
for j in range(i, len(l)):
if (l[j] not in p_n) and (j+1 not in p_i):
p_i.append(j+1); p_n.append(l[j])
if len(p_n) == 3:
p_n.clear()
break
print(len(p_i)//3)
for i in range(0, len(p_i), 3):
if len(p_i[i:i+3]) == 3:
print(*p_i[i:i+3])
else:
break
``` | 0 | |
976 | C | Nested Segments | PROGRAMMING | 1,500 | [
"greedy",
"implementation",
"sortings"
] | null | null | You are given a sequence *a*1,<=*a*2,<=...,<=*a**n* of one-dimensional segments numbered 1 through *n*. Your task is to find two distinct indices *i* and *j* such that segment *a**i* lies within segment *a**j*.
Segment [*l*1,<=*r*1] lies within segment [*l*2,<=*r*2] iff *l*1<=≥<=*l*2 and *r*1<=≤<=*r*2.
Print indices *i* and *j*. If there are multiple answers, print any of them. If no answer exists, print -1 -1. | The first line contains one integer *n* (1<=≤<=*n*<=≤<=3·105) — the number of segments.
Each of the next *n* lines contains two integers *l**i* and *r**i* (1<=≤<=*l**i*<=≤<=*r**i*<=≤<=109) — the *i*-th segment. | Print two distinct indices *i* and *j* such that segment *a**i* lies within segment *a**j*. If there are multiple answers, print any of them. If no answer exists, print -1 -1. | [
"5\n1 10\n2 9\n3 9\n2 3\n2 9\n",
"3\n1 5\n2 6\n6 20\n"
] | [
"2 1\n",
"-1 -1\n"
] | In the first example the following pairs are considered correct:
- (2, 1), (3, 1), (4, 1), (5, 1) — not even touching borders; - (3, 2), (4, 2), (3, 5), (4, 5) — touch one border; - (5, 2), (2, 5) — match exactly. | 0 | [
{
"input": "5\n1 10\n2 9\n3 9\n2 3\n2 9",
"output": "2 1"
},
{
"input": "3\n1 5\n2 6\n6 20",
"output": "-1 -1"
},
{
"input": "1\n1 1000000000",
"output": "-1 -1"
},
{
"input": "2\n1 1000000000\n1 1000000000",
"output": "2 1"
},
{
"input": "2\n1 1000000000\n500000000 500000000",
"output": "2 1"
},
{
"input": "2\n1 10\n2 10",
"output": "2 1"
},
{
"input": "2\n10 20\n10 11",
"output": "2 1"
},
{
"input": "3\n1 10\n10 20\n9 11",
"output": "-1 -1"
},
{
"input": "3\n1 1\n2 3\n2 2",
"output": "3 2"
},
{
"input": "4\n1 10\n2 11\n3 10000000\n3 100000000",
"output": "3 4"
},
{
"input": "2\n3 7\n3 9",
"output": "1 2"
},
{
"input": "3\n1 2\n2 3\n1 2",
"output": "3 1"
},
{
"input": "3\n5 6\n4 7\n3 8",
"output": "2 3"
},
{
"input": "3\n2 9\n1 7\n2 8",
"output": "3 1"
},
{
"input": "2\n1 4\n1 5",
"output": "1 2"
},
{
"input": "3\n1 2\n1 3\n4 4",
"output": "1 2"
},
{
"input": "3\n1 2\n1 3\n67 1234567",
"output": "1 2"
},
{
"input": "2\n1 1\n1 1",
"output": "2 1"
},
{
"input": "3\n1 5\n4 7\n3 9",
"output": "2 3"
},
{
"input": "2\n1 1\n1 10",
"output": "1 2"
},
{
"input": "2\n1 2\n1 3",
"output": "1 2"
},
{
"input": "2\n1 10\n1 11",
"output": "1 2"
},
{
"input": "2\n1 1\n1 2",
"output": "1 2"
},
{
"input": "2\n2 3\n2 4",
"output": "1 2"
},
{
"input": "2\n1 3\n3 3",
"output": "2 1"
},
{
"input": "3\n1 10\n11 13\n12 12",
"output": "3 2"
},
{
"input": "2\n2 10\n1 10",
"output": "1 2"
},
{
"input": "3\n1 3\n4 5\n4 4",
"output": "3 2"
},
{
"input": "5\n1 1\n2 6\n3 5\n10 15\n20 25",
"output": "3 2"
},
{
"input": "3\n1 1000\n1001 1007\n1002 1007",
"output": "3 2"
},
{
"input": "3\n1 3\n2 5\n3 4",
"output": "3 2"
},
{
"input": "3\n1 10\n2 11\n3 11",
"output": "3 2"
},
{
"input": "2\n2000000 999999999\n1000000 1000000000",
"output": "1 2"
},
{
"input": "3\n2 10\n11 12\n4 5",
"output": "3 1"
},
{
"input": "2\n1 10\n1 19",
"output": "1 2"
},
{
"input": "4\n1 3\n100 102\n108 110\n1 3",
"output": "4 1"
},
{
"input": "3\n1 3\n5 9\n5 6",
"output": "3 2"
},
{
"input": "3\n1 3\n3 4\n3 5",
"output": "2 3"
},
{
"input": "3\n1 2\n1 3\n1 4",
"output": "2 3"
},
{
"input": "4\n2 3\n1 4\n100 200\n1000 2000",
"output": "1 2"
},
{
"input": "3\n1 1\n2 100\n3 99",
"output": "3 2"
},
{
"input": "3\n1 2\n1 3\n12 1234",
"output": "1 2"
},
{
"input": "3\n1 4\n2 6\n3 5",
"output": "3 2"
},
{
"input": "3\n1 10\n2 12\n1 9",
"output": "3 1"
},
{
"input": "2\n1 3\n1 5",
"output": "1 2"
},
{
"input": "3\n1 2\n2 5\n2 3",
"output": "3 2"
},
{
"input": "4\n1 3\n1 4\n5 10\n11 13",
"output": "1 2"
},
{
"input": "4\n7 15\n6 9\n9 10\n10 11",
"output": "3 1"
},
{
"input": "4\n2 3\n100 200\n1000 2000\n1 4",
"output": "1 4"
},
{
"input": "3\n10 20\n5 9\n11 19",
"output": "3 1"
},
{
"input": "10\n1 2\n2 3\n3 4\n4 5\n5 6\n6 6\n6 7\n7 8\n8 9\n9 10",
"output": "6 7"
},
{
"input": "2\n1 4\n1 7",
"output": "1 2"
},
{
"input": "3\n1 11\n2 12\n2 13",
"output": "2 3"
},
{
"input": "2\n1 4\n1 8",
"output": "1 2"
},
{
"input": "2\n2 5\n1 5",
"output": "1 2"
},
{
"input": "2\n2 9\n1 10",
"output": "1 2"
},
{
"input": "3\n2 4\n2 4\n1 3",
"output": "2 1"
},
{
"input": "6\n10 11\n12 13\n15 16\n15 17\n18 19\n59 60",
"output": "3 4"
},
{
"input": "2\n1 3\n1 7",
"output": "1 2"
},
{
"input": "5\n4 6\n7 60\n80 90\n4 5\n8 80",
"output": "4 1"
},
{
"input": "2\n1 3\n1 4",
"output": "1 2"
},
{
"input": "3\n2 9\n1 7\n2 9",
"output": "3 1"
},
{
"input": "2\n1 4\n1 6",
"output": "1 2"
},
{
"input": "3\n4 4\n2 3\n4 5",
"output": "1 3"
},
{
"input": "2\n1 5\n1 7",
"output": "1 2"
},
{
"input": "2\n1 2\n1 4",
"output": "1 2"
},
{
"input": "4\n1 1\n2 2\n5 10\n2 4",
"output": "2 4"
},
{
"input": "3\n11 12\n11 15\n43 45",
"output": "1 2"
},
{
"input": "3\n2 3\n2 4\n2 5",
"output": "2 3"
},
{
"input": "2\n2 3\n2 5",
"output": "1 2"
},
{
"input": "3\n1 3\n1 4\n1 5",
"output": "2 3"
},
{
"input": "3\n1 1\n1 2\n1 3",
"output": "2 3"
},
{
"input": "2\n2 3\n1 3",
"output": "1 2"
},
{
"input": "11\n22226 28285\n9095 23314\n19162 25530\n255 13298\n4904 25801\n17914 23501\n8441 28117\n11880 29994\n11123 19874\n21505 27971\n7658 14109",
"output": "11 5"
},
{
"input": "8\n4 11\n5 12\n6 13\n7 14\n8 15\n9 16\n10 17\n1 11",
"output": "1 8"
},
{
"input": "4\n1 10\n12 15\n1 3\n17 18",
"output": "3 1"
},
{
"input": "3\n1 5\n1 10\n1 20",
"output": "2 3"
},
{
"input": "3\n1 1000\n1001 1003\n1 1",
"output": "3 1"
},
{
"input": "3\n1 10\n2 11\n2 11",
"output": "3 2"
},
{
"input": "2\n1 1\n1 3",
"output": "1 2"
},
{
"input": "2\n1 5\n1 6",
"output": "1 2"
},
{
"input": "3\n1 5\n3 6\n1 4",
"output": "3 1"
},
{
"input": "4\n2 8\n1 3\n2 9\n1 2",
"output": "4 2"
},
{
"input": "3\n3 6\n1 3\n3 9",
"output": "1 3"
},
{
"input": "6\n2 40\n5 50\n10 60\n3 45\n1 40\n100 111",
"output": "1 5"
},
{
"input": "4\n1 2\n4 4\n3 3\n2 3",
"output": "3 4"
},
{
"input": "4\n1 1\n4 5\n7 9\n1 1",
"output": "4 1"
},
{
"input": "6\n30 35\n18 29\n28 32\n4 9\n1002 129212\n8 281",
"output": "2 6"
},
{
"input": "2\n10 13\n10 14",
"output": "1 2"
},
{
"input": "5\n2 4\n3 6\n4 5\n222 333\n111 444",
"output": "3 2"
},
{
"input": "3\n1 2\n4 5\n1 1",
"output": "3 1"
},
{
"input": "2\n2 100\n1 100",
"output": "1 2"
},
{
"input": "3\n1 10\n9 20\n3 5",
"output": "3 1"
},
{
"input": "2\n1 9\n1 10",
"output": "1 2"
},
{
"input": "3\n1 2\n1 4\n1 6",
"output": "2 3"
}
] | 1,544,943,420 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 6 | 108 | 0 | n=int(input())
m=a=0
d=[list(map(int,input().split()))for _ in' '*n]
s=sorted(range(n),key=lambda x:d[x])
for i in s:
y=d[i][1]
if y<=m:print(i+1,a+1);exit(0)
else:m=y;a=i
print(-1,-1) | Title: Nested Segments
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You are given a sequence *a*1,<=*a*2,<=...,<=*a**n* of one-dimensional segments numbered 1 through *n*. Your task is to find two distinct indices *i* and *j* such that segment *a**i* lies within segment *a**j*.
Segment [*l*1,<=*r*1] lies within segment [*l*2,<=*r*2] iff *l*1<=≥<=*l*2 and *r*1<=≤<=*r*2.
Print indices *i* and *j*. If there are multiple answers, print any of them. If no answer exists, print -1 -1.
Input Specification:
The first line contains one integer *n* (1<=≤<=*n*<=≤<=3·105) — the number of segments.
