Submission #296130

#TimeUsernameProblemLanguageResultExecution timeMemory
296130MoNsTeR_CuBeSplit the Attractions (IOI19_split)C++17
53 / 100
216 ms30840 KiB
#include "split.h" #include <bits/stdc++.h> using namespace std; vector< int > U; vector< int > unionSize; int getParents(int a){ if(U[a] == a) return a; else return U[a] = getParents(U[a]); } void Union(int a, int b){ if(getParents(a) == getParents(b)) return; unionSize[getParents(b)] += unionSize[getParents(a)]; U[getParents(a)] = getParents(b); } void compute_tree(int root, int last, vector< bool > &visited, vector< vector< int > > &Graph, vector< vector< int > > &Tree, vector< pair<int, int> > &back_edges){ visited[root] = true; for(int a : Graph[root]){ if(visited[a] && a != last){ back_edges.push_back({root, a}); continue; }else if(visited[a]) continue; Tree[root].push_back(a); Tree[a].push_back(root); compute_tree(a,root, visited, Graph, Tree, back_edges); } } void compute_subtrees(int root, int last, vector< vector< int > > &Tree, vector< int > &dp){ //cout << "ROOT " << root << ' ' << last << endl; for(int a : Tree[root]){ if(a == last){ continue; } else{ compute_subtrees(a, root, Tree, dp); dp[root] += dp[a]; } } } int find_centroid(int root, int last, vector< vector< int > > &Tree, vector< int > &dp, int &n){ for(int a : Tree[root]){ if(a == last) continue; if(dp[a] > n/2){ return find_centroid(a, root, Tree,dp,n); } } return root; } void compute_centroid_graph(int root, vector< vector< int > > &Tree, vector< vector< int > > &centroidGraph,vector< bool > &visitedCentroid, const int &centroid, vector< pair<int, int> > &centroidEdges){ visitedCentroid[root] = true; for(int a : Tree[root]){ if(visitedCentroid[a]) continue; if(a == centroid){ centroidEdges.push_back({a,root}); continue; } //cout << "ROOT " << root << " " << a << endl; centroidGraph[a].push_back(root); centroidGraph[root].push_back(a); compute_centroid_graph(a, Tree, centroidGraph, visitedCentroid, centroid, centroidEdges); } } int computeSizeSubtree(int root, vector< vector< int > > &centroidGraph, vector< bool > &visitedSubset, const int bigRoot){ int tot = 1; visitedSubset[root] = true; Union(root, bigRoot); //cout << "SUBTREE " << root << endl; //cout << centroidGraph[root].size() << endl; for(int a : centroidGraph[root]){ if(visitedSubset[a]) continue; //cout << root << ' ' << a << endl; tot += computeSizeSubtree(a, centroidGraph, visitedSubset, bigRoot); } return tot; } void colourGraph(int root, vector< vector< int > > &centroidGraph, vector< bool > &visitedColouring, vector< int > &ans, const int colour, int &total){ if(total == 0) return; visitedColouring[root] = true; ans[root] = colour; total--; //cout << "COLOURING " << root << " in " << colour << endl; if(total == 0) return; for(int a : centroidGraph[root]){ if(visitedColouring[a]) continue; colourGraph(a, centroidGraph, visitedColouring, ans, colour, total); } } vector<int> find_split(int n, int a, int b, int c, vector<int> p, vector<int> q) { vector< pair<int, int> > sorting = {{a,1},{b,2},{c,3}}; sort(sorting.begin(), sorting.end()); a = sorting[0].first; b = sorting[1].first; c = sorting[2].first; vector< vector< int > > Graph(n); vector< bool > visited(n,false); for(int i = 0; i < (int)p.size(); i++){ Graph[p[i]].push_back(q[i]); Graph[q[i]].push_back(p[i]); } //TRANSFORM THE GRAPH TO A TREE vector< vector< int > > Tree(n); vector< pair<int, int> > back_edges; //cout << "OK" << endl; compute_tree(0,-1, visited, Graph, Tree, back_edges); //cout << "OK" << endl; //for(auto e: back_edges) cout << e.first << ' ' << e.second << endl; //COMPUTE SIZE OF SUBTREES vector< int > dp(n, 1); compute_subtrees(0,-1,Tree,dp); //FIND THE CENTROID int centroid = find_centroid(0,-1, Tree, dp,n); //cout << "CENTROID " << centroid << endl; //COMPUTE CENTROID GRAPH vector< vector< int > > centroidGraph(n); vector< bool > visitedCentroid(n,false); vector< pair<int, int> > centroidEdges; for(int i = 0; i < n; i++){ if(!visitedCentroid[i] && i != centroid){ compute_centroid_graph(i,Tree, centroidGraph,visitedCentroid, centroid, centroidEdges); } } //COMPUTE SIZE AND ROOT OF EACH SUBSET U.resize(n); unionSize.resize(n,1); for(int i = 0; i < n; i++) U[i] = i; vector< pair<int, int> > sizeAndRootOfSubset; vector< bool > visitedSubset(n, false); for(int i = 0; i < n; i++){ if(!visitedSubset[i]){ int size = computeSizeSubtree(i, centroidGraph, visitedSubset, i); sizeAndRootOfSubset.push_back({size,i}); //cout << "SIZE " << size << ' ' << "ROOT " << i << endl; } } //cout << "OK" << endl; //CHECK IF ONE OF THEM IS SMALLER THAN A sort(sizeAndRootOfSubset.begin(), sizeAndRootOfSubset.end()); if(sizeAndRootOfSubset.back().first >= a){ vector< int > ans(n,-1); vector< bool > visitedColouring(n,false); colourGraph(sizeAndRootOfSubset.back().second, centroidGraph, visitedColouring, ans, sorting[0].second, a); //ADD EDGES TO CENTROID for(auto e : centroidEdges){ centroidGraph[e.first].push_back(e.second); centroidGraph[e.second].push_back(e.first); } int left = b; //cout << left << endl; colourGraph(centroid, centroidGraph, visitedColouring, ans, sorting[1].second, left); //REPLACE ALL -1 by 3 for(int &A : ans){ if(A == -1) A=sorting[2].second; } return ans; } for(auto e : back_edges){ if(e.first == centroid || e.second == centroid) continue; centroidGraph[e.first].push_back(e.second); centroidGraph[e.second].push_back(e.first); if(getParents(e.first) == getParents(e.second)){ continue; } else{ Union(e.first, e.second); if(unionSize[getParents(e.first)] >= a){ vector< int > ans(n,-1); vector< bool > visitedColouring(n,false); colourGraph(getParents(e.first), centroidGraph, visitedColouring, ans, sorting[0].second, a); for(auto E : centroidEdges){ centroidGraph[E.first].push_back(E.second); centroidGraph[E.second].push_back(E.first); } int left = b; colourGraph(centroid, centroidGraph, visitedColouring, ans, sorting[1].second, left); //REPLACE ALL -1 by 3 for(int &A : ans){ if(A == -1) A=sorting[2].second; } return ans; } } } vector< int > ans(n); return ans; }
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...
#Verdict Execution timeMemoryGrader output
Fetching results...