competitive
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verify/aizu-GRL_1_A.test.cpp
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- Last update: 2025-05-09 08:40:27+00:00
- Problem: https://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=GRL_1_A&lang=ja
Depends on
Code
#define PROBLEM "https://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=GRL_1_A&lang=ja"
#include "template"
#include "graphtemplate"
#include "dijkstra"
int main() { IO();
int T=1;
// cin >> T;
while (T--) solve();
}
void solve() {
int n, m, s; cin >> n >> m >> s;
graph<ll, true, true> g(n);
g.read(m, 0);
vll d = dijkstra(g, s);
range(i, d) {
if (i == numeric_limits<ll>::max()) {
cout << "INF" << nl;
} else {
cout << i << nl;
}
}
}#line 1 "verify/aizu-GRL_1_A.test.cpp"
#define PROBLEM "https://judge.u-aizu.ac.jp/onlinejudge/description.jsp?id=GRL_1_A&lang=ja"
#line 2 "util/template.hpp"
#ifdef poe
#define debug(x) cerr<<#x<<": "<<x<<endl
#else
#define debug(x)
// #pragma GCC target("arch=skylake-avx512")
// #pragma GCC target("avx2")
// #pragma GCC optimize("O3")
// #pragma GCC optimize("unroll-loops")
#endif
#include<bits/stdc++.h>
using namespace std;
using ll=long long;
using ull=unsigned long long;
using ld=long double;
using pi=pair<int,int>;
using pll=pair<ll,ll>;
using str=string;
template<class T>using vec=vector<T>;
using vi=vec<int>;using vvi=vec<vi>;using vvvi=vec<vvi>;using vvvvi=vec<vvvi>;using vvvvvi=vec<vvvvi>;
using vll=vec<ll>;using vvll=vec<vll>;using vvvll=vec<vvll>;using vvvvll=vec<vvvll>;using vvvvvll=vec<vvvvll>;
using vpi=vec<pi>;using vvpi=vec<vpi>;using vvvpi=vec<vvpi>;using vvvvpi=vec<vvvpi>;using vvvvvpi=vec<vvvvpi>;
using vpll=vec<pll>;using vvpll=vec<vpll>;using vvvpll=vec<vvpll>;using vvvvpll=vec<vvvpll>;using vvvvvpll=vec<vvvvpll>;
template<class T>using pq=priority_queue<T,vector<T>>;
template<class T>using pqg=priority_queue<T,vector<T>,greater<T>>;
#define rep(i,n) for(int i=0;i<(int)(n);i++)
#define rep1(i,n) for(int i=1;i<=(int)(n);i++)
#define per(i,n) for(int i=(int)(n)-1;0<=i;i--)
#define per1(i,n) for(int i=(int)(n);0<i;i--)
#define range(i,x) for(auto&i:x)
#define range2(i,j,x) for(auto&[i,j]:x)
#define all(x) (x).begin(),(x).end()
#define rall(x) (x).rbegin(),(x).rend()
#define Sort(x) sort((x).begin(),(x).end())
#define troS(x) sort((x).rbegin(),(x).rend())
#define Reverse(x) reverse((x).begin(),(x).end())
#define uniq(x) sort((x).begin(),(x).end());(x).erase(unique((x).begin(),(x).end()),(x).end())
#define nextp(x) next_permutation((x).begin(),(x).end())
#define nextc(x,k) next_combination((x).begin(),(x).end(),k)
#define bit(x,i) (((x)>>(i))&1)
#define pf push_front
#define pb push_back
#define df pop_front
#define db pop_back
#define fi first
#define se second
#define elif else if
#define Yes cout<<"Yes"<<'\n'
#define No cout<<"No"<<'\n'
#define YN(x) cout<<((x)?"Yes":"No")<<'\n'
#define O(x) cout<<(x)<<'\n'
#define ismid(a,b,c) ((a)<=(b)&&(b)<(c))
template<class S,class T>bool chmin(S&a,T b){if(a>b){a=b;return true;}return false;}
template<class S,class T>bool chmax(S&a,T b){if(a<b){a=b;return true;}return false;}
template<class T>bool next_combination(T l,T r,int k){T m=l+k;if(l==r||l==m||r==m)return false;T t=m;while(l!=t){t--;if(*t<*(r-1)){T d=m;while(*t>=*d)d++;iter_swap(t,d);rotate(t+1,d+1,r);rotate(m,m+(r-d)-1,r);return true;}}rotate(l,m,r);return false;}
template<class T>T Min(T a,T b){return a<b?a:b;}
template<class T,class...Args>T Min(T a,T b,Args...args){return Min(Min(a,b),args...);}
template<class T>T Max(T a,T b){return a>b?a:b;}
template<class T,class...Args>T Max(T a,T b,Args...args){return Max(Max(a,b),args...);}
template<class T>T Sum(T a){return a;}
template<class T,class... Args>T Sum(T a,Args... args){return a+Sum(args...);}
template<class T>T Max(const vector<T>&v){return *max_element(all(v));}
template<class T>T Min(const vector<T>&v){return *min_element(all(v));}
template<class T>T Sum(const vector<T>&v){return accumulate(all(v),T(0));}
template<class S,class T>T Max(const pair<S,T>&p){return max(p.first,p.second);}