Each of the next *n* lines contains two integers *l**i* and *r**i* (1<=≤<=*l**i*<=≤<=*r**i*<=≤<=109) — the *i*-th segment.
Output Specification:
Print two distinct indices *i* and *j* such that segment *a**i* lies within segment *a**j*. If there are multiple answers, print any of them. If no answer exists, print -1 -1.
Demo Input:
['5\n1 10\n2 9\n3 9\n2 3\n2 9\n', '3\n1 5\n2 6\n6 20\n']
Demo Output:
['2 1\n', '-1 -1\n']
Note:
In the first example the following pairs are considered correct:
- (2, 1), (3, 1), (4, 1), (5, 1) — not even touching borders; - (3, 2), (4, 2), (3, 5), (4, 5) — touch one border; - (5, 2), (2, 5) — match exactly. | ```python
n=int(input())
m=a=0
d=[list(map(int,input().split()))for _ in' '*n]
s=sorted(range(n),key=lambda x:d[x])
for i in s:
y=d[i][1]
if y<=m:print(i+1,a+1);exit(0)
else:m=y;a=i
print(-1,-1)
``` | 0 | |
796 | A | Buying A House | PROGRAMMING | 800 | [
"brute force",
"implementation"
] | null | null | Zane the wizard had never loved anyone before, until he fell in love with a girl, whose name remains unknown to us.
The girl lives in house *m* of a village. There are *n* houses in that village, lining in a straight line from left to right: house 1, house 2, ..., house *n*. The village is also well-structured: house *i* and house *i*<=+<=1 (1<=≤<=*i*<=<<=*n*) are exactly 10 meters away. In this village, some houses are occupied, and some are not. Indeed, unoccupied houses can be purchased.
You will be given *n* integers *a*1,<=*a*2,<=...,<=*a**n* that denote the availability and the prices of the houses. If house *i* is occupied, and therefore cannot be bought, then *a**i* equals 0. Otherwise, house *i* can be bought, and *a**i* represents the money required to buy it, in dollars.
As Zane has only *k* dollars to spare, it becomes a challenge for him to choose the house to purchase, so that he could live as near as possible to his crush. Help Zane determine the minimum distance from his crush's house to some house he can afford, to help him succeed in his love. | The first line contains three integers *n*, *m*, and *k* (2<=≤<=*n*<=≤<=100, 1<=≤<=*m*<=≤<=*n*, 1<=≤<=*k*<=≤<=100) — the number of houses in the village, the house where the girl lives, and the amount of money Zane has (in dollars), respectively.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=100) — denoting the availability and the prices of the houses.
It is guaranteed that *a**m*<==<=0 and that it is possible to purchase some house with no more than *k* dollars. | Print one integer — the minimum distance, in meters, from the house where the girl Zane likes lives to the house Zane can buy. | [
"5 1 20\n0 27 32 21 19\n",
"7 3 50\n62 0 0 0 99 33 22\n",
"10 5 100\n1 0 1 0 0 0 0 0 1 1\n"
] | [
"40",
"30",
"20"
] | In the first sample, with *k* = 20 dollars, Zane can buy only house 5. The distance from house *m* = 1 to house 5 is 10 + 10 + 10 + 10 = 40 meters.
In the second sample, Zane can buy houses 6 and 7. It is better to buy house 6 than house 7, since house *m* = 3 and house 6 are only 30 meters away, while house *m* = 3 and house 7 are 40 meters away. | 500 | [
{
"input": "5 1 20\n0 27 32 21 19",
"output": "40"
},
{
"input": "7 3 50\n62 0 0 0 99 33 22",
"output": "30"
},
{
"input": "10 5 100\n1 0 1 0 0 0 0 0 1 1",
"output": "20"
},
{
"input": "5 3 1\n1 1 0 0 1",
"output": "10"
},
{
"input": "5 5 5\n1 0 5 6 0",
"output": "20"
},
{
"input": "15 10 50\n20 0 49 50 50 50 50 50 50 0 50 50 49 0 20",
"output": "10"
},
{
"input": "7 5 1\n0 100 2 2 0 2 1",
"output": "20"
},
{
"input": "100 50 100\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 0 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": "10"
},
{
"input": "100 50 1\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 0 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": "490"
},
{
"input": "100 77 50\n50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 0 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0 50 100 49 51 0",
"output": "10"
},
{
"input": "100 1 1\n0 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 0",
"output": "980"
},
{
"input": "100 1 100\n0 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100",
"output": "10"
},
{
"input": "100 10 99\n0 0 0 0 0 0 0 0 0 0 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 100 99 98",
"output": "890"
},
{
"input": "7 4 5\n1 0 6 0 5 6 0",
"output": "10"
},
{
"input": "7 4 5\n1 6 5 0 0 6 0",
"output": "10"
},
{
"input": "100 42 59\n50 50 50 50 50 50 50 50 50 50 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 59 60 60 60 60 60 60 60 60 0 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 60 0",
"output": "90"
},
{
"input": "2 1 100\n0 1",
"output": "10"
},
{
"input": "2 2 100\n1 0",
"output": "10"
},
{
"input": "10 1 88\n0 95 0 0 0 0 0 94 0 85",
"output": "90"
},
{
"input": "10 2 14\n2 0 1 26 77 39 41 100 13 32",
"output": "10"
},
{
"input": "10 3 11\n0 0 0 0 0 62 0 52 1 35",
"output": "60"
},
{
"input": "20 12 44\n27 40 58 69 53 38 31 39 75 95 8 0 28 81 77 90 38 61 21 88",
"output": "10"
},
{
"input": "30 29 10\n59 79 34 12 100 6 1 58 18 73 54 11 37 46 89 90 80 85 73 45 64 5 31 0 89 19 0 74 0 82",
"output": "70"
},
{
"input": "40 22 1\n7 95 44 53 0 0 19 93 0 68 65 0 24 91 10 58 17 0 71 0 100 0 94 90 79 73 0 73 4 61 54 81 7 13 21 84 5 41 0 1",
"output": "180"
},
{
"input": "40 22 99\n60 0 100 0 0 100 100 0 0 0 0 100 100 0 0 100 100 0 100 100 100 0 100 100 100 0 100 100 0 0 100 100 100 0 0 100 0 100 0 0",
"output": "210"
},
{
"input": "50 10 82\n56 54 0 0 0 0 88 93 0 0 83 93 0 0 91 89 0 30 62 52 24 84 80 8 38 13 92 78 16 87 23 30 71 55 16 63 15 99 4 93 24 6 3 35 4 42 73 27 86 37",
"output": "80"
},
{
"input": "63 49 22\n18 3 97 52 75 2 12 24 58 75 80 97 22 10 79 51 30 60 68 99 75 2 35 3 97 88 9 7 18 5 0 0 0 91 0 91 56 36 76 0 0 0 52 27 35 0 51 72 0 96 57 0 0 0 0 92 55 28 0 30 0 78 77",
"output": "190"
},
{
"input": "74 38 51\n53 36 55 42 64 5 87 9 0 16 86 78 9 22 19 1 25 72 1 0 0 0 79 0 0 0 77 58 70 0 0 100 64 0 99 59 0 0 0 0 65 74 0 96 0 58 89 93 61 88 0 0 82 89 0 0 49 24 7 77 89 87 94 61 100 31 93 70 39 49 39 14 20 84",
"output": "190"
},
{
"input": "89 22 11\n36 0 68 89 0 85 72 0 38 56 0 44 0 94 0 28 71 0 0 18 0 0 0 89 0 0 0 75 0 0 0 32 66 0 0 0 0 0 0 48 63 0 64 58 0 23 48 0 0 52 93 61 57 0 18 0 0 34 62 17 0 41 0 0 53 59 44 0 0 51 40 0 0 100 100 54 0 88 0 5 45 56 57 67 24 16 88 86 15",
"output": "580"
},
{
"input": "97 44 100\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 51 19",
"output": "520"
},
{
"input": "100 1 1\n0 0 0 0 10 54 84 6 17 94 65 82 34 0 61 46 42 0 2 16 56 0 100 0 82 0 0 0 89 78 96 56 0 0 0 0 0 0 0 0 77 70 0 96 67 0 0 32 44 1 72 50 14 11 24 61 100 64 19 5 67 69 44 82 93 22 67 93 22 61 53 64 79 41 84 48 43 97 7 24 8 49 23 16 72 52 97 29 69 47 29 49 64 91 4 73 17 18 51 67",
"output": "490"
},
{
"input": "100 1 50\n0 0 0 60 0 0 54 0 80 0 0 0 97 0 68 97 84 0 0 93 0 0 0 0 68 0 0 62 0 0 55 68 65 87 0 69 0 0 0 0 0 52 61 100 0 71 0 82 88 78 0 81 0 95 0 57 0 67 0 0 0 55 86 0 60 72 0 0 73 0 83 0 0 60 64 0 56 0 0 77 84 0 58 63 84 0 0 67 0 16 3 88 0 98 31 52 40 35 85 23",
"output": "890"
},
{
"input": "100 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 91 70 14",
"output": "970"
},
{
"input": "100 1 29\n0 0 0 0 64 0 89 97 0 0 0 59 0 67 62 0 59 0 0 80 0 0 0 0 0 97 0 57 0 64 32 0 44 0 0 48 0 47 38 0 42 0 0 0 0 0 0 46 74 0 86 33 33 0 44 0 79 0 0 0 0 91 59 0 59 65 55 0 0 58 33 95 0 97 76 0 81 0 41 0 38 81 80 0 85 0 31 0 0 92 0 0 45 96 0 85 91 87 0 10",
"output": "990"
},
{
"input": "100 50 20\n3 0 32 0 48 32 64 0 54 26 0 0 0 0 0 28 0 0 54 0 0 45 49 0 38 74 0 0 39 42 62 48 75 96 89 42 0 44 0 0 30 21 76 0 50 0 79 0 0 0 0 99 0 84 62 0 0 0 0 53 80 0 28 0 0 53 0 0 38 0 62 0 0 62 0 0 88 0 44 32 0 81 35 45 49 0 69 73 38 27 72 0 96 72 69 0 0 22 76 10",
"output": "490"
},
{
"input": "100 50 20\n49 0 56 0 87 25 40 0 50 0 0 97 0 0 36 29 0 0 0 0 0 73 29 71 44 0 0 0 91 92 69 0 0 60 81 49 48 38 0 87 0 82 0 32 0 82 46 39 0 0 29 0 0 29 0 79 47 0 0 0 0 0 49 0 24 33 70 0 63 45 97 90 0 0 29 53 55 0 84 0 0 100 26 0 88 0 0 0 0 81 70 0 30 80 0 75 59 98 0 2",
"output": "500"
},
{
