Submission #297624

#TimeUsernameProblemLanguageResultExecution timeMemory
297624A02Split the Attractions (IOI19_split)C++14
Compilation error
0 ms0 KiB
#include <bits/stdc++.h> #include "rect.h" using namespace std; void updateMinSegTree(vector<int> &segtree, int p, int a){ int N = segtree.size() / 2; p += N; segtree[p] = a; p /= 2; while (p > 0){ segtree[p] = min(segtree[2 * p], segtree[2 * p + 1]); p /= 2; } } int queryMinSegTree(vector<int> &segtree, int l, int r){ int N = segtree.size() / 2; int total = 2501; for (l += N, r += N; l < r; l /= 2, r /= 2){ if (l % 2 == 1){ total = min(segtree[l++], total); } if (r % 2 == 1){ total = min(segtree[--r], total); } } return total; } void updateMaxSegTree(vector<int> &segtree, int p, int a){ int N = segtree.size() / 2; p += N; segtree[p] = a; p /= 2; while (p > 0){ segtree[p] = max(segtree[2 * p], segtree[2 * p + 1]); p /= 2; } } int queryMaxSegTree(vector<int> &segtree, int l, int r){ int N = segtree.size() / 2; int total = -1; for (l += N, r += N; l < r; l /= 2, r /= 2){ if (l % 2 == 1){ total = max(segtree[l++], total); } if (r % 2 == 1){ total = max(segtree[--r], total); } } return total; } long long count_rectangles(vector<vector<int> > a) { int n = a.size(); int m = a[0].size(); long long total = 0; bool all_one = true; for (int i = 0; i < n; i++){ for (int j = 0; j < m; j++){ if (a[i][j] > 1){ all_one = false; break; } } } if (all_one){ vector<vector<bool> > visited (n, vector<bool> (m, false)); for (int i = 0; i < n; i++){ for (int j = 0; j < m; j++){ if (a[i][j] == 0 && !visited[i][j]){ vector<pair<int, int> > ones; bool bad = false; queue<pair<int, int> > to_visit; to_visit.push(make_pair(i, j)); visited[i][j] = true; while(!to_visit.empty()){ pair<int, int> current = to_visit.front(); to_visit.pop(); if (current.first == 0 || current.first == n - 1 || current.second == 0 || current.second == m - 1){ bad = true; } int ic = current.first; int jc = current.second; if (ic < n - 1 && !visited[ic + 1][jc]){ if (a[ic + 1][jc] == 1){ ones.push_back(make_pair(ic + 1, jc)); } else { visited[ic + 1][jc] = true; to_visit.push(make_pair(ic + 1, jc)); } } if (ic > 0 && !visited[ic - 1][jc]){ if (a[ic - 1][jc] == 1){ ones.push_back(make_pair(ic - 1, jc)); } else { visited[ic - 1][jc] = true; to_visit.push(make_pair(ic - 1, jc)); } } if (jc < m - 1 && !visited[ic][jc + 1]){ if (a[ic][jc + 1] == 1){ ones.push_back(make_pair(ic, jc + 1)); } else { visited[ic][jc + 1] = true; to_visit.push(make_pair(ic, jc + 1)); } } if (jc > 0 && !visited[ic][jc - 1]){ if (a[ic][jc - 1] == 1){ ones.push_back(make_pair(ic, jc - 1)); } else { visited[ic][jc - 1] = true; to_visit.push(make_pair(ic, jc - 1)); } } } if (!bad){ int mini = n; int maxi = 0; int minj = m; int maxj = 0; for (int x = 0; x < ones.size(); x++){ mini = min(mini, ones[x].first); minj = min(minj, ones[x].second); maxi = max(maxi, ones[x].first); maxj = max(maxj, ones[x].second); } for (int x = 0; x < ones.size(); x++){ if (ones[x].first != mini && ones[x].first != maxi && ones[x].second != minj && ones[x].second != maxj){ bad = true; break; } } } if (!bad){ total++; } } } } return total; } vector<vector<int> > min_left (vector<vector<int> > (n, vector<int> (m, 0))); vector<vector<int> > min_up (vector<vector<int> > (n, vector<int> (m, 0))); vector<vector<int> > max_right (vector<vector<int> > (n, vector<int> (m, 0))); vector<vector<int> > max_down (vector<vector<int> > (n, vector<int> (m, 0))); for (int i = 0; i < n; i++){ vector<int> current_row = a[i]; vector<pair<int, int> > order_to_process (m, pair<int, int>()); for (int j = 0; j < m; j++){ order_to_process[j].first = a[i][j]; order_to_process[j].second = j; } sort(order_to_process.begin(), order_to_process.end()); for (int x = 0; x < m; x++){ int current_value = order_to_process[x].first; int current_index = order_to_process[x].second; int current_right_index = current_index + 1; int current_left_index = current_index - 1; while (current_right_index < m){ if (a[i][current_right_index] >= current_value){ break; } else { current_right_index = max_right[i][current_right_index]; } } while (current_left_index >= 0){ if (a[i][current_left_index] >= current_value){ break; } else { current_left_index = min_left[i][current_left_index]; } } max_right[i][current_index] = current_right_index; min_left[i][current_index] = current_left_index; } } for (int j = 0; j < m; j++){ vector<int> current_column (n, 0); for (int i = 0; i < n; i++){ current_column[i] = a[i][j]; } vector<pair<int, int> > order_to_process (n, pair<int, int>()); for (int i = 0; i < n; i++){ order_to_process[i].first = a[i][j]; order_to_process[i].second = i; } sort(order_to_process.begin(), order_to_process.end()); for (int x = 0; x < n; x++){ int current_value = order_to_process[x].first; int current_index = order_to_process[x].second; int current_down_index = current_index + 1; int current_up_index = current_index - 1; while (current_down_index < n){ if (a[current_down_index][j] >= current_value){ break; } else { current_down_index = max_down[current_down_index][j]; } } while (current_up_index >= 0){ if (a[current_up_index][j] >= current_value){ break; } else { current_up_index = min_up[current_up_index][j]; } } max_down[current_index][j] = current_down_index; min_up[current_index][j] = current_up_index; } } //vector<vector<int> > min_left_seg_trees (vector<vector<int> > (m, vector<int> (2 * n, 0))); //vector<vector<int> > min_up_seg_trees (vector<vector<int> > (n, vector<int> (2 * m, 0))); //vector<vector<int> > max_right_seg_trees (vector<vector<int> > (m, vector<int> (2 * n, 0))); //vector<vector<int> > max_down_seg_trees (vector<vector<int> > (n, vector<int> (2 * m, 0))); for (int i = 0; i < n; i++){ for (int j = 0; j < m; j++){ //updateMaxSegTree(min_left_seg_trees[j], i, min_left[i][j]); //updateMinSegTree(max_right_seg_trees[j], i, max_right[i][j]); //updateMaxSegTree(min_up_seg_trees[i], j, min_up[i][j]); //updateMinSegTree(max_down_seg_trees[i], j, max_down[i][j]); } } vector<vector<vector<int> > > min_left_precomputed(m, vector<vector<int> > (n, vector<int>())); for (int j = 0; j < m; j++){ for (int i1 = 0; i1 < n; i1++){ min_left_precomputed[j][i1].push_back(min_left[i1][j]); for (int d = 1; i1 + d < n; d++){ min_left_precomputed[j][i1].push_back(max(min_left[i1 + d][j], min_left_precomputed[j][i1][d - 1])); } } } for (int r1 = 1; r1 < n - 1; r1++){ for (int c1 = 1; c1 < m - 1; c1++){ if (b){ break; } int right = max_right[r1][c1 - 1]; for (int r2 = r1; r2 < n - 1; r2++){ right = min(right, max_right[r2][c1 - 1]); int down = max_down[r1 - 1][c1]; int up = min_up[r2 + 1][c1]; for (int c2 = c1; c2 < m - 1 && c2 < right; c2++){ down = min(down, max_down[r1 - 1][c2]); up = max(up, min_up[r2 + 1][c2]); if (down > r2){ if (up < r1){ if (min_left_precomputed[c2 + 1][0].size() == 0){ for (int i1 = 0; i1 < n; i1++){ min_left_precomputed[c2 + 1][i1].push_back(min_left[i1][c2 + 1]); for (int d = 1; i1 + d < n; d++){ min_left_precomputed[c2 + 1][i1].push_back(max(min_left[i1 + d][c2 + 1], min_left_precomputed[c2 + 1][i1][d - 1])); } } } if (min_left_precomputed[c2 + 1][r1][r2 - r1] < c1){ total++; } } else{ b = true; break; } } else{ //b = true; break; } } } } } return total; }

Compilation message (stderr)

split.cpp:2:10: fatal error: rect.h: No such file or directory
    2 | #include "rect.h"
      |          ^~~~~~~~
compilation terminated.