POJ 3259 Wormholes (最短路)

时间:2023-03-09 10:05:14
POJ 3259 Wormholes (最短路)
Wormholes
Time Limit: 2000MS   Memory Limit: 65536K
Total Submissions: 34302   Accepted: 12520

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..NM (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, FF farm descriptions follow. 
Line 1 of each farm: Three space-separated integers respectively: NM, and W 
Lines 2..M+1 of each farm: Three space-separated numbers (SET) 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 (SET) 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

2

3 3 1

1 2 2

1 3 4

2 3 1

3 1 3

3 2 1

1 2 3

2 3 4

3 1 8

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.
以每个点为起点跑一次,检测是否有负环。
 #include <iostream>

 #include <cstdio>

 using    namespace    std;

 const    int    INF = 0xfffffff;

 const    int    SIZE = ;

 int    D[];

 int    N,M,W,F;

 struct    Node

 {

     int    from,to,cost;

 }G[SIZE];

 bool    Bellman_Ford(int);

 bool    relax(int,int,int);

 int    main(void)

 {

     scanf("%d",&F);

     while(F --)

     {

         scanf("%d%d%d",&N,&M,&W);

         int    i = ;

         while(i <  * M)

         {

             scanf("%d%d%d",&G[i].from,&G[i].to,&G[i].cost);

             i ++;

             G[i] = G[i - ];

             swap(G[i].from,G[i].to);

             i ++;

         }

         while(i < W + M * )

         {

             scanf("%d%d%d",&G[i].from,&G[i].to,&G[i].cost);

             G[i].cost = -G[i].cost;

             i ++;

         }

         bool    flag = true;

         for(int i = ;i <= N;i ++)

             if(!Bellman_Ford(i))

             {

                 puts("YES");

                 flag = false;

                 break;

             }

         if(flag)

             puts("NO");

     }

     return    ;

 }

 bool    Bellman_Ford(int s)

 {

     fill(D,D + ,INF);

     D[s] = ;

     bool    update;

     for(int i = ;i < N - ;i ++)

     {

         update = false;

         for(int i = ;i < M *  + W;i ++)

             if(relax(G[i].from,G[i].to,G[i].cost))

                 update = true;

         if(!update)

             break;

     }

     for(int i = ;i < M *  + W;i ++)

         if(relax(G[i].from,G[i].to,G[i].cost))

             return    false;

     return    true;

 }

 bool    relax(int from,int to,int cost)

 {

     if(D[to] > D[from] + cost)

     {

         D[to] = D[from] + cost;

         return    true;

     }

     return    false;

 }

Bellman_Ford

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