Submission #304768

# Submission time Handle Problem Language Result Execution time Memory
304768 2020-09-21T20:40:15 Z Fdg Counting Mushrooms (IOI20_mushrooms) C++14
97.4138 / 100
10 ms 544 KB
#include <iostream>
#include <vector>
#include <map>
#include <set>
#include <algorithm>
#include "mushrooms.h"

using namespace std;

const int VAL = 100;

vector<int> a, b, missing;

map<int, vector<int>> diff, eq;
set<int> found;

void nextPos(const vector<int>& v, int& pos) {
  while (pos < (int) v.size()) {
    if (found.count(v[pos])) {
      ++pos;
    } else break;
  }
}

void process(int x, bool isA) {
  if (found.count(x)) return;
  found.insert(x);

  if (isA) a.push_back(x);
  else b.push_back(x);

  if (diff.count(x))
    for (int val : diff[x]) {
      process(val, !isA);
    }

  if (eq.count(x))
    for (int val : eq[x]) {
      process(val, isA);
    }
}

int count_mushrooms(int n) {
  a.clear(); b.clear(); diff.clear(); found.clear(); missing.clear();

  srand(time(NULL));
  vector<int> v;
  for (int i = 1; i < n; ++i)
    v.push_back(i);
  // random_shuffle(v.begin(), v.end());

  int ans = 0, pos = 0;

  bool doNextSimple = false;

  double COEF = 1.2;
  int iter = 1;

  a.push_back(0); found.insert(0);
  while (a.size() < VAL && b.size() < VAL && pos + 10 < (int) v.size()) {
    if (a.size() > 2 && b.size() > 1) {
      vector<int> arr;
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(a[0]);
        arr.push_back(v[pos]), ++pos;
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(a[1]);
        arr.push_back(v[pos]), ++pos; 
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(a[2]);
        arr.push_back(v[pos]), ++pos; 
      }

      int ret = use_machine(arr);
      if (arr.size() == 2) {
        if (ret == 1) {
          process(arr[1], false);
        } else {
          process(arr[1], true);
        }
      } else if (arr.size() == 4) {
        if (ret == 3) {
          process(arr[1], false);
          process(arr[3], false);
        } else if (ret == 2) {
          process(arr[1], false);
          process(arr[3], true);
        } else if (ret == 1) {
          process(arr[1], true);
          process(arr[3], false); 
        } else {
          process(arr[1], true);
          process(arr[3], true);
        }
      } else if (arr.size() == 6) {
        if (ret == 5) {
          process(arr[1], false);
          process(arr[3], false);
          process(arr[5], false);
        } else if (ret == 4) {
          process(arr[1], false);
          process(arr[3], false);
          process(arr[5], true);
        } else if (ret == 3) {
          process(arr[5], false);
          vector<int> nArr = {b[1], arr[1], b[0], a[0], arr[3], a[1]};
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
            nArr.push_back(a[2]);
          }
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
          }

          int cur = use_machine(nArr) - 1;
          process(arr[1], (cur & 4));
          process(arr[3], !(cur & 4));
          process(nArr[6], !(cur & 2));
          process(nArr[8], !(cur & 1));
        } else if (ret == 2) {
          process(arr[5], true);
          vector<int> nArr = {b[1], arr[1], b[0], a[0], arr[3], a[1]};
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
            nArr.push_back(a[2]);
          }
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
          }

          int cur = use_machine(nArr) - 1;
          process(arr[1], (cur & 4));
          process(arr[3], !(cur & 4));
          process(nArr[6], !(cur & 2));
          process(nArr[8], !(cur & 1));
        } else if (ret == 1) {
          process(arr[1], true);
          process(arr[3], true);
          process(arr[5], false);
        } else {
          process(arr[1], true);
          process(arr[3], true);
          process(arr[5], true);
        }
      }
    } else if (b.size() > 2 && a.size() > 1) {
      vector<int> arr;
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(b[0]);
        arr.push_back(v[pos]), ++pos;
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(b[1]);
        arr.push_back(v[pos]), ++pos; 
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(b[2]);
        arr.push_back(v[pos]), ++pos; 
      }

