Minimal Ratio Tree

Time Limit: 2000/1000 MS (Java/Others)    Memory Limit: 32768/32768 K (Java/Others)

Total Submission(s): 3345    Accepted Submission(s): 1019

For a tree, which nodes and edges are all weighted, the ratio of it is calculated according to the following equation.










Given a complete graph of n nodes with all nodes and edges weighted, your task is to find a tree, which is a sub-graph of the original graph, with m nodes and whose ratio is the smallest among all the trees of m nodes in the graph.

Input contains multiple test cases. The first line of each test case contains two integers n (2<=n<=15) and m (2<=m<=n), which stands for the number of nodes in the graph and the number of nodes in the minimal ratio tree. Two zeros end the input. The next line
contains n numbers which stand for the weight of each node. The following n lines contain a diagonally symmetrical n×n connectivity matrix with each element shows the weight of the edge connecting one node with another. Of course, the diagonal will be all
0, since there is no edge connecting a node with itself.







All the weights of both nodes and edges (except for the ones on the diagonal of the matrix) are integers and in the range of [1, 100].



The figure below illustrates the first test case in sample input. Node 1 and Node 3 form the minimal ratio tree. 

3 2

30 20 10

0 6 2

6 0 3

2 3 0

2 2

1 1

0 2

2 0

0 0

1 3

1 2

题意描写叙述：



给出n个点的权值和这n个点之间的边的权值。从这n个点之中选出m个点使得这m个点的权值最大，这m个点的生成树中边的权值最小。即Ratio最小。依照升序输出这m个点。





解题思路：



首先n的范围是[2，15]，所以能够用dfs搜索使得Ratio最小的点。那么思路基本清晰：首先dfs，搜索全部的点选与不选所得到的最大的Ratio。假设当前状态下得到的Ratio比之前得到的Ratio要小，那么把当前状态的vis数组更新的答案ans数组中。

最后从1到n扫描ans数组就可以保证答案是升序。

參考代码：

#include<stack>

#include<queue>

#include<cmath>

#include<cstdio>

#include<cstring>

#include<iostream>

#include<algorithm>

#pragma commment(linker,"/STACK: 102400000 102400000")

using namespace std;

const double eps=1e-6;

const int INF=0x3f3f3f3f;

const int MAXN=20;

int n,m,mincost[MAXN],node[MAXN],edge[MAXN][MAXN];

bool vis[MAXN],used[MAXN],ans[MAXN];

double temp;

double prim()

{

    memset(mincost,0,sizeof(mincost));

    memset(used,false,sizeof(used));

    int s;

    for(int i=1; i<=n; i++)

        if(vis[i])

        {

            s=i;

            break;

        }

    for(int i=1; i<=n; i++)

    {

        mincost[i]=edge[s][i];

        used[i]=false;

    }

    used[s]=true;

    int res=0;

    int nodevalue=node[s];

    for(int j=1; j<n; j++)

    {

        int v=-1;

        for(int i=1; i<=n; i++)

            if(vis[i]&&!used[i]&&(v==-1||mincost[v]>mincost[i]))//vis[i]表示第i个点有没有被选中

                v=i;

        res+=mincost[v];

        nodevalue+=node[v];

        used[v]=true;

        for(int i=1; i<=n; i++)

            if(vis[i]&&!used[i]&&mincost[i]>edge[v][i])

                mincost[i]=edge[v][i];

    }

    return (res+0.0)/nodevalue;

}

void dfs(int pos,int num)

{

    if(num>m)

        return ;

    if(pos==n+1)

    {

        if(num!=m)

            return ;

        double tans=prim();

        if(tans<temp)

        {

            temp=tans;

            memcpy(ans,vis,sizeof(ans));

        }

        return ;

    }

    vis[pos]=true;//选择当前点

    dfs(pos+1,num+1);

    vis[pos]=false;//不选择当前点，消除标记

    dfs(pos+1,num);

}

int main()

{

#ifndef ONLINE_JUDGE

    freopen("in.txt","r",stdin);

#endif // ONLINE_JUDGE

    while(scanf("%d%d",&n,&m))

    {

        if(n==0&&m==0)

            break;

        for(int i=1; i<=n; i++)

            scanf("%d",&node[i]);

        for(int i=1; i<=n; i++)

            for(int j=1; j<=n; j++)

                scanf("%d",&edge[i][j]);

        temp=INF;

        dfs(1,0);

        bool flag=false;

        for(int i=1; i<=n; i++)

        {

            if(ans[i])

            {

                if(flag)

                    printf(" ");

                else

                    flag=true;

                printf("%d",i);

            }

        }

        printf("\n");

    }

    return 0;

}