"input": "100 2 2\n0 0 43 90 47 5 2 97 52 69 21 48 64 10 34 97 97 74 8 19 68 56 55 24 47 38 43 73 72 72 60 60 51 36 33 44 100 45 13 54 72 52 0 15 3 6 50 8 88 4 78 26 40 27 30 63 67 83 61 91 33 97 54 20 92 27 89 35 10 7 84 50 11 95 74 88 24 44 74 100 18 56 34 91 41 34 51 51 11 91 89 54 19 100 83 89 10 17 76 20",
"output": "50"
},
{
"input": "100 100 34\n5 73 0 0 44 0 0 0 79 55 0 0 0 0 0 0 0 0 83 67 75 0 0 0 0 59 0 74 0 0 47 98 0 0 72 41 0 55 87 0 0 78 84 0 0 39 0 79 72 95 0 0 0 0 0 85 53 84 0 0 0 0 37 75 0 66 0 0 0 0 61 0 70 0 37 60 42 78 92 52 0 0 0 55 77 57 0 63 37 0 0 0 96 70 0 94 97 0 0 0",
"output": "990"
},
{
"input": "100 100 100\n43 79 21 87 84 14 28 69 92 16 3 71 79 37 48 37 72 58 12 72 62 49 37 17 60 54 41 99 15 72 40 89 76 1 99 87 14 56 63 48 69 37 96 64 7 14 1 73 85 33 98 70 97 71 96 28 49 71 56 2 67 22 100 2 98 100 62 77 92 76 98 98 47 26 22 47 50 56 9 16 72 47 5 62 29 78 81 1 0 63 32 65 87 3 40 53 8 80 93 0",
"output": "10"
},
{
"input": "100 38 1\n3 59 12 81 33 95 0 41 36 17 63 76 42 77 85 56 3 96 55 41 24 87 18 9 0 37 0 61 69 0 0 0 67 0 0 0 0 0 0 18 0 0 47 56 74 0 0 80 0 42 0 1 60 59 62 9 19 87 92 48 58 30 98 51 99 10 42 94 51 53 50 89 24 5 52 82 50 39 98 8 95 4 57 21 10 0 44 32 19 14 64 34 79 76 17 3 15 22 71 51",
"output": "140"
},
{
"input": "100 72 1\n56 98 8 27 9 23 16 76 56 1 34 43 96 73 75 49 62 20 18 23 51 55 30 84 4 20 89 40 75 16 69 35 1 0 16 0 80 0 41 17 0 0 76 23 0 92 0 34 0 91 82 54 0 0 0 63 85 59 98 24 29 0 8 77 26 0 34 95 39 0 0 0 74 0 0 0 0 12 0 92 0 0 55 95 66 30 0 0 29 98 0 0 0 47 0 0 80 0 0 4",
"output": "390"
},
{
"input": "100 66 1\n38 50 64 91 37 44 74 21 14 41 80 90 26 51 78 85 80 86 44 14 49 75 93 48 78 89 23 72 35 22 14 48 100 71 62 22 7 95 80 66 32 20 17 47 79 30 41 52 15 62 67 71 1 6 0 9 0 0 0 11 0 0 24 0 31 0 77 0 51 0 0 0 0 0 0 77 0 36 44 19 90 45 6 25 100 87 93 30 4 97 36 88 33 50 26 71 97 71 51 68",
"output": "130"
},
{
"input": "100 55 1\n0 33 45 83 56 96 58 24 45 30 38 60 39 69 21 87 59 21 72 73 27 46 61 61 11 97 77 5 39 3 3 35 76 37 53 84 24 75 9 48 31 90 100 84 74 81 83 83 42 23 29 94 18 1 0 53 52 99 86 37 94 54 28 75 28 80 17 14 98 68 76 20 32 23 42 31 57 79 60 14 18 27 1 98 32 3 96 25 15 38 2 6 3 28 59 54 63 2 43 59",
"output": "10"
},
{
"input": "100 55 1\n24 52 41 6 55 11 58 25 63 12 70 39 23 28 72 17 96 85 7 84 21 13 34 37 97 43 36 32 15 30 58 5 14 71 40 70 9 92 44 73 31 58 96 90 19 35 29 91 25 36 48 95 61 78 0 1 99 61 81 88 42 53 61 57 42 55 74 45 41 92 99 30 20 25 89 50 37 4 17 24 6 65 15 44 40 2 38 43 7 90 38 59 75 87 96 28 12 67 24 32",
"output": "10"
},
{
"input": "100 21 1\n62 5 97 80 81 28 83 0 26 0 0 0 0 23 0 0 90 0 0 0 0 0 0 0 0 54 71 8 0 0 42 0 73 0 17 0 1 31 71 78 58 72 84 39 54 59 13 29 16 41 71 35 88 55 70 50 33 100 100 60 52 90 7 66 44 55 51 42 90 17 86 44 46 8 52 74 8 22 2 92 34 37 58 98 70 74 19 91 74 25 4 38 71 68 50 68 63 14 60 98",
"output": "160"
},
{
"input": "5 2 20\n27 0 32 21 19",
"output": "30"
},
{
"input": "6 4 10\n10 0 0 0 0 10",
"output": "20"
},
{
"input": "8 7 100\n1 0 0 0 0 0 0 1",
"output": "10"
},
{
"input": "5 3 20\n1 21 0 0 1",
"output": "20"
},
{
"input": "4 3 1\n0 0 0 1",
"output": "10"
},
{
"input": "5 2 3\n4 0 5 6 1",
"output": "30"
},
{
"input": "5 3 87\n88 89 0 1 90",
"output": "10"
},
{
"input": "5 3 20\n15 30 0 15 35",
"output": "10"
},
{
"input": "6 3 50\n0 0 0 1 2 0",
"output": "10"
},
{
"input": "6 4 9\n100 9 10 0 0 9",
"output": "20"
},
{
"input": "5 4 20\n0 20 0 0 20",
"output": "10"
},
{
"input": "6 3 3\n1 5 0 2 2 0",
"output": "10"
},
{
"input": "5 4 100\n0 1 0 0 1",
"output": "10"
}
] | 1,588,019,371 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 3 | 124 | 0 | n,m,k = map(int,input().split())
a = list(map(int,input().split()))
# print(n,m,k)
op1,op2 = 101,101
for i in range(m,n):
# print(i)
if a[i] < k and a[i]!=0:
op1 = i
break
# print()
for i in range(0,m-1):
# print(i)
if a[i] < k and a[i]!=0:
op2 = i
print(abs(min(op1,op2)-(m-1))*10)
| Title: Buying A House
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Zane the wizard had never loved anyone before, until he fell in love with a girl, whose name remains unknown to us.
The girl lives in house *m* of a village. There are *n* houses in that village, lining in a straight line from left to right: house 1, house 2, ..., house *n*. The village is also well-structured: house *i* and house *i*<=+<=1 (1<=≤<=*i*<=<<=*n*) are exactly 10 meters away. In this village, some houses are occupied, and some are not. Indeed, unoccupied houses can be purchased.
You will be given *n* integers *a*1,<=*a*2,<=...,<=*a**n* that denote the availability and the prices of the houses. If house *i* is occupied, and therefore cannot be bought, then *a**i* equals 0. Otherwise, house *i* can be bought, and *a**i* represents the money required to buy it, in dollars.
As Zane has only *k* dollars to spare, it becomes a challenge for him to choose the house to purchase, so that he could live as near as possible to his crush. Help Zane determine the minimum distance from his crush's house to some house he can afford, to help him succeed in his love.
Input Specification:
The first line contains three integers *n*, *m*, and *k* (2<=≤<=*n*<=≤<=100, 1<=≤<=*m*<=≤<=*n*, 1<=≤<=*k*<=≤<=100) — the number of houses in the village, the house where the girl lives, and the amount of money Zane has (in dollars), respectively.
The second line contains *n* integers *a*1,<=*a*2,<=...,<=*a**n* (0<=≤<=*a**i*<=≤<=100) — denoting the availability and the prices of the houses.
It is guaranteed that *a**m*<==<=0 and that it is possible to purchase some house with no more than *k* dollars.
Output Specification:
Print one integer — the minimum distance, in meters, from the house where the girl Zane likes lives to the house Zane can buy.
Demo Input:
['5 1 20\n0 27 32 21 19\n', '7 3 50\n62 0 0 0 99 33 22\n', '10 5 100\n1 0 1 0 0 0 0 0 1 1\n']
Demo Output:
['40', '30', '20']
Note:
In the first sample, with *k* = 20 dollars, Zane can buy only house 5. The distance from house *m* = 1 to house 5 is 10 + 10 + 10 + 10 = 40 meters.
In the second sample, Zane can buy houses 6 and 7. It is better to buy house 6 than house 7, since house *m* = 3 and house 6 are only 30 meters away, while house *m* = 3 and house 7 are 40 meters away. | ```python
n,m,k = map(int,input().split())
a = list(map(int,input().split()))
# print(n,m,k)
op1,op2 = 101,101
for i in range(m,n):
# print(i)
if a[i] < k and a[i]!=0:
op1 = i
break
# print()
for i in range(0,m-1):
# print(i)
if a[i] < k and a[i]!=0:
op2 = i
print(abs(min(op1,op2)-(m-1))*10)
``` | 0 | |
441 | B | Valera and Fruits | PROGRAMMING | 1,400 | [
"greedy",
"implementation"
] | null | null | Valera loves his garden, where *n* fruit trees grow.
This year he will enjoy a great harvest! On the *i*-th tree *b**i* fruit grow, they will ripen on a day number *a**i*. Unfortunately, the fruit on the tree get withered, so they can only be collected on day *a**i* and day *a**i*<=+<=1 (all fruits that are not collected in these two days, become unfit to eat).
Valera is not very fast, but there are some positive points. Valera is ready to work every day. In one day, Valera can collect no more than *v* fruits. The fruits may be either from the same tree, or from different ones. What is the maximum amount of fruit Valera can collect for all time, if he operates optimally well? | The first line contains two space-separated integers *n* and *v* (1<=≤<=*n*,<=*v*<=≤<=3000) — the number of fruit trees in the garden and the number of fruits that Valera can collect in a day.
Next *n* lines contain the description of trees in the garden. The *i*-th line contains two space-separated integers *a**i* and *b**i* (1<=≤<=*a**i*,<=*b**i*<=≤<=3000) — the day the fruits ripen on the *i*-th tree and the number of fruits on the *i*-th tree. | Print a single integer — the maximum number of fruit that Valera can collect. | [
"2 3\n1 5\n2 3\n",
"5 10\n3 20\n2 20\n1 20\n4 20\n5 20\n"
] | [
"8\n",
"60\n"
] | In the first sample, in order to obtain the optimal answer, you should act as follows.
- On the first day collect 3 fruits from the 1-st tree. - On the second day collect 1 fruit from the 2-nd tree and 2 fruits from the 1-st tree. - On the third day collect the remaining fruits from the 2-nd tree.
