Submission #339175

#TimeUsernameProblemLanguageResultExecution timeMemory
339175bigDuckRace (IOI11_race)C++14
0 / 100
4 ms5100 KiB
#include "race.h" #include<bits/stdc++.h> using namespace std; #define INIT ios_base :: sync_with_stdio(false); cin.tie(NULL); cout.tie(NULL);mt19937 rng(chrono::steady_clock::now().time_since_epoch().count()); #define mp make_pair #define pb push_back #define ft first #define sc second #define ll long long #define pii pair<int, int> #define count_bits __builtin_popcount int n, k; vector<pii> g[200010]; bool v[200010]; int res=1e9; int subtask_2(int s, int l, int h){ int res=1e9; if(l>k){ v[s]=false; return res; } if(l==k){ v[s]=false; return h; } v[s]=true; for(pii pr:g[s]){ int u=pr.ft, d=pr.sc; if(!v[u]){ res=min(subtask_2(u, l+d, h+1), res); } } v[s]=false; return res; } map<pii, int> h; int sz[200010]; void build_sz(int s){ v[s]=true; sz[s]=1; for(pii u:g[s]){ if(!v[u.ft]){ build_sz(u.ft); sz[s]+=sz[u.ft]; } } v[s]=false; return; } pii find_centroids(int s, int total){ v[s]=true; int mx=0, u=s; for(pii node:g[s]){ if( (sz[node.ft]>mx) && (!v[node.ft]) ){ mx=sz[node.ft]; u=node.ft; } if( (v[node.ft]) && ( (total-sz[s])>mx ) ){ mx=(total-sz[s]); u=node.ft; } } pii res; if(!v[u]){res=find_centroids(u, total);} else{ res={u, s}; } v[s]=false; return res; } multiset<pii> k1, k2; void path(int s, int l, int h, int tp){ if(l>k){ return; } if(tp==1){ k1.insert({l, h}); } else{ k2.insert({l, h}); } if(l==k){return;} v[s]=true; for(auto pr:g[s]){ int u=pr.ft, d=pr.sc; if(!v[u]){ path(u, l+d, h+1, tp); } } v[s]=false; return; } void remove_edge(pii e, int d){ int u=e.ft, v=e.sc; g[u].erase(find(g[u].begin(), g[u].end(),mp(v, d) )); g[v].erase(find(g[v].begin(), g[v].end(),mp(u, d) )); } void combine(int d){ while((!k1.empty()) && (!k2.empty())){ auto it1=k1.end(); it1--; int s1=it1->ft, pl1=it1->sc; k1.erase(it1); while( (((k2.begin()->ft)+s1)<(k-d)) && (!k2.empty()) ){ k2.erase(k2.begin()); } if(k2.empty()){ break; } int s2=(*k2.begin()).ft, pl2=(*k2.begin()).sc; if( (s2+s1)==(k-d) ){ res=min(res, pl1+pl2); } } } void subtask_4(){ queue<int> forest; forest.push(1); while(!forest.empty()){ int node=forest.front(); forest.pop(); build_sz(node); //cout<<node<<"\n"<<flush; if(sz[node]==1){continue;} pii e=find_centroids(node, sz[node]); int d=h[e]; //cout<<e.ft<<" "<<e.sc<<"\n"<<flush; //partea din stanga: k1.insert({0, 1}); v[e.sc]=true;v[e.ft]=false; path(e.ft, 0, 1, 1); v[e.sc]=false; //partea din dreapta: k2.insert({0, 1}); v[e.ft]=true; v[e.sc]=false; path(e.sc, 0, 1, 2); v[e.ft]=false; //combinarea: combine(d); remove_edge(e, d); forest.push(e.ft); forest.push(e.sc); } } int best_path(int N, int K, int H[][2], int L[]) { n=N; k=K; for(int i=0; i<(n-1); i++){ int u=H[i][0]+1, v=H[i][1]+1, d=L[i]; g[u].pb({v, d}); g[v].pb({u, d}); h[{u, v} ]=d; h[{v, u} ]=d; } /*if( (k<=100) ){ subtask_3(1);} else{ if(n<=1000){ for(int i=1; i<=n; i++){ res=min(res, subtask_2(i, 0, 1)); } } else{ subtask_4(); } }*/ subtask_4(); k1.clear(); k2.clear(); if(res==(1e9)){ return -1; } return res-1; }
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