      int ret = use_machine(arr);
      if (arr.size() == 2) {
        if (ret == 1) {
          process(arr[1], true);
        } else {
          process(arr[1], false);
        }
        exit(-1);
      } else if (arr.size() == 4) {
        if (ret == 3) {
          process(arr[1], true);
          process(arr[3], true);
        } else if (ret == 2) {
          process(arr[1], true);
          process(arr[3], false);
        } else if (ret == 1) {
          process(arr[1], false);
          process(arr[3], true); 
        } else {
          process(arr[1], false);
          process(arr[3], false);
        }
        exit(-1);
      } else if (arr.size() == 6) {
        if (ret == 5) {
          process(arr[1], true);
          process(arr[3], true);
          process(arr[5], true);
        } else if (ret == 4) {
          process(arr[1], true);
          process(arr[3], true);
          process(arr[5], false);
        } else if (ret == 3) {
          process(arr[5], true);
          vector<int> nArr = {a[1], arr[1], a[0], b[0], arr[3], b[1]};
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
            nArr.push_back(b[2]);
          }
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
          }

          int cur = use_machine(nArr) - 1;
          process(arr[1], !(cur & 4));
          process(arr[3], (cur & 4));
          process(nArr[6], (cur & 2));
          process(nArr[8], (cur & 1));
        } else if (ret == 2) {
          process(arr[5], false);
          vector<int> nArr = {a[1], arr[1], a[0], b[0], arr[3], b[1]};
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
            nArr.push_back(b[2]);
          }
          nextPos(v, pos);
          if (pos < (int) v.size()) {
            nArr.push_back(v[pos]), ++pos;
          }

          int cur = use_machine(nArr) - 1;
          process(arr[1], !(cur & 4));
          process(arr[3], (cur & 4));
          process(nArr[6], (cur & 2));
          process(nArr[8], (cur & 1));
        } else if (ret == 1) {
          process(arr[1], false);
          process(arr[3], false);
          process(arr[5], true);
        } else {
          process(arr[1], false);
          process(arr[3], false);
          process(arr[5], false);
        }
      }
    } else if (a.size() > 1) {
      vector<int> arr;
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(v[pos]), ++pos;
        arr.push_back(a[0]);
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(v[pos]), ++pos;
        arr.push_back(a[1]); 
      }
 
      int ret = use_machine(arr);
      if (arr.size() == 2) {
        if (ret == 1) {
          process(arr[0], false);
        } else {
          process(arr[0], true);
        }
      } else if (arr.size() == 4) {
        if (ret == 3) {
          process(arr[0], false);
          process(arr[2], false);
        } else if (ret == 2) {
          process(arr[0], true);
          process(arr[2], false);
        } else if (ret == 1) {
          process(arr[0], false);
          process(arr[2], true); 
        } else {
          process(arr[0], true);
          process(arr[2], true);
        }
      }
    } else if (b.size() > 1) {
      vector<int> arr;
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(v[pos]), ++pos;
        arr.push_back(b[0]);
      }
      nextPos(v, pos);
      if (pos < (int) v.size()) {
        arr.push_back(v[pos]), ++pos;
        arr.push_back(b[1]); 
      }
 
      int ret = use_machine(arr);
      if (arr.size() == 2) {
        if (ret == 1) {
          process(arr[0], true);
        } else {
          process(arr[0], false);
        }
      } else if (arr.size() == 4) {
        if (ret == 3) {
          process(arr[0], true);
          process(arr[2], true);
        } else if (ret == 2) {
          process(arr[0], false);
          process(arr[2], true);
        } else if (ret == 1) {
          process(arr[0], true);
          process(arr[2], false); 
        } else {
          process(arr[0], false);
          process(arr[2], false);
        }
      }
    } else {
      vector<int> arr = {a[0]};
      nextPos(v, pos);
      if (pos < (int) v.size()) arr.push_back(v[pos]), ++pos;
      else break;