In the second sample, you can only collect 60 fruits, the remaining fruit will simply wither. | 1,000 | [
{
"input": "2 3\n1 5\n2 3",
"output": "8"
},
{
"input": "5 10\n3 20\n2 20\n1 20\n4 20\n5 20",
"output": "60"
},
{
"input": "10 3000\n1 2522\n4 445\n8 1629\n5 772\n9 2497\n6 81\n3 426\n7 1447\n2 575\n10 202",
"output": "10596"
},
{
"input": "5 3000\n5 772\n1 2522\n2 575\n4 445\n3 426",
"output": "4740"
},
{
"input": "2 1500\n2 575\n1 2522",
"output": "3097"
},
{
"input": "12 2856\n9 2728\n8 417\n3 1857\n10 1932\n1 775\n12 982\n9 1447\n1 426\n7 2918\n11 2522\n10 2497\n9 772",
"output": "18465"
},
{
"input": "24 1524\n16 934\n23 1940\n21 1447\n20 417\n24 1340\n22 1932\n13 775\n19 2918\n12 2355\n9 593\n11 2676\n3 1857\n16 868\n13 426\n18 1679\n22 991\n9 2728\n10 2497\n16 1221\n9 772\n23 2522\n24 982\n12 1431\n18 757",
"output": "25893"
},
{
"input": "1 10\n3000 30",
"output": "20"
},
{
"input": "2 1\n30 3\n31 2",
"output": "3"
},
{
"input": "4 2061\n1 426\n3 2522\n1 772\n1 1447",
"output": "5167"
},
{
"input": "2 1\n1 1\n1 1",
"output": "2"
},
{
"input": "1 10\n3000 20",
"output": "20"
},
{
"input": "1 1000\n3000 2000",
"output": "2000"
},
{
"input": "2 100\n3000 100\n3000 100",
"output": "200"
},
{
"input": "2 3\n1 6\n3 6",
"output": "12"
},
{
"input": "1 40\n3000 42",
"output": "42"
},
{
"input": "1 100\n3000 200",
"output": "200"
},
{
"input": "1 50\n3000 100",
"output": "100"
},
{
"input": "1 1\n3000 2",
"output": "2"
},
{
"input": "2 3000\n3000 3000\n3000 3000",
"output": "6000"
},
{
"input": "2 2\n2999 3\n3000 2",
"output": "5"
},
{
"input": "1 2\n3000 3",
"output": "3"
},
{
"input": "2 5\n2999 10\n3000 5",
"output": "15"
},
{
"input": "1 3\n5 3",
"output": "3"
},
{
"input": "2 1000\n2999 2000\n3000 1000",
"output": "3000"
},
{
"input": "1 5\n3000 10",
"output": "10"
},
{
"input": "1 10\n3000 15",
"output": "15"
},
{
"input": "5 1\n10 100\n2698 100\n200 100\n3000 100\n1500 100",
"output": "10"
},
{
"input": "1 1\n3000 3000",
"output": "2"
},
{
"input": "2 10\n2999 100\n3000 100",
"output": "30"
},
{
"input": "1 10\n3000 100",
"output": "20"
}
] | 1,508,612,015 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 1 | 78 | 23,244,800 | from collections import defaultdict
def main():
MAX = 3002
(n, v) = map(int, input().split(' '))
m = defaultdict(list)
for i in range(n):
(ai, bi) = map(int, input().split(' '))
m[ai].append(bi)
a = [[] for i in range(MAX)]
for i in range(0, MAX):
if i in m:
a[i] = m[i]
else:
a[i] = [0]
r = 0
l = 0
for i in range(1, 5):
xs = []
vv = v
for ai in a[i]:
y = 0
if l > 0 and vv > 0:
y = min(vv, l)
r += y
vv -= y
l -= y
x = min(vv, ai)
vv -= x
r += x
if ai - x > 0:
xs.append(ai - x)
#print(i, x, y, r, xs)
l = 0
for x in xs:
if x > 0:
l += x
return r
print(main())
| Title: Valera and Fruits
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Valera loves his garden, where *n* fruit trees grow.
This year he will enjoy a great harvest! On the *i*-th tree *b**i* fruit grow, they will ripen on a day number *a**i*. Unfortunately, the fruit on the tree get withered, so they can only be collected on day *a**i* and day *a**i*<=+<=1 (all fruits that are not collected in these two days, become unfit to eat).
Valera is not very fast, but there are some positive points. Valera is ready to work every day. In one day, Valera can collect no more than *v* fruits. The fruits may be either from the same tree, or from different ones. What is the maximum amount of fruit Valera can collect for all time, if he operates optimally well?
Input Specification:
The first line contains two space-separated integers *n* and *v* (1<=≤<=*n*,<=*v*<=≤<=3000) — the number of fruit trees in the garden and the number of fruits that Valera can collect in a day.
Next *n* lines contain the description of trees in the garden. The *i*-th line contains two space-separated integers *a**i* and *b**i* (1<=≤<=*a**i*,<=*b**i*<=≤<=3000) — the day the fruits ripen on the *i*-th tree and the number of fruits on the *i*-th tree.
Output Specification:
Print a single integer — the maximum number of fruit that Valera can collect.
Demo Input:
['2 3\n1 5\n2 3\n', '5 10\n3 20\n2 20\n1 20\n4 20\n5 20\n']
Demo Output:
['8\n', '60\n']
Note:
In the first sample, in order to obtain the optimal answer, you should act as follows.
- On the first day collect 3 fruits from the 1-st tree. - On the second day collect 1 fruit from the 2-nd tree and 2 fruits from the 1-st tree. - On the third day collect the remaining fruits from the 2-nd tree.
In the second sample, you can only collect 60 fruits, the remaining fruit will simply wither. | ```python
from collections import defaultdict
def main():
MAX = 3002
(n, v) = map(int, input().split(' '))
m = defaultdict(list)
for i in range(n):
(ai, bi) = map(int, input().split(' '))
m[ai].append(bi)
a = [[] for i in range(MAX)]
for i in range(0, MAX):
if i in m:
a[i] = m[i]
else:
a[i] = [0]
r = 0
l = 0
for i in range(1, 5):
xs = []
vv = v
for ai in a[i]:
y = 0
if l > 0 and vv > 0:
y = min(vv, l)
r += y
vv -= y
l -= y
x = min(vv, ai)
vv -= x
r += x
if ai - x > 0:
xs.append(ai - x)
#print(i, x, y, r, xs)
l = 0
for x in xs:
if x > 0:
l += x
return r
print(main())
``` | 0 | |
985 | C | Liebig's Barrels | PROGRAMMING | 1,500 | [
"greedy"
] | null | null | You have *m*<==<=*n*·*k* wooden staves. The *i*-th stave has length *a**i*. You have to assemble *n* barrels consisting of *k* staves each, you can use any *k* staves to construct a barrel. Each stave must belong to exactly one barrel.
Let volume *v**j* of barrel *j* be equal to the length of the minimal stave in it.
You want to assemble exactly *n* barrels with the maximal total sum of volumes. But you have to make them equal enough, so a difference between volumes of any pair of the resulting barrels must not exceed *l*, i.e. |*v**x*<=-<=*v**y*|<=≤<=*l* for any 1<=≤<=*x*<=≤<=*n* and 1<=≤<=*y*<=≤<=*n*.
Print maximal total sum of volumes of equal enough barrels or 0 if it's impossible to satisfy the condition above. | The first line contains three space-separated integers *n*, *k* and *l* (1<=≤<=*n*,<=*k*<=≤<=105, 1<=≤<=*n*·*k*<=≤<=105, 0<=≤<=*l*<=≤<=109).
The second line contains *m*<==<=*n*·*k* space-separated integers *a*1,<=*a*2,<=...,<=*a**m* (1<=≤<=*a**i*<=≤<=109) — lengths of staves. | Print single integer — maximal total sum of the volumes of barrels or 0 if it's impossible to construct exactly *n* barrels satisfying the condition |*v**x*<=-<=*v**y*|<=≤<=*l* for any 1<=≤<=*x*<=≤<=*n* and 1<=≤<=*y*<=≤<=*n*. | [
"4 2 1\n2 2 1 2 3 2 2 3\n",
"2 1 0\n10 10\n",
"1 2 1\n5 2\n",
"3 2 1\n1 2 3 4 5 6\n"
] | [
"7\n",
"20\n",
"2\n",
"0\n"
] | In the first example you can form the following barrels: [1, 2], [2, 2], [2, 3], [2, 3].
In the second example you can form the following barrels: [10], [10].
In the third example you can form the following barrels: [2, 5].
In the fourth example difference between volumes of barrels in any partition is at least 2 so it is impossible to make barrels equal enough. | 0 | [
{
"input": "4 2 1\n2 2 1 2 3 2 2 3",
"output": "7"
},
{
"input": "2 1 0\n10 10",
"output": "20"
},
{
"input": "1 2 1\n5 2",
"output": "2"
},
{
"input": "3 2 1\n1 2 3 4 5 6",
"output": "0"
},
{
"input": "10 3 189\n267 697 667 4 52 128 85 616 142 344 413 660 962 194 618 329 266 593 558 447 89 983 964 716 32 890 267 164 654 71",
"output": "0"
},
{
"input": "10 3 453\n277 706 727 812 692 686 196 507 911 40 498 704 573 381 463 759 704 381 693 640 326 405 47 834 962 521 463 740 520 494",
"output": "2979"
},
{
"input": "10 3 795\n398 962 417 307 760 534 536 450 421 280 608 111 687 726 941 903 630 900 555 403 795 122 814 188 234 976 679 539 525 104",
"output": "5045"
},
{
"input": "6 2 29\n1 2 3 3 4 5 5 6 7 7 8 9",
"output": "28"
},
{
"input": "2 1 2\n1 2",
"output": "3"
}
] | 1,593,182,823 | 2,147,483,647 | PyPy 3 | WRONG_ANSWER | TESTS | 6 | 218 | 30,924,800 | """ 616C """
""" 1152B """
import math
# import sys
def main():
# n ,m= map(int,input().split())
# arr = list(map(int,input().split()))
# b = list(map(int,input().split()))
# n = int(input())
# string = str(input())
n ,k,l = map(int,input().split())
a = list(map(int,input().split()))
a.sort()
index = -1
for i in range(n-1,-1,-1):
if((a[i]-a[0])<=l):
index = i
break
if((index+1)<n):
print(0)
return
extra = index+1 - n
start = 0
ans = 0
while start<=index:
ans += a[start]
start += min(extra,k-1)+1
extra -= min(extra,k-1)
if extra<0:
extra = 0
print(ans)
return
main()
# def test():
# t = int(input())
# while t:
# main()
# t-=1
# test()
| Title: Liebig's Barrels
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
You have *m*<==<=*n*·*k* wooden staves. The *i*-th stave has length *a**i*. You have to assemble *n* barrels consisting of *k* staves each, you can use any *k* staves to construct a barrel. Each stave must belong to exactly one barrel.
Let volume *v**j* of barrel *j* be equal to the length of the minimal stave in it.
You want to assemble exactly *n* barrels with the maximal total sum of volumes. But you have to make them equal enough, so a difference between volumes of any pair of the resulting barrels must not exceed *l*, i.e. |*v**x*<=-<=*v**y*|<=≤<=*l* for any 1<=≤<=*x*<=≤<=*n* and 1<=≤<=*y*<=≤<=*n*.
Print maximal total sum of volumes of equal enough barrels or 0 if it's impossible to satisfy the condition above.
Input Specification:
The first line contains three space-separated integers *n*, *k* and *l* (1<=≤<=*n*,<=*k*<=≤<=105, 1<=≤<=*n*·*k*<=≤<=105, 0<=≤<=*l*<=≤<=109).
The second line contains *m*<==<=*n*·*k* space-separated integers *a*1,<=*a*2,<=...,<=*a**m* (1<=≤<=*a**i*<=≤<=109) — lengths of staves.
Output Specification:
Print single integer — maximal total sum of the volumes of barrels or 0 if it's impossible to construct exactly *n* barrels satisfying the condition |*v**x*<=-<=*v**y*|<=≤<=*l* for any 1<=≤<=*x*<=≤<=*n* and 1<=≤<=*y*<=≤<=*n*.
Demo Input:
['4 2 1\n2 2 1 2 3 2 2 3\n', '2 1 0\n10 10\n', '1 2 1\n5 2\n', '3 2 1\n1 2 3 4 5 6\n']
Demo Output:
['7\n', '20\n', '2\n', '0\n']
Note:
In the first example you can form the following barrels: [1, 2], [2, 2], [2, 3], [2, 3].
