# | 제출 시각 | 아이디 | 문제 | 언어 | 결과 | 실행 시간 | 메모리 |
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1090432 | 2024-09-18T10:59:44 Z | lucri | COVID tests (CEOI24_covid) | C++17 | 2481 ms | 600 KB |
#include <bits/stdc++.h> /// You may use: // The number of students int N,T; // The probability any given student is positive double P; // This function performs a test on a subset of samples. // Its argument is a vector of Booleans of length N, // where the i-th element is true if the i-th sample should be added to the mix. // It returns true if (and only if) at least one of the samples in the mix is positive. bool test_students(std::vector<bool> mask) { assert(mask.size() == (size_t)N); std::string mask_str(N, ' '); for (int i = 0; i < N; i++) mask_str[i] = mask[i] ? '1' : '0'; printf("Q %s\n", mask_str.c_str()); fflush(stdout); char answer; scanf(" %c", &answer); return answer == 'P'; } /// You should implement: // This function will be called once for each test instance. // It should use test_students to determine which samples are positive. // It must return a vector of Booleans of length N, // where the i-th element is true if and only if the i-th sample is positive. std::vector<bool> answer; std::vector<bool> test; std::vector<int> ind; int p[5010]; void calculeaza(int b,int e,int sz) { if(b>e) return; int ce=e; e=b+2*sz-1; while(e>p[0]) { ++p[0]; p[p[0]]=p[p[0]]=ce; } while(b<e) { if(b>ce) return; int mid=(b+e)/2; for(int i=b;i<=mid;++i) test[p[i]]=1; bool r=test_students(test); for(int i=b;i<=mid;++i) test[p[i]]=0; if(r==false) b=mid+1; else e=mid; } if(b<=ce) { answer[p[b]]=1; calculeaza(b+1,ce,sz); } return; } void raspunde(int sz) { p[0]=0; for(int i=0;i<N;i+=sz) { for(int j=i;j<i+sz&&j<N;++j) test[j]=1; if(test_students(test)==true) { for(int j=i;j<i+sz&&j<N;++j) p[++p[0]]=j; } for(int j=i;j<i+sz&&j<N;++j) test[j]=0; } calculeaza(1,p[0],sz); } std::vector<bool> find_positive() { for(int i=0;i<N;++i) { answer[i]=test[i]=0; ind[i]=i; } random_shuffle(ind.begin(),ind.end()); if(T==1)//subtask 1 { raspunde(1); } else if(P>0.17)//P=0.2 { raspunde(10); } else if(P>0.11)//P=0.158765 { raspunde(6); } else if(P>0.1)//P=0.104571 { raspunde(6); } else if(P>0.06)//P=0.068648 { raspunde(10); } else if(P>0.03)//P=0.039856 { raspunde(17); } else if(P>0.02)//P=0.028545 { raspunde(24); } else if(P>0.01)//P=0.011546 { raspunde(75); } else if(P>0.005)///P=0.005256 { raspunde(200); } else///P=0.001 { raspunde(500); } return answer; } int main() { scanf("%d %lf %d", &N, &P, &T); // You may perform any extra initialization here. srand(time(0)); answer.resize(N); ind.resize(N); test.resize(N); for (int i = 0; i < T; i++) { std::vector<bool> answer = find_positive(); assert(answer.size() == (size_t)N); std::string answer_str(N, ' '); for (int j = 0; j < N; j++) answer_str[j] = answer[j] ? '1' : '0'; printf("A %s\n", answer_str.c_str()); fflush(stdout); char verdict; scanf(" %c", &verdict); if (verdict == 'W') exit(0); } return 0; }
Compilation message
# | 결과 | 실행 시간 | 메모리 | Grader output |
---|---|---|---|---|
1 | Correct | 0 ms | 344 KB | Output is correct |
# | 결과 | 실행 시간 | 메모리 | Grader output |
---|---|---|---|---|
1 | Correct | 16 ms | 344 KB | Output is correct |
2 | Correct | 9 ms | 444 KB | Output is correct |
3 | Correct | 12 ms | 440 KB | Output is correct |
4 | Correct | 9 ms | 340 KB | Output is correct |
5 | Correct | 12 ms | 440 KB | Output is correct |
6 | Correct | 17 ms | 600 KB | Output is correct |
7 | Correct | 11 ms | 344 KB | Output is correct |
8 | Correct | 8 ms | 344 KB | Output is correct |
9 | Correct | 9 ms | 344 KB | Output is correct |
10 | Correct | 7 ms | 344 KB | Output is correct |
11 | Correct | 15 ms | 340 KB | Output is correct |
12 | Correct | 8 ms | 344 KB | Output is correct |
13 | Correct | 11 ms | 344 KB | Output is correct |
14 | Correct | 9 ms | 344 KB | Output is correct |
15 | Correct | 8 ms | 344 KB | Output is correct |
16 | Correct | 11 ms | 344 KB | Output is correct |
17 | Correct | 6 ms | 344 KB | Output is correct |
# | 결과 | 실행 시간 | 메모리 | Grader output |
---|---|---|---|---|
1 | Correct | 27 ms | 344 KB | Output is correct (P=0.001, F=15.1, Q=11.7) -> 90.00 points |
2 | Correct | 118 ms | 344 KB | Output is correct (P=0.005256, F=51.1, Q=50.3) -> 90.00 points |
3 | Correct | 241 ms | 344 KB | Output is correct (P=0.011546, F=94.9, Q=98.5) -> 78.14 points |
4 | Correct | 478 ms | 344 KB | Output is correct (P=0.028545, F=191.5, Q=204.7) -> 70.55 points |
5 | Correct | 664 ms | 592 KB | Output is correct (P=0.039856, F=246.3, Q=266.6) -> 67.69 points |
6 | Correct | 1033 ms | 428 KB | Output is correct (P=0.068648, F=366.2, Q=407.9) -> 61.83 points |
7 | Correct | 1336 ms | 344 KB | Output is correct (P=0.104571, F=490.3, Q=556.5) -> 58.44 points |
8 | Correct | 1939 ms | 440 KB | Output is correct (P=0.158765, F=639.1, Q=754.9) -> 52.18 points |
9 | Correct | 2481 ms | 344 KB | Output is correct (P=0.2, F=731.4, Q=1012.8) -> 35.45 points |