      int ret = use_machine(arr);
      if (ret & 1) {
        process(arr[1], false);
      } else {
        process(arr[1], true);
      }
    }
  }

  ans = a.size();

  for (int x : missing) {
    if (!found.count(x))
      v.push_back(x);
  }

  if (a.size() >= b.size()) {
    while (pos < (int) v.size()) {
      vector<int> arr;
      int used = 0;
      for (int i = 0; i < (int) a.size(); ++i) {
        arr.push_back(a[i]);
        nextPos(v, pos);
        if (pos < (int) v.size()) {
          arr.push_back(v[pos]), ++pos;
          ++used;
        } else break;
      }
      int ret = use_machine(arr);
      int diff = (ret / 2) + (ret & 1);
      ans += used - diff;
      if (ret & 1) {
        b.push_back(arr.back());
      } else {
        a.push_back(arr.back());
      }
    }
  } else {
    while (pos < (int) v.size()) {
      vector<int> arr;
      int used = 0;
      for (int i = 0; i < (int) b.size(); ++i) {
        arr.push_back(b[i]);
        nextPos(v, pos);
        if (pos < (int) v.size()) {
          arr.push_back(v[pos]), ++pos;
          ++used;
        } else break;
      }
      int ret = use_machine(arr);
      int diff = (ret / 2) + (ret & 1);
      ans += diff;
      if (ret & 1) {
        a.push_back(arr.back());
      } else {
        b.push_back(arr.back());
      }
    }
  }

  return ans;
}

// int count_mushrooms(int n) {
//   int ans = 1;
//   for (int i = 1; i < n; i += 2) {
//     vector<int> v;
//     if (i + 1 < n) v = {i, 0, i + 1};
//     else v = {i, 0};
//     int ret = use_machine(v);
//     ans += (v.size() - 1) - ret;
//   }
//   return ans;
// }

// int main() {
//   ios::sync_with_stdio(false);