In the second example you can form the following barrels: [10], [10].
In the third example you can form the following barrels: [2, 5].
In the fourth example difference between volumes of barrels in any partition is at least 2 so it is impossible to make barrels equal enough. | ```python
""" 616C """
""" 1152B """
import math
# import sys
def main():
# n ,m= map(int,input().split())
# arr = list(map(int,input().split()))
# b = list(map(int,input().split()))
# n = int(input())
# string = str(input())
n ,k,l = map(int,input().split())
a = list(map(int,input().split()))
a.sort()
index = -1
for i in range(n-1,-1,-1):
if((a[i]-a[0])<=l):
index = i
break
if((index+1)<n):
print(0)
return
extra = index+1 - n
start = 0
ans = 0
while start<=index:
ans += a[start]
start += min(extra,k-1)+1
extra -= min(extra,k-1)
if extra<0:
extra = 0
print(ans)
return
main()
# def test():
# t = int(input())
# while t:
# main()
# t-=1
# test()
``` | 0 | |
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"
}
] | 1,641,993,237 | 2,147,483,647 | Python 3 | OK | TESTS | 40 | 92 | 0 | t=input()
s=input()
c=0
z=-1
for a in range(len(t)):
if t[a]==s[z] :
c+=1
z-=1
else:
c+=0
print(["NO","YES"][c==len(t)]) | 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
t=input()
s=input()
c=0
z=-1
for a in range(len(t)):
if t[a]==s[z] :
c+=1
z-=1
else:
c+=0
print(["NO","YES"][c==len(t)])
``` | 3.977 |
1,000 | B | Light It Up | PROGRAMMING | 1,500 | [
"greedy"
] | null | null | Recently, you bought a brand new smart lamp with programming features. At first, you set up a schedule to the lamp. Every day it will turn power on at moment $0$ and turn power off at moment $M$. Moreover, the lamp allows you to set a program of switching its state (states are "lights on" and "lights off"). Unfortunately, some program is already installed into the lamp.
The lamp allows only good programs. Good program can be represented as a non-empty array $a$, where $0 < a_1 < a_2 < \dots < a_{|a|} < M$. All $a_i$ must be integers. Of course, preinstalled program is a good program.
The lamp follows program $a$ in next manner: at moment $0$ turns power and light on. Then at moment $a_i$ the lamp flips its state to opposite (if it was lit, it turns off, and vice versa). The state of the lamp flips instantly: for example, if you turn the light off at moment $1$ and then do nothing, the total time when the lamp is lit will be $1$. Finally, at moment $M$ the lamp is turning its power off regardless of its state.
Since you are not among those people who read instructions, and you don't understand the language it's written in, you realize (after some testing) the only possible way to alter the preinstalled program. You can insert at most one element into the program $a$, so it still should be a good program after alteration. Insertion can be done between any pair of consecutive elements of $a$, or even at the begining or at the end of $a$.
Find such a way to alter the program that the total time when the lamp is lit is maximum possible. Maybe you should leave program untouched. If the lamp is lit from $x$ till moment $y$, then its lit for $y - x$ units of time. Segments of time when the lamp is lit are summed up. | First line contains two space separated integers $n$ and $M$ ($1 \le n \le 10^5$, $2 \le M \le 10^9$) — the length of program $a$ and the moment when power turns off.
Second line contains $n$ space separated integers $a_1, a_2, \dots, a_n$ ($0 < a_1 < a_2 < \dots < a_n < M$) — initially installed program $a$. | Print the only integer — maximum possible total time when the lamp is lit. | [
"3 10\n4 6 7\n",
"2 12\n1 10\n",
"2 7\n3 4\n"
] | [
"8\n",
"9\n",
"6\n"
] | In the first example, one of possible optimal solutions is to insert value $x = 3$ before $a_1$, so program will be $[3, 4, 6, 7]$ and time of lamp being lit equals $(3 - 0) + (6 - 4) + (10 - 7) = 8$. Other possible solution is to insert $x = 5$ in appropriate place.
In the second example, there is only one optimal solution: to insert $x = 2$ between $a_1$ and $a_2$. Program will become $[1, 2, 10]$, and answer will be $(1 - 0) + (10 - 2) = 9$.
In the third example, optimal answer is to leave program untouched, so answer will be $(3 - 0) + (7 - 4) = 6$. | 0 | [
{
"input": "3 10\n4 6 7",
"output": "8"
},
{
"input": "2 12\n1 10",
"output": "9"
},
{
"input": "2 7\n3 4",
"output": "6"
},
{
"input": "1 2\n1",
"output": "1"
},
{
"input": "5 10\n1 3 5 6 8",
"output": "6"
},
{
"input": "7 1000000000\n1 10001 10011 20011 20021 40021 40031",
"output": "999999969"
},
{
"input": "7 1000000000\n3 10001 10011 20011 20021 40021 40031",
"output": "999999969"
},
{
"input": "1 10\n1",
"output": "9"
},
{
"input": "1 10000000\n1",
"output": "9999999"
},
{
"input": "1 8\n1",
"output": "7"
},
{
"input": "7 17\n1 5 9 10 11 14 16",
"output": "9"
},
{
"input": "4 17\n1 5 9 10",
"output": "12"
},
{
"input": "5 12\n1 2 3 4 5",
"output": "9"
},
{
"input": "2 1000000000\n100 111",
"output": "999999989"
},
{
"input": "3 90591\n90579 90580 90581",
"output": "90589"
},
{
"input": "5 16\n1 2 3 4 5",
"output": "13"
},
{
"input": "6 981231233\n1 6 15 30 130 1875",
"output": "981229468"
},
{
"input": "1 3\n1",
"output": "2"
},
{
"input": "3 12\n4 7 11",
"output": "8"
},
{
"input": "1 100000\n1",
"output": "99999"
},
{
"input": "2 5\n1 3",
"output": "3"
},
{
"input": "1 1000000000\n1",
"output": "999999999"
},
{
"input": "1 1000000000\n999999999",
"output": "999999999"
},
{
"input": "3 4\n1 2 3",
"output": "2"
},
{
"input": "3 5\n1 2 3",
"output": "3"
},
{
"input": "1 4\n2",
"output": "3"
},
{
"input": "3 5\n1 3 4",
"output": "3"
},
{
"input": "9 20\n5 9 11 12 14 15 16 17 19",
"output": "12"
},
{
"input": "2 4\n1 2",
"output": "3"
},
{
"input": "1 10\n2",
"output": "9"
},
{
"input": "2 6\n2 4",
"output": "4"
},
{
"input": "2 4\n1 3",
"output": "2"
},
{
"input": "3 6\n1 2 4",
"output": "4"
},
{
"input": "7 9863\n65 96 97 98 101 112 1115",
"output": "9819"
}
] | 1,635,844,386 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 8 | 93 | 12,595,200 | n,m = map(int,input().split())
l = [0]+list(map(int,input().split()))+[m]
a=b=0
for i in range(1,len(l),2):
a+=l[i]-l[i-1]
for i in range(2,len(l),2):
b+=l[i-1]-l[i-2]
if l[i]-l[i-1]>1:
a=max(m-l[i-1]-1-(a-b)+b,a)
print(a) | Title: Light It Up
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Recently, you bought a brand new smart lamp with programming features. At first, you set up a schedule to the lamp. Every day it will turn power on at moment $0$ and turn power off at moment $M$. Moreover, the lamp allows you to set a program of switching its state (states are "lights on" and "lights off"). Unfortunately, some program is already installed into the lamp.
The lamp allows only good programs. Good program can be represented as a non-empty array $a$, where $0 < a_1 < a_2 < \dots < a_{|a|} < M$. All $a_i$ must be integers. Of course, preinstalled program is a good program.
The lamp follows program $a$ in next manner: at moment $0$ turns power and light on. Then at moment $a_i$ the lamp flips its state to opposite (if it was lit, it turns off, and vice versa). The state of the lamp flips instantly: for example, if you turn the light off at moment $1$ and then do nothing, the total time when the lamp is lit will be $1$. Finally, at moment $M$ the lamp is turning its power off regardless of its state.
Since you are not among those people who read instructions, and you don't understand the language it's written in, you realize (after some testing) the only possible way to alter the preinstalled program. You can insert at most one element into the program $a$, so it still should be a good program after alteration. Insertion can be done between any pair of consecutive elements of $a$, or even at the begining or at the end of $a$.
Find such a way to alter the program that the total time when the lamp is lit is maximum possible. Maybe you should leave program untouched. If the lamp is lit from $x$ till moment $y$, then its lit for $y - x$ units of time. Segments of time when the lamp is lit are summed up.
Input Specification:
First line contains two space separated integers $n$ and $M$ ($1 \le n \le 10^5$, $2 \le M \le 10^9$) — the length of program $a$ and the moment when power turns off.
Second line contains $n$ space separated integers $a_1, a_2, \dots, a_n$ ($0 < a_1 < a_2 < \dots < a_n < M$) — initially installed program $a$.
Output Specification:
Print the only integer — maximum possible total time when the lamp is lit.
Demo Input:
['3 10\n4 6 7\n', '2 12\n1 10\n', '2 7\n3 4\n']
Demo Output:
['8\n', '9\n', '6\n']
Note:
In the first example, one of possible optimal solutions is to insert value $x = 3$ before $a_1$, so program will be $[3, 4, 6, 7]$ and time of lamp being lit equals $(3 - 0) + (6 - 4) + (10 - 7) = 8$. Other possible solution is to insert $x = 5$ in appropriate place.
In the second example, there is only one optimal solution: to insert $x = 2$ between $a_1$ and $a_2$. Program will become $[1, 2, 10]$, and answer will be $(1 - 0) + (10 - 2) = 9$.
In the third example, optimal answer is to leave program untouched, so answer will be $(3 - 0) + (7 - 4) = 6$. | ```python
n,m = map(int,input().split())
l = [0]+list(map(int,input().split()))+[m]
a=b=0
for i in range(1,len(l),2):
a+=l[i]-l[i-1]
for i in range(2,len(l),2):
b+=l[i-1]-l[i-2]
if l[i]-l[i-1]>1:
a=max(m-l[i-1]-1-(a-b)+b,a)
print(a)
``` | 0 | |
582 | A | GCD Table | PROGRAMMING | 1,700 | [
"constructive algorithms",
"greedy",
"number theory"
] | null | null | The GCD table *G* of size *n*<=×<=*n* for an array of positive integers *a* of length *n* is defined by formula
Let us remind you that the greatest common divisor (GCD) of two positive integers *x* and *y* is the greatest integer that is divisor of both *x* and *y*, it is denoted as . For example, for array *a*<==<={4,<=3,<=6,<=2} of length 4 the GCD table will look as follows:
Given all the numbers of the GCD table *G*, restore array *a*. | The first line contains number *n* (1<=≤<=*n*<=≤<=500) — the length of array *a*. The second line contains *n*2 space-separated numbers — the elements of the GCD table of *G* for array *a*.
