A group of commandos were assigned a critical task. They are to destroy an enemy headquarter. The enemy head quarter consists of several buildings and the buildings are connected by roads. The commandos must visit each building and place a bomb at the base of each building. They start their mission at the base of a particular building and from there they disseminate to reach each building. The commandos must use the available roads to travel between buildings. Any of them can visit one building after another, but they must all gather at a common place when their task in done. In this problem, you will be given the description of different enemy headquarters. Your job is to determine the minimum time needed to complete the mission. Each commando takes exactly one unit of time to move between buildings. You may assume that the time required to place a bomb is negligible. Each commando can carry unlimited number of bombs and there is an unlimited supply of commando troops for the mission.

Input

Input starts with an integer T (≤50), denoting the number of test cases.

The first line of each case starts with a positive integer N (1 ≤ N ≤ 100), where N denotes the number of buildings in the headquarter. The next line contains a positive integer R, where R is the number of roads connecting two buildings. Each of the next R lines contain two distinct numbers u v (0 ≤ u, v < N), this means there is a road connecting building u to building v. The buildings are numbered from 0 to N-1. The last line of each case contains two integers s d (0 ≤ s, d < N). Where s denotes the building from where the mission starts and d denotes the building where they must meet. You may assume that two buildings will be directly connected by at most one road. The input will be given such that, it will be possible to go from any building to another by using one or more roads.

Output

For each case, print the case number and the minimum time required to complete the mission.

Sample

Sample Input	Sample Output
Click to copy 2 4 3 0 1 2 1 1 3 0 3 2 1 0 1 1 0	Click to copy Case 1: 4 Case 2: 1

LOJ 1174 - Commandos

Problem summary:

Each test case will have a graph consisting of N buildings (nodes) and R roads (edges). Each road has one unit edge cost. The task is to determine the minimum time needed to place a bomb in each building given that the commandos will start their mission from a specific building s and reunite at a specific building d after finishing their mission. You have unlimited supply of commandos each having unlimited number of bombs.

Observations and Solution:

As the graph is not weighted, we can solve this problem using BFS. But how to minimize the time? It is easy to observe that using one commando to place bombs in all the buildings is not a good idea. Also we have unlimited supply of commando troops. So we can take N commandos and assign each commando for only one building and in this way we can get the optimal result. For example: A commando's task is to place a bomb in the building x. He will start from s and will go to x using the shortest path between s and x. After placing the bomb he will go to d using the shortest path between x and d. In this way all the commandos will take minimum time possible to finish their job. Among all these times, the maximum one will be the minimum time to complete the mission.

To implement the solution, we need to run two BFS. First BFS will start from s and calculate the costs of the shortest paths of all the buildings from s. Another BFS will start from d and find the costs of the shortest paths of all the buildings from d. The time needed to place bomb in a building will be the sum of its distances from s and d. For all the buildings i (0 ≤ i < N) we will take the maximum of those times:

answer = max(answer, distance_from_s[i] + distance_from_d[i]).

Helpful resources:

Code:

C++

#include <bits/stdc++.h>
using namespace std;

vector<bool> vis;
vector<int> dis_from_s, dis_from_d;
vector<vector<int> > graph;

void bfs(int node, vector<int>& dis)
{
    queue<int> q;
    vis[node] = true;
    q.push(node);

    while(!q.empty())
    {
        int u = q.front();
        q.pop();

        for(auto v: graph[u])
        {
            if(!vis[v])
            {
                vis[v] = true;
                dis[v] = dis[u]+1;
                q.push(v);
            }
        }
    }
}

int main()
{
    ios_base::sync_with_stdio(0);
    cin.tie(0);
    cout.tie(0);

    int t;
    cin>>t;

    for(int cs=1; cs<=t; cs++)
    {
        int n, r, s, d, ans = 0;
        cin>>n>>r;
        vis.assign(n, false);
        dis_from_s.assign(n, 0);
        dis_from_d.assign(n, 0);
        graph.assign(n, vector<int>());

        for(int i=0; i<r; i++)
        {
            int u, v;
            cin>>u>>v;
            graph[u].push_back(v);
            graph[v].push_back(u);
        }

        cin>>s>>d;
        bfs(s, dis_from_s);
        fill(vis.begin(), vis.end(), false);
        bfs(d, dis_from_d);

        for(int i=0; i<n; i++)
            ans = max(ans, dis_from_s[i]+dis_from_d[i]);

        cout<<"Case "<<cs<<": "<<ans<<"\n";
    }

    return 0;
}

Happy coding! :3

Tutorial source