//   return 0; 
// }

Compilation message

mushrooms.cpp: In function 'int count_mushrooms(int)':
mushrooms.cpp:54:8: warning: unused variable 'doNextSimple' [-Wunused-variable]
   54 |   bool doNextSimple = false;
      |        ^~~~~~~~~~~~
mushrooms.cpp:56:10: warning: unused variable 'COEF' [-Wunused-variable]
   56 |   double COEF = 1.2;
      |          ^~~~
mushrooms.cpp:57:7: warning: unused variable 'iter' [-Wunused-variable]
   57 |   int iter = 1;
      |       ^~~~
# Verdict Execution time Memory Grader output
1 Correct 0 ms 256 KB Output is correct
2 Correct 0 ms 256 KB Output is correct
3 Correct 0 ms 256 KB Output is correct
4 Correct 1 ms 256 KB Output is correct
5 Correct 1 ms 256 KB Output is correct
6 Correct 2 ms 384 KB Output is correct
7 Correct 7 ms 512 KB Output is correct
8 Correct 6 ms 512 KB Output is correct
9 Correct 7 ms 512 KB Output is correct
10 Correct 8 ms 512 KB Output is correct
11 Correct 7 ms 512 KB Output is correct
12 Correct 9 ms 512 KB Output is correct
13 Correct 6 ms 512 KB Output is correct
14 Correct 4 ms 384 KB Output is correct
15 Correct 8 ms 512 KB Output is correct
16 Correct 7 ms 512 KB Output is correct
17 Correct 5 ms 384 KB Output is correct
18 Correct 6 ms 512 KB Output is correct
19 Correct 7 ms 512 KB Output is correct
20 Correct 9 ms 512 KB Output is correct
21 Correct 7 ms 512 KB Output is correct
22 Correct 7 ms 512 KB Output is correct
23 Correct 8 ms 512 KB Output is correct
24 Correct 5 ms 512 KB Output is correct
25 Correct 7 ms 512 KB Output is correct
26 Correct 9 ms 512 KB Output is correct
27 Correct 7 ms 512 KB Output is correct
28 Correct 7 ms 512 KB Output is correct
29 Correct 9 ms 512 KB Output is correct
30 Correct 9 ms 512 KB Output is correct
31 Correct 7 ms 512 KB Output is correct
32 Correct 8 ms 512 KB Output is correct
33 Correct 7 ms 512 KB Output is correct
34 Partially correct 7 ms 544 KB Output is partially correct
35 Partially correct 8 ms 512 KB Output is partially correct
36 Correct 7 ms 512 KB Output is correct
37 Partially correct 9 ms 512 KB Output is partially correct
38 Correct 7 ms 512 KB Output is correct
39 Partially correct 10 ms 512 KB Output is partially correct
40 Correct 9 ms 512 KB Output is correct
41 Partially correct 7 ms 512 KB Output is partially correct
42 Partially correct 8 ms 512 KB Output is partially correct
43 Correct 7 ms 512 KB Output is correct
44 Partially correct 9 ms 512 KB Output is partially correct
45 Correct 7 ms 512 KB Output is correct
46 Partially correct 7 ms 512 KB Output is partially correct
47 Partially correct 7 ms 512 KB Output is partially correct
48 Correct 7 ms 512 KB Output is correct
49 Partially correct 9 ms 512 KB Output is partially correct
50 Correct 7 ms 512 KB Output is correct
51 Correct 7 ms 512 KB Output is correct
52 Correct 10 ms 512 KB Output is correct
53 Partially correct 10 ms 512 KB Output is partially correct
54 Partially correct 7 ms 512 KB Output is partially correct
55 Partially correct 9 ms 512 KB Output is partially correct
56 Partially correct 8 ms 512 KB Output is partially correct
57 Correct 7 ms 512 KB Output is correct
58 Partially correct 6 ms 512 KB Output is partially correct
59 Correct 7 ms 512 KB Output is correct
60 Partially correct 7 ms 512 KB Output is partially correct
61 Partially correct 7 ms 512 KB Output is partially correct
62 Correct 1 ms 256 KB Output is correct
63 Correct 0 ms 256 KB Output is correct
64 Correct 0 ms 256 KB Output is correct
65 Correct 0 ms 256 KB Output is correct
66 Correct 0 ms 256 KB Output is correct
67 Correct 0 ms 256 KB Output is correct
68 Correct 1 ms 256 KB Output is correct
69 Correct 0 ms 256 KB Output is correct
70 Correct 0 ms 256 KB Output is correct
71 Correct 0 ms 256 KB Output is correct
72 Correct 0 ms 256 KB Output is correct
73 Correct 1 ms 256 KB Output is correct
74 Correct 1 ms 256 KB Output is correct
75 Correct 0 ms 256 KB Output is correct
76 Correct 0 ms 256 KB Output is correct
77 Correct 0 ms 256 KB Output is correct
78 Correct 0 ms 256 KB Output is correct
79 Correct 0 ms 256 KB Output is correct
80 Correct 1 ms 256 KB Output is correct
81 Correct 0 ms 256 KB Output is correct
82 Correct 0 ms 256 KB Output is correct
83 Correct 0 ms 256 KB Output is correct
84 Correct 0 ms 256 KB Output is correct
85 Correct 0 ms 256 KB Output is correct
86 Correct 1 ms 256 KB Output is correct
87 Correct 0 ms 256 KB Output is correct
88 Correct 0 ms 256 KB Output is correct
89 Correct 1 ms 256 KB Output is correct
90 Correct 0 ms 256 KB Output is correct
91 Correct 1 ms 256 KB Output is correct