All the numbers in the table are positive integers, not exceeding 109. Note that the elements are given in an arbitrary order. It is guaranteed that the set of the input data corresponds to some array *a*. | In the single line print *n* positive integers — the elements of array *a*. If there are multiple possible solutions, you are allowed to print any of them. | [
"4\n2 1 2 3 4 3 2 6 1 1 2 2 1 2 3 2\n",
"1\n42\n",
"2\n1 1 1 1\n"
] | [
"4 3 6 2",
"42 ",
"1 1 "
] | none | 750 | [
{
"input": "4\n2 1 2 3 4 3 2 6 1 1 2 2 1 2 3 2",
"output": "2 3 4 6 "
},
{
"input": "1\n42",
"output": "42 "
},
{
"input": "2\n1 1 1 1",
"output": "1 1 "
},
{
"input": "2\n54748096 1 641009859 1",
"output": "54748096 641009859 "
},
{
"input": "3\n1 7 923264237 374288891 7 524125987 1 1 1",
"output": "374288891 524125987 923264237 "
},
{
"input": "4\n1 1 1 1 1 702209411 496813081 673102149 1 1 561219907 1 1 1 1 1",
"output": "496813081 561219907 673102149 702209411 "
},
{
"input": "5\n1 1 1 1 1 9 564718673 585325539 1 1 3 1 9 1 1 365329221 3 291882089 3 1 412106895 1 1 1 3",
"output": "291882089 365329221 412106895 564718673 585325539 "
},
{
"input": "5\n1 161 1 534447872 161 233427865 1 7 7 73701396 1 401939237 4 1 1 1 1 1 7 115704211 1 4 1 7 1",
"output": "73701396 115704211 233427865 401939237 534447872 "
},
{
"input": "5\n2 11 1 1 2 4 2 1 181951 4 345484316 2 4 4 4 2 1 140772746 1 634524 4 521302304 1 2 11",
"output": "181951 634524 140772746 345484316 521302304 "
},
{
"input": "5\n27 675 1 1 347621274 5 2 13 189 738040275 5 1 189 13 1 959752125 770516962 769220855 5 5 2 675 1 1 27",
"output": "347621274 738040275 769220855 770516962 959752125 "
},
{
"input": "5\n2029 6087 2029 2029 6087 2029 527243766 4058 2029 2029 2029 2029 2029 2029 2029 2029 165353355 4058 2029 731472761 739767313 2029 2029 2029 585281282",
"output": "165353355 527243766 585281282 731472761 739767313 "
},
{
"input": "5\n537163 537163 537163 537163 537163 537163 1074326 537163 537163 537163 515139317 1074326 537163 537163 537163 539311652 321760637 170817834 537163 537163 537163 537163 537163 537163 392666153",
"output": "170817834 321760637 392666153 515139317 539311652 "
},
{
"input": "4\n1 188110 607844 2 1 1 695147 1 1 1 143380513 1 1 1 1 2",
"output": "188110 607844 695147 143380513 "
},
{
"input": "4\n3 1 96256522 120 360284388 3 3 2 2 2 3 12 12 2 1 198192381",
"output": "120 96256522 198192381 360284388 "
},
{
"input": "4\n67025 13405 1915 1915 1915 1915 5745 676469920 53620 5745 660330300 67025 53620 380098775 533084295 13405",
"output": "380098775 533084295 660330300 676469920 "
},
{
"input": "4\n700521 233507 759364764 467014 468181535 233507 233507 890362191 233507 700521 467014 233507 946637378 233507 233507 233507",
"output": "468181535 759364764 890362191 946637378 "
},
{
"input": "3\n484799 1 1 744137 1 1 909312183 1 1",
"output": "484799 744137 909312183 "
},
{
"input": "3\n1 716963379 1 1 205 1 1 964 1",
"output": "205 964 716963379 "
},
{
"input": "3\n5993 781145599 54740062 5993 5993 267030101 5993 5993 5993",
"output": "54740062 267030101 781145599 "
},
{
"input": "3\n121339 121339 121339 55451923 531222142 121339 121339 435485671 121339",
"output": "55451923 435485671 531222142 "
},
{
"input": "5\n4 4 4 4 4 4 4 4 4 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1",
"output": "1 2 4 4 4 "
},
{
"input": "4\n1 1 1 1 1 1 1 1 1 1 1 1 3 3 3 3",
"output": "1 1 3 3 "
},
{
"input": "6\n1 1 1 1 1 1 1 1 1 1 1 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 6 6 6 6 6 6 6 6 6",
"output": "1 3 3 6 6 6 "
}
] | 1,444,214,581 | 2,147,483,647 | Python 3 | COMPILATION_ERROR | TESTS | 0 | 0 | 0 | def gcd(a,b):
while b: a,b=b,a%b
return a
n=int(input())
l=list(map(int,input().split()))
m={}
ans=[]
for x in l: m[x]=m.get(x,0)+1
for x in sorted(m.keys())[::-1]:
if m[x]==0: continue
for y in ans: m[]t=min((m[x]//2)*2,k)
m[gcd(x,y)]-=2
ans+=[x]
print(' '.join(map(str,ans))) | Title: GCD Table
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
The GCD table *G* of size *n*<=×<=*n* for an array of positive integers *a* of length *n* is defined by formula
Let us remind you that the greatest common divisor (GCD) of two positive integers *x* and *y* is the greatest integer that is divisor of both *x* and *y*, it is denoted as . For example, for array *a*<==<={4,<=3,<=6,<=2} of length 4 the GCD table will look as follows:
Given all the numbers of the GCD table *G*, restore array *a*.
Input Specification:
The first line contains number *n* (1<=≤<=*n*<=≤<=500) — the length of array *a*. The second line contains *n*2 space-separated numbers — the elements of the GCD table of *G* for array *a*.
All the numbers in the table are positive integers, not exceeding 109. Note that the elements are given in an arbitrary order. It is guaranteed that the set of the input data corresponds to some array *a*.
Output Specification:
In the single line print *n* positive integers — the elements of array *a*. If there are multiple possible solutions, you are allowed to print any of them.
Demo Input:
['4\n2 1 2 3 4 3 2 6 1 1 2 2 1 2 3 2\n', '1\n42\n', '2\n1 1 1 1\n']
Demo Output:
['4 3 6 2', '42 ', '1 1 ']
Note:
none | ```python
def gcd(a,b):
while b: a,b=b,a%b
return a
n=int(input())
l=list(map(int,input().split()))
m={}
ans=[]
for x in l: m[x]=m.get(x,0)+1
for x in sorted(m.keys())[::-1]:
if m[x]==0: continue
for y in ans: m[]t=min((m[x]//2)*2,k)
m[gcd(x,y)]-=2
ans+=[x]
print(' '.join(map(str,ans)))
``` | -1 | |
834 | A | The Useless Toy | PROGRAMMING | 900 | [
"implementation"
] | null | null | Walking through the streets of Marshmallow City, Slastyona have spotted some merchants selling a kind of useless toy which is very popular nowadays – caramel spinner! Wanting to join the craze, she has immediately bought the strange contraption.
Spinners in Sweetland have the form of V-shaped pieces of caramel. Each spinner can, well, spin around an invisible magic axis. At a specific point in time, a spinner can take 4 positions shown below (each one rotated 90 degrees relative to the previous, with the fourth one followed by the first one):
After the spinner was spun, it starts its rotation, which is described by a following algorithm: the spinner maintains its position for a second then majestically switches to the next position in clockwise or counter-clockwise order, depending on the direction the spinner was spun in.
Slastyona managed to have spinner rotating for exactly *n* seconds. Being fascinated by elegance of the process, she completely forgot the direction the spinner was spun in! Lucky for her, she managed to recall the starting position, and wants to deduct the direction given the information she knows. Help her do this. | There are two characters in the first string – the starting and the ending position of a spinner. The position is encoded with one of the following characters: v (ASCII code 118, lowercase v), < (ASCII code 60), ^ (ASCII code 94) or > (ASCII code 62) (see the picture above for reference). Characters are separated by a single space.
In the second strings, a single number *n* is given (0<=≤<=*n*<=≤<=109) – the duration of the rotation.
It is guaranteed that the ending position of a spinner is a result of a *n* second spin in any of the directions, assuming the given starting position. | Output cw, if the direction is clockwise, ccw – if counter-clockwise, and undefined otherwise. | [
"^ >\n1\n",
"< ^\n3\n",
"^ v\n6\n"
] | [
"cw\n",
"ccw\n",
"undefined\n"
] | none | 500 | [
{
"input": "^ >\n1",
"output": "cw"
},
{
"input": "< ^\n3",
"output": "ccw"
},
{
"input": "^ v\n6",
"output": "undefined"
},
{
"input": "^ >\n999999999",
"output": "ccw"
},
{
"input": "> v\n1",
"output": "cw"
},
{
"input": "v <\n1",
"output": "cw"
},
{
"input": "< ^\n1",
"output": "cw"
},
{
"input": "v <\n422435957",
"output": "cw"
},
{
"input": "v >\n139018901",
"output": "ccw"
},
{
"input": "v ^\n571728018",
"output": "undefined"
},
{
"input": "^ ^\n0",
"output": "undefined"
},
{
"input": "< >\n2",
"output": "undefined"
},
{
"input": "> >\n1000000000",
"output": "undefined"
},
{
"input": "v v\n8",
"output": "undefined"
},
{
"input": "< <\n1568",
"output": "undefined"
},
{
"input": "^ v\n2",
"output": "undefined"
},
{
"input": "^ <\n1",
"output": "ccw"
},
{
"input": "< v\n1",
"output": "ccw"
},
{
"input": "v >\n1",
"output": "ccw"
},
{
"input": "> ^\n1",
"output": "ccw"
},
{
"input": "v <\n422435957",
"output": "cw"
},
{
"input": "v v\n927162384",
"output": "undefined"
},
{
"input": "v ^\n571728018",
"output": "undefined"
},
{
"input": "^ <\n467441155",
"output": "cw"
},
{
"input": "^ >\n822875521",
"output": "cw"
},
{
"input": "^ <\n821690113",
"output": "ccw"
},
{
"input": "^ <\n171288453",
"output": "ccw"
},
{
"input": "^ <\n110821381",
"output": "ccw"
},
{
"input": "^ ^\n539580280",
"output": "undefined"
},
{
"input": "^ >\n861895563",
"output": "ccw"
},
{
"input": "v v\n4",
"output": "undefined"
},
{
"input": "^ ^\n4",
"output": "undefined"
},
{
"input": "> >\n4",
"output": "undefined"
},
{
"input": "< <\n8",
"output": "undefined"
},
{
"input": "v v\n0",
"output": "undefined"
},
{
"input": "^ <\n11",
"output": "cw"
},
{
"input": "< <\n4",
"output": "undefined"
},
{
"input": "< <\n0",
"output": "undefined"
},
{
"input": "< v\n3",
"output": "cw"
},
{
"input": "^ <\n3",
"output": "cw"
},
{
"input": "^ <\n7",
"output": "cw"
},
{
"input": "< >\n6",
"output": "undefined"
},
{
"input": "v >\n3",
"output": "cw"
},
{
"input": "> >\n300",
"output": "undefined"
},
{
"input": "> >\n0",
"output": "undefined"
},
{
"input": "v <\n3",
"output": "ccw"
},
{
"input": "> >\n12",
"output": "undefined"
}
] | 1,653,060,010 | 2,147,483,647 | Python 3 | WRONG_ANSWER | TESTS | 4 | 46 | 0 | arr = ["^" , ">" , "v" , "<"]
a,b = input().split()
n = int(input())%4
x,y = arr.index(a),arr.index(b)
if n% 2 == 0:print('undefined')
else:
if arr[n] == b and x < y:print('cw')
else:print('ccw') | Title: The Useless Toy
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Walking through the streets of Marshmallow City, Slastyona have spotted some merchants selling a kind of useless toy which is very popular nowadays – caramel spinner! Wanting to join the craze, she has immediately bought the strange contraption.