template<class S,class T>T Min(const pair<S,T>&p){return min(p.first,p.second);}
template<class S,class T>T Sum(const pair<S,T>&p){return p.first+p.second;}
template<class S,class T>istream&operator>>(istream&s,pair<S,T>&p){s>>p.first>>p.second;return s;}
template<class S,class T>ostream&operator<<(ostream&s,pair<S,T>&p){s<<p.first<<' '<<p.second<<'\n';return s;}
template<class T>istream&operator>>(istream&s,vector<T>&v){for(auto&i:v)s>>i;return s;}
template<class T>ostream&operator<<(ostream&s,vector<T>&v){for(auto&i:v)s<<i<<' ';s<<'\n';return s;}
template<class F>long long bsearch(long long ok,long long ng,F&f){while(abs(ok-ng)>1){long long mid=(ok+ng)/2;if(f(mid))ok=mid;else ng=mid;}return ok;}
const int dxy[5]={0,1,0,-1,0};
const int dx[8]={0,1,0,-1,1,1,-1,-1};
const int dy[8]={1,0,-1,0,1,-1,1,-1};
#define nl '\n'
#define sp ' '
#define inf ((1<<30)-(1<<15))
#define INF (1LL<<61)
#define mod 998244353
void IO() {
ios::sync_with_stdio(false);
cin.tie(nullptr);
cout<<fixed<<setprecision(30);
}
void solve();
#line 3 "graph/graphtemplate.hpp"
using namespace std;
// 辺の構造体 edge(from, to, cost, id)
template<class T = int>
struct edge {
int from, to;
T cost;
int id;
};
// 頂点の構造体 vector<edge<T>>
template<class T = int>
using edges = vector<edge<T>>;
// グラフの構造体 graph<T, directed, weighted>
template <class T = int, bool directed = false, bool weighted = false>
struct graph {
bool isdirected, isweighted;
edges<T> _edges;
vector<edges<T>> data;
T sumcost;
graph() = default;
// 頂点数 n のグラフを作成する
graph(int n) : isdirected(directed), isweighted(weighted), data(n), sumcost(T{}) {}
// from から to へ辺を追加する
void add_edge(int from, int to, T cost = 1, int id = -1) {
if (id == -1) id = _edges.size();
data[from].push_back(edge<T>(from, to, cost, id));
_edges.push_back(edge<T>(from, to, cost, id));
if (!isdirected) {
data[to].push_back(edge<T>(to, from, cost, id));
}
sumcost += cost;
}
// 辺を追加する
void add_edge(edge<T> _e) {
add_edge(_e.from, _e.to, _e.cost, _e.id);
}
// 標準入力から辺を読み込む
void read(int m, int indexed = 1) {
for (int i=0; i<m; i++) {
int from, to;
T cost = 1;
cin >> from >> to;
if (isweighted) cin >> cost;
add_edge(from - indexed, to - indexed, cost);
}
}
// 頂点数を返す
int size() {
return data.size();
}
// 頂点を返す
edges<T> operator[](int k) {
return data[k];
}
vector<int> path_to_vertex(edges<T>& _e) {
vector<int> re;
if (_e.size() == 0) {
return re;
}
if (_e.size() == 1) {
re.push_back(_e[0].from);
re.push_back(_e[0].to);
return re;
}
int x=_e[0].from,y=_e[0].to;
if (x==_e[1].to || x == _e[1].from) swap(x, y);
re.push_back(x);
for (int i=1; i<_e.size(); i++) {
re.push_back(y);
x = _e[i].to;
if (x == y) x = _e[i].from;
swap(x, y);
}
return re;
}
edges<T> vetex_to_path (vector<int>& v){
edges<T> re;
for (int i=0; i+1<v.size(); i++) {
for (auto& _e : this[v[i]]) {
if (_e.to == v[i+1]) {
re.push_back(_e);
break;
}
}
}
return re;
}
};
#line 4 "graph/dijkstra.hpp"
using namespace std;
// ダイクストラ法を用いて単一始点最短経路を求める ただし、負辺が存在しないこと O(m log n)
template<class T = int, bool directed = false, bool weighted = true>
vector<T> dijkstra(graph<T, directed, weighted>& g, int from = 0) {
vector<T> dist(g.size(), numeric_limits<T>::max()); dist[from] = T{};
vector<bool> visited(g.size());
priority_queue<pair<T, int>, vector<pair<T, int>>, greater<pair<T, int>>> q;
q.push({T{}, from});
while (!q.empty()) {
auto [t, x] = q.top(); q.pop();
if (visited[x]) continue;
visited[x] = true;
for (auto& _e : g[x]) {
int y = _e.to;
if (dist[x] + _e.cost < dist[y]) {
dist[y] = dist[x] + _e.cost;
q.push({dist[y], y});
}
}
}
return dist;
}
// ダイクストラ法を用いて二点間最短経路を求める ただし、負閉路が存在しないこと O(m log n)
template<class T = int, bool directed = false, bool weighted = true>
T dijkstra(graph<T, directed, weighted>& g, int from, int to) {
return dijkstra(g, from)[to];
}
#line 5 "verify/aizu-GRL_1_A.test.cpp"
int main() { IO();
int T=1;
// cin >> T;
while (T--) solve();
}
void solve() {
int n, m, s; cin >> n >> m >> s;
graph<ll, true, true> g(n);
g.read(m, 0);
vll d = dijkstra(g, s);
range(i, d) {
if (i == numeric_limits<ll>::max()) {
cout << "INF" << nl;
} else {
cout << i << nl;
}
}
}