POJ3259 Wormholes

Description

While exploring his many farms, Farmer John has discovered a number of amazing wormholes. A wormhole is very peculiar because it is a one-way path that delivers you to its destination at a time that is BEFORE you entered the wormhole! Each of FJ's farms comprises N (1 ≤ N ≤ 500) fields conveniently numbered 1..N, M (1 ≤ M ≤ 2500) paths, and W (1 ≤ W≤ 200) wormholes.

As FJ is an avid time-traveling fan, he wants to do the following: start at some field, travel through some paths and wormholes, and return to the starting field a time before his initial departure. Perhaps he will be able to meet himself :) .

To help FJ find out whether this is possible or not, he will supply you with complete maps to F (1 ≤ F ≤ 5) of his farms. No paths will take longer than 10,000 seconds to travel and no wormhole can bring FJ back in time by more than 10,000 seconds.

Input

Line 1: A single integer, F. F farm descriptions follow.
Line 1 of each farm: Three space-separated integers respectively: N, M, and W
Lines 2..M+1 of each farm: Three space-separated numbers (S, E, T) that describe, respectively: a bidirectional path between S and E that requires T seconds to traverse. Two fields might be connected by more than one path.
Lines M+2..M+W+1 of each farm: Three space-separated numbers (S, E, T) that describe, respectively: A one way path from S to E that also moves the traveler back T seconds.

Output

Lines 1..F: For each farm, output "YES" if FJ can achieve his goal, otherwise output "NO" (do not include the quotes).

Sample Input

Sample Output

NO

YES

Hint

For farm 1, FJ cannot travel back in time.
For farm 2, FJ could travel back in time by the cycle 1->2->3->1, arriving back at his starting location 1 second before he leaves. He could start from anywhere on the cycle to accomplish this.

『题解』

存在负权边时不能用Dijkstra算法求最短路。本题采用Bellman-Ford最短路算法判断负权回路。模板题冲冲冲。

『C++』

 #include <iostream>

 #include <vector>

 using namespace std;

 #define INF 0x7fffffff

 int FieldsN, dist[];

 struct Edge

 {

     int s, e;

     int t;

     Edge() {}

     Edge(int _s, int _e, int _t) :

         s(_s), e(_e), t(_t) {}

 };

 vector<Edge> edges;

 bool Bellmen_Ford(int v)

 {

     int s, e, t;

     int Size = edges.size();

     for (int k = ; k <= FieldsN; k++)

         dist[k] = INF;

     dist[v] = ;

     for (int k = ; k < FieldsN; k++) {

         for (int i = ; i < Size; i++) {

             s = edges[i].s;

             e = edges[i].e;

             t = edges[i].t;

             if (dist[s] != INF && dist[s] + t < dist[e])

                 dist[e] = dist[s] + t;

         }

     }

     for (int i = ; i < Size; i++) {

         s = edges[i].s;

         e = edges[i].e;

         t = edges[i].t;

         if (dist[s] + t < dist[e]) return true;

     }

     return false;

 }

 int main()

 {

     int F, M, W, S, E, T;

     cin >> F;

     while (F--) {

         edges.clear();

         cin >> FieldsN >> M >> W;

         while (M--) {

             cin >> S >> E >> T;

             edges.push_back(Edge(S, E, T));

             edges.push_back(Edge(E, S, T));

         }

         while (W--) {

             cin >> S >> E >> T;

             edges.push_back(Edge(S, E, -T));

         }

         if (Bellmen_Ford()) printf("YES\n");

         else printf("NO\n");

     }

     //system("pause");

     return ;

 }

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