Spinners in Sweetland have the form of V-shaped pieces of caramel. Each spinner can, well, spin around an invisible magic axis. At a specific point in time, a spinner can take 4 positions shown below (each one rotated 90 degrees relative to the previous, with the fourth one followed by the first one):
After the spinner was spun, it starts its rotation, which is described by a following algorithm: the spinner maintains its position for a second then majestically switches to the next position in clockwise or counter-clockwise order, depending on the direction the spinner was spun in.
Slastyona managed to have spinner rotating for exactly *n* seconds. Being fascinated by elegance of the process, she completely forgot the direction the spinner was spun in! Lucky for her, she managed to recall the starting position, and wants to deduct the direction given the information she knows. Help her do this.
Input Specification:
There are two characters in the first string – the starting and the ending position of a spinner. The position is encoded with one of the following characters: v (ASCII code 118, lowercase v), < (ASCII code 60), ^ (ASCII code 94) or > (ASCII code 62) (see the picture above for reference). Characters are separated by a single space.
In the second strings, a single number *n* is given (0<=≤<=*n*<=≤<=109) – the duration of the rotation.
It is guaranteed that the ending position of a spinner is a result of a *n* second spin in any of the directions, assuming the given starting position.
Output Specification:
Output cw, if the direction is clockwise, ccw – if counter-clockwise, and undefined otherwise.
Demo Input:
['^ >\n1\n', '< ^\n3\n', '^ v\n6\n']
Demo Output:
['cw\n', 'ccw\n', 'undefined\n']
Note:
none | ```python
arr = ["^" , ">" , "v" , "<"]
a,b = input().split()
n = int(input())%4
x,y = arr.index(a),arr.index(b)
if n% 2 == 0:print('undefined')
else:
if arr[n] == b and x < y:print('cw')
else:print('ccw')
``` | 0 | |
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"
}
] | 1,661,510,988 | 2,147,483,647 | PyPy 3-64 | OK | TESTS | 81 | 124 | 0 | # Young Physicist
n = int(input())
codordinates = []
for i in range(n):
x,y,z = map(int,input().split())
codordinates.append((x,y,z))
x = 0
y = 0
z = 0
for i in codordinates:
x += i[0]
y += i[1]
z += i[2]
if x==0 and y==0 and 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
# Young Physicist
n = int(input())
codordinates = []
for i in range(n):
x,y,z = map(int,input().split())
codordinates.append((x,y,z))
x = 0
y = 0
z = 0
for i in codordinates:
x += i[0]
y += i[1]
z += i[2]
if x==0 and y==0 and z==0:
print("YES")
else:
print("NO")
``` | 3.969 |
145 | B | Lucky Number 2 | PROGRAMMING | 1,800 | [
"constructive algorithms"
] | null | null | Petya loves lucky numbers very much. Everybody knows that lucky numbers are positive integers whose decimal record contains only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Petya loves long lucky numbers very much. He is interested in the minimum lucky number *d* that meets some condition. Let *cnt*(*x*) be the number of occurrences of number *x* in number *d* as a substring. For example, if *d*<==<=747747, then *cnt*(4)<==<=2, *cnt*(7)<==<=4, *cnt*(47)<==<=2, *cnt*(74)<==<=2. Petya wants the following condition to fulfil simultaneously: *cnt*(4)<==<=*a*1, *cnt*(7)<==<=*a*2, *cnt*(47)<==<=*a*3, *cnt*(74)<==<=*a*4. Petya is not interested in the occurrences of other numbers. Help him cope with this task. | The single line contains four integers *a*1, *a*2, *a*3 and *a*4 (1<=≤<=*a*1,<=*a*2,<=*a*3,<=*a*4<=≤<=106). | On the single line print without leading zeroes the answer to the problem — the minimum lucky number *d* such, that *cnt*(4)<==<=*a*1, *cnt*(7)<==<=*a*2, *cnt*(47)<==<=*a*3, *cnt*(74)<==<=*a*4. If such number does not exist, print the single number "-1" (without the quotes). | [
"2 2 1 1\n",
"4 7 3 1\n"
] | [
"4774\n",
"-1\n"
] | none | 1,000 | [
{
"input": "2 2 1 1",
"output": "4774"
},
{
"input": "4 7 3 1",
"output": "-1"
},
{
"input": "4 7 4 7",
"output": "-1"
},
{
"input": "1 1 1 1",
"output": "-1"
},
{
"input": "2 2 1 2",
"output": "7474"
},
{
"input": "2 1 2 1",
"output": "-1"
},
{
"input": "2 2 2 1",
"output": "4747"
},
{
"input": "3 3 1 1",
"output": "447774"
},
{
"input": "3 2 1 2",
"output": "74474"
},
{
"input": "2 1 3 1",
"output": "-1"
},
{
"input": "7 7 1 1",
"output": "44444477777774"
},
{
"input": "4 7 2 1",
"output": "44474777777"
},
{
"input": "3 3 2 2",
"output": "474774"
},
{
"input": "4 3 2 1",
"output": "4447477"
},
{
"input": "4 4 2 2",
"output": "44747774"
},
{
"input": "1000000 1000000 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "10 10 3 5",
"output": "-1"
},
{
"input": "10 10 3 7",
"output": "-1"
},
{
"input": "1 7 1 1",
"output": "74777777"
},
{
"input": "8 3 2 1",
"output": "44444447477"
},
{
"input": "1000000 1000000 1000000 1000000",
"output": "-1"
},
{
"input": "4584 45854 25 685",
"output": "-1"
},
{
"input": "1 1 1 2",
"output": "-1"
},
{
"input": "3 1000000 3 1",
"output": "-1"
},
{
"input": "4 58458 2 1",
"output": "4447477777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "845 8549 54 8",
"output": "-1"
},
{
"input": "1000000 1000000 100000 100000",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 499 500",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 100000 100001",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "845488 44884 9945 9944",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "7 7 4 5",
"output": "74447474747774"
},
{
"input": "7 8 5 4",
"output": "444747474747777"
},
{
"input": "1000000 1000000 400000 400001",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "4585 4588 98 99",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 2 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "2 100000 1 2",
"output": "7477777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "86451 754 85 84",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "98654 4844 1001 1000",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "5 5 1 2",
"output": "7444477774"
},
{
"input": "5 5 2 1",
"output": "4444747777"
},
{
"input": "4 4 1 1",
"output": "44477774"
},
{
"input": "4 4 2 2",
"output": "44747774"
},
{
"input": "4 4 3 3",
"output": "47474774"
},
{
"input": "10 9 4 5",
"output": "7444444747474777774"
},
{
"input": "100 100 4 5",
"output": "74444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444447474747777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777774"
},
{
"input": "1000000 1000000 1 2",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 47 46",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 999999 1000000",
"output": "7474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747..."
},
{
"input": "54585 4584 458 954",
"output": "-1"
},
{
"input": "6 6 1 3",
"output": "-1"
},
{
"input": "6 6 2 3",
"output": "744447477774"
},
{
"input": "6 10 2 1",
"output": "4444474777777777"
},
{
"input": "7 3 1 1",
"output": "4444447774"
},
{
"input": "47 74 8 9",
"output": "7444444444444444444444444444444444444444747474747474747777777777777777777777777777777777777777777777777777777777777777774"
},
{
"input": "458445 445 6 7",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 10000 10001",
"output": "7444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "1000000 1000000 978 977",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "7 1000 1 2",
"output": "7444444777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "1 10 1 1",
"output": "74777777777"
},
{
"input": "70 60 20 21",
"output": "7444444444444444444444444444444444444444444444444447474747474747474747474747474747474747477777777777777777777777777777777777777774"
},
{
"input": "57 59 3 4",
"output": "74444444444444444444444444444444444444444444444444444447474777777777777777777777777777777777777777777777777777777774"
},
{
"input": "10 10 5 5",
"output": "44444747474747777774"
},
{
"input": "69 84 25 24",
"output": "444444444444444444444444444444444444444444444747474747474747474747474747474747474747474747474777777777777777777777777777777777777777777777777777777777777"
},
{
"input": "25 94 11 12",
"output": "74444444444444474747474747474747474777777777777777777777777777777777777777777777777777777777777777777777777777777777774"
},
{
"input": "1 1000000 4 5",
"output": "-1"
},
{
"input": "7 1000000 2 3",
"output": "7444447477777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "1000000 1 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "45 65 31 32",
"output": "74444444444444474747474747474747474747474747474747474747474747474747474747477777777777777777777777777777777774"
},
{
"input": "31 32 30 31",
"output": "747474747474747474747474747474747474747474747474747474747474774"
},
{
"input": "1 1000000 1 1",
"output": "7477777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "2 1000000 1 1",
"output": "4777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777..."
},
{
"input": "50000 1000000 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "74544 1 1 1",
"output": "4444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444..."
},
{
"input": "2 2 3 4",
"output": "-1"
},
{
"input": "1 1000 2 1",
"output": "-1"
},
{
"input": "1 10 1 2",
"output": "-1"
},
{
"input": "1000000 1000000 1000000 999999",
"output": "4747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474..."
},
{
"input": "1 2 1 1",
"output": "747"
},
{
"input": "2 1 1 1",
"output": "474"
},
{
"input": "2 2 2 1",
"output": "4747"
},
{
"input": "2 2 2 2",
"output": "-1"
},
{
"input": "1 3 1 1",
"output": "7477"
},
{
"input": "1 4 1 1",
"output": "74777"
},
{
"input": "2 3 2 2",
"output": "74747"
},
{
"input": "2 5 2 2",
"output": "7474777"
},
{
"input": "1 2 2 1",
"output": "-1"
},
{
"input": "10 100 2 2",
"output": "44444444747777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777774"
},
{
"input": "3 4 3 3",
"output": "7474747"
},
{
"input": "30 30 29 29",
"output": "474747474747474747474747474747474747474747474747474747474774"
},
{
"input": "10 10 1 2",
"output": "74444444447777777774"
},
{
"input": "999999 1000000 999999 999999",
"output": "7474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747474747..."
},
{
"input": "10 11 1 1",
"output": "444444444777777777774"
},
{
"input": "10 10 2 2",
"output": "44444444747777777774"
},
{
"input": "100 200 5 5",
"output": "444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444444447474747477777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777777774"
},
{
"input": "10 11 10 10",
"output": "747474747474747474747"
},
{
"input": "5 10 2 3",
"output": "744474777777774"
},
{
"input": "6 8 1 1",
"output": "44444777777774"
},
{
"input": "1 9 2 2",
"output": "-1"
}
] | 1,678,959,080 | 2,147,483,647 | PyPy 3 | OK | TESTS | 99 | 404 | 9,011,200 | a, b, c, d = input().strip().split()
a = int(a)
b = int(b)
c = int(c)
d = int(d)
if abs(c - d) > 1 or min(a, b) < max(c, d) or a == b == c == d:
print(-1)
exit()
if c == d:
if a == c:
ans = '74' * c + '7' * (b - c)
else:
ans = '4' * (a - c - 1) + '47' * c + '7' * (b - c) + '4'
elif c > d:
ans = '4' * (a - c) + '47' * c + '7' * (b - c)
else:
ans = '7' + '4' * (a - c) + '74' * (c - 1) + '7' * (b - c) + '4'
print(ans) | Title: Lucky Number 2
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Petya loves lucky numbers very much. Everybody knows that lucky numbers are positive integers whose decimal record contains only the lucky digits 4 and 7. For example, numbers 47, 744, 4 are lucky and 5, 17, 467 are not.
Petya loves long lucky numbers very much. He is interested in the minimum lucky number *d* that meets some condition. Let *cnt*(*x*) be the number of occurrences of number *x* in number *d* as a substring. For example, if *d*<==<=747747, then *cnt*(4)<==<=2, *cnt*(7)<==<=4, *cnt*(47)<==<=2, *cnt*(74)<==<=2. Petya wants the following condition to fulfil simultaneously: *cnt*(4)<==<=*a*1, *cnt*(7)<==<=*a*2, *cnt*(47)<==<=*a*3, *cnt*(74)<==<=*a*4. Petya is not interested in the occurrences of other numbers. Help him cope with this task.
Input Specification:
The single line contains four integers *a*1, *a*2, *a*3 and *a*4 (1<=≤<=*a*1,<=*a*2,<=*a*3,<=*a*4<=≤<=106).
Output Specification:
On the single line print without leading zeroes the answer to the problem — the minimum lucky number *d* such, that *cnt*(4)<==<=*a*1, *cnt*(7)<==<=*a*2, *cnt*(47)<==<=*a*3, *cnt*(74)<==<=*a*4. If such number does not exist, print the single number "-1" (without the quotes).
Demo Input:
['2 2 1 1\n', '4 7 3 1\n']
Demo Output:
['4774\n', '-1\n']
Note:
none | ```python
a, b, c, d = input().strip().split()
a = int(a)
b = int(b)
c = int(c)
d = int(d)
if abs(c - d) > 1 or min(a, b) < max(c, d) or a == b == c == d:
print(-1)
exit()
if c == d:
if a == c:
ans = '74' * c + '7' * (b - c)
else:
ans = '4' * (a - c - 1) + '47' * c + '7' * (b - c) + '4'
elif c > d:
ans = '4' * (a - c) + '47' * c + '7' * (b - c)
else:
ans = '7' + '4' * (a - c) + '74' * (c - 1) + '7' * (b - c) + '4'
print(ans)
``` | 3 | |
813 | A | The Contest | PROGRAMMING | 1,100 | [
"implementation"
] | null | null | Pasha is participating in a contest on one well-known website. This time he wants to win the contest and will do anything to get to the first place!
This contest consists of *n* problems, and Pasha solves *i*th problem in *a**i* time units (his solutions are always correct). At any moment of time he can be thinking about a solution to only one of the problems (that is, he cannot be solving two problems at the same time). The time Pasha spends to send his solutions is negligible. Pasha can send any number of solutions at the same moment.
Unfortunately, there are too many participants, and the website is not always working. Pasha received the information that the website will be working only during *m* time periods, *j*th period is represented by its starting moment *l**j* and ending moment *r**j*. Of course, Pasha can send his solution only when the website is working. In other words, Pasha can send his solution at some moment *T* iff there exists a period *x* such that *l**x*<=≤<=*T*<=≤<=*r**x*.
Pasha wants to know his best possible result. We need to tell him the minimal moment of time by which he is able to have solutions to all problems submitted, if he acts optimally, or say that it's impossible no matter how Pasha solves the problems. | The first line contains one integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems. The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=105) — the time Pasha needs to solve *i*th problem.
The third line contains one integer *m* (0<=≤<=*m*<=≤<=1000) — the number of periods of time when the website is working. Next *m* lines represent these periods. *j*th line contains two numbers *l**j* and *r**j* (1<=≤<=*l**j*<=<<=*r**j*<=≤<=105) — the starting and the ending moment of *j*th period.
It is guaranteed that the periods are not intersecting and are given in chronological order, so for every *j*<=><=1 the condition *l**j*<=><=*r**j*<=-<=1 is met. | If Pasha can solve and submit all the problems before the end of the contest, print the minimal moment of time by which he can have all the solutions submitted.
Otherwise print "-1" (without brackets). | [
"2\n3 4\n2\n1 4\n7 9\n",
"1\n5\n1\n1 4\n",
"1\n5\n1\n1 5\n"
] | [
"7\n",
"-1\n",
"5\n"
] | In the first example Pasha can act like this: he solves the second problem in 4 units of time and sends it immediately. Then he spends 3 time units to solve the first problem and sends it 7 time units after the contest starts, because at this moment the website starts working again.
In the second example Pasha invents the solution only after the website stops working for the last time.
In the third example Pasha sends the solution exactly at the end of the first period. | 0 | [
{
"input": "2\n3 4\n2\n1 4\n7 9",
"output": "7"
},
{
"input": "1\n5\n1\n1 4",
"output": "-1"
},
{
"input": "1\n5\n1\n1 5",
"output": "5"
},
{
"input": "5\n100000 100000 100000 100000 100000\n0",
"output": "-1"
},
{
"input": "5\n886 524 128 4068 298\n3\n416 3755\n4496 11945\n17198 18039",
"output": "5904"
},
{
"input": "10\n575 3526 1144 1161 889 1038 790 19 765 357\n2\n4475 10787\n16364 21678",
"output": "10264"
},
{
"input": "1\n4\n1\n5 9",
"output": "5"
},
{
"input": "1\n200\n4\n1 10\n20 40\n50 55\n190 210",
"output": "200"
},
{
"input": "4\n643 70 173 745\n14\n990 995\n1256 1259\n1494 1499\n1797 1804\n2443 2450\n2854 2859\n3164 3167\n4084 4092\n4615 4622\n5555 5563\n6412 6421\n7173 7180\n7566 7571\n8407 8415",
"output": "1797"
},
{
"input": "42\n749 516 256 497 37 315 184 518 103 726 80 983 474 884 209 706 10 543 587 371 199 315 967 707 948 736 590 734 715 184 230 513 199 898 287 468 250 600 352 29 408 22\n2\n312 314\n1293 1302",
"output": "-1"
},
{
"input": "1\n10000\n2\n1 10\n9998 10000",
"output": "10000"
},
{
"input": "1\n547\n15\n774 779\n1598 1605\n2458 2464\n3138 3140\n3372 3378\n4268 4272\n4730 4733\n5064 5067\n5074 5075\n5483 5490\n5894 5901\n5931 5938\n6750 6756\n7487 7491\n8328 8332",
"output": "774"
},
{
"input": "1\n10\n2\n1 2\n11 12",
"output": "11"
},
{
"input": "2\n4 6\n2\n5 10\n15 20",
"output": "10"
},
{
"input": "2\n16 5\n3\n5 10\n15 20\n25 30",
"output": "25"
},
{
"input": "1\n16\n2\n5 10\n15 20",
"output": "16"
},
{
"input": "44\n750 672 846 969 981 698 380 968 813 587 156 28 446 917 849 449 173 764 226 958 335 622 236 782 416 689 113 728 452 265 585 217 707 50 520 712 946 275 423 123 175 268 583 528\n4\n869 870\n1353 1354\n1683 1685\n2532 2540",
"output": "-1"
},
{
"input": "1\n1\n0",
"output": "-1"
},
{
"input": "3\n1 2 5\n3\n5 6\n7 8\n9 13",
"output": "8"
},
{
"input": "1\n2\n0",
"output": "-1"
},
{
"input": "1\n5\n3\n1 2\n3 4\n10 11",
"output": "10"
},
{
"input": "1\n4\n0",
"output": "-1"
},
{
"input": "1\n5\n0",
"output": "-1"
},
{
"input": "1\n239\n0",
"output": "-1"
}
] | 1,496,676,394 | 1,294 | Python 3 | OK | TESTS | 29 | 62 | 0 | def solve():
strInput = input()
n = int(strInput)
strInput = input()
times = strInput.split()
totalSolvingTime = 0
for s in times:
totalSolvingTime += int(s)
strInput = input()
m = int(strInput)
for i in range(m):
fullRange = input()
boundaries = fullRange.split()
if totalSolvingTime > int(boundaries[1]):
continue
else:
left = int(boundaries[0])
if left >= totalSolvingTime:
return left
else:
return totalSolvingTime
return -1
print(solve())
| Title: The Contest
Time Limit: None seconds
Memory Limit: None megabytes
Problem Description:
Pasha is participating in a contest on one well-known website. This time he wants to win the contest and will do anything to get to the first place!
This contest consists of *n* problems, and Pasha solves *i*th problem in *a**i* time units (his solutions are always correct). At any moment of time he can be thinking about a solution to only one of the problems (that is, he cannot be solving two problems at the same time). The time Pasha spends to send his solutions is negligible. Pasha can send any number of solutions at the same moment.
Unfortunately, there are too many participants, and the website is not always working. Pasha received the information that the website will be working only during *m* time periods, *j*th period is represented by its starting moment *l**j* and ending moment *r**j*. Of course, Pasha can send his solution only when the website is working. In other words, Pasha can send his solution at some moment *T* iff there exists a period *x* such that *l**x*<=≤<=*T*<=≤<=*r**x*.
Pasha wants to know his best possible result. We need to tell him the minimal moment of time by which he is able to have solutions to all problems submitted, if he acts optimally, or say that it's impossible no matter how Pasha solves the problems.
Input Specification:
The first line contains one integer *n* (1<=≤<=*n*<=≤<=1000) — the number of problems. The second line contains *n* integers *a**i* (1<=≤<=*a**i*<=≤<=105) — the time Pasha needs to solve *i*th problem.
The third line contains one integer *m* (0<=≤<=*m*<=≤<=1000) — the number of periods of time when the website is working. Next *m* lines represent these periods. *j*th line contains two numbers *l**j* and *r**j* (1<=≤<=*l**j*<=<<=*r**j*<=≤<=105) — the starting and the ending moment of *j*th period.
It is guaranteed that the periods are not intersecting and are given in chronological order, so for every *j*<=><=1 the condition *l**j*<=><=*r**j*<=-<=1 is met.
Output Specification:
If Pasha can solve and submit all the problems before the end of the contest, print the minimal moment of time by which he can have all the solutions submitted.
Otherwise print "-1" (without brackets).
Demo Input:
['2\n3 4\n2\n1 4\n7 9\n', '1\n5\n1\n1 4\n', '1\n5\n1\n1 5\n']
Demo Output:
['7\n', '-1\n', '5\n']
Note:
In the first example Pasha can act like this: he solves the second problem in 4 units of time and sends it immediately. Then he spends 3 time units to solve the first problem and sends it 7 time units after the contest starts, because at this moment the website starts working again.
In the second example Pasha invents the solution only after the website stops working for the last time.
In the third example Pasha sends the solution exactly at the end of the first period. | ```python
def solve():
strInput = input()
n = int(strInput)
strInput = input()
times = strInput.split()
totalSolvingTime = 0
for s in times:
totalSolvingTime += int(s)
strInput = input()
m = int(strInput)
for i in range(m):
fullRange = input()
boundaries = fullRange.split()
if totalSolvingTime > int(boundaries[1]):
continue
else:
left = int(boundaries[0])
if left >= totalSolvingTime:
return left
else:
return totalSolvingTime
return -1
print(solve())
``` | 3 |
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