Strongly connected
Time Limit: 1000ms
Memory Limit: 32768KB
This problem will be judged on HDU. Original ID: 463564-bit integer IO format: %I64d Java class name: Main
Give a simple directed graph with N nodes and M edges. Please tell me the maximum number of the edges you can add that the graph is still a simple directed graph. Also, after you add these edges, this graph must NOT be strongly connected.
A simple directed graph is a directed graph having no multiple edges or graph loops.
A strongly connected digraph is a directed graph in which it is possible to reach any node starting from any other node by traversing edges in the direction(s) in which they point.
A simple directed graph is a directed graph having no multiple edges or graph loops.
A strongly connected digraph is a directed graph in which it is possible to reach any node starting from any other node by traversing edges in the direction(s) in which they point.
Input
The first line of date is an integer T, which is the number of the text cases.
Then T cases follow, each case starts of two numbers N and M, 1<=N<=100000, 1<=M<=100000, representing the number of nodes and the number of edges, then M lines follow. Each line contains two integers x and y, means that there is a edge from x to y.
Then T cases follow, each case starts of two numbers N and M, 1<=N<=100000, 1<=M<=100000, representing the number of nodes and the number of edges, then M lines follow. Each line contains two integers x and y, means that there is a edge from x to y.
Output
For each case, you should output the maximum number of the edges you can add.
If the original graph is strongly connected, just output -1.
If the original graph is strongly connected, just output -1.
Sample Input
3 3 3 1 2 2 3 3 1 3 3 1 2 2 3 1 3 6 6 1 2 2 3 3 1 4 5 5 6 6 4
Sample Output
Case 1: -1 Case 2: 1 Case 3: 15
Source
解题:不错的题目,首先做有向图的强连通分量缩点,同时记录各个scc的点,那么可以想象下,我们把可以加的边都加进去,会导致全图分成两个完全图的强连通块,但是这两个块之间,只有一个到另一个块的边,这样保证全图不是一个SCC
所以这样需要找入度或出度为0的SCC
1 #include <bits/stdc++.h> 2 using namespace std; 3 using LL = long long; 4 const int INF = 0x3f3f3f3f; 5 const int maxn = 100010; 6 7 vector<int>g[maxn]; 8 stack<int>stk; 9 int dfn[maxn],low[maxn],belong[maxn],cnt[maxn],clk,scc; 10 int ind[maxn],oud[maxn]; 11 bool instack[maxn]; 12 void tarjan(int u) { 13 dfn[u] = low[u] = ++clk; 14 stk.push(u); 15 instack[u] = true; 16 for(int i = g[u].size()-1; i >= 0; --i) { 17 if(!dfn[g[u][i]]) { 18 tarjan(g[u][i]); 19 low[u] = min(low[u],low[g[u][i]]); 20 } else if(instack[g[u][i]]) 21 low[u] = min(low[u],dfn[g[u][i]]); 22 } 23 if(low[u] == dfn[u]) { 24 int v; 25 do { 26 instack[v = stk.top()] = false; 27 belong[v] = scc; 28 stk.pop(); 29 ++cnt[scc]; 30 } while(v != u); 31 ++scc; 32 } 33 } 34 int main() { 35 int kase,n,m,u,v,cs = 1; 36 scanf("%d",&kase); 37 while(kase--) { 38 scanf("%d%d",&n,&m); 39 for(int i = 0; i <= n; ++i) { 40 g[i].clear(); 41 dfn[i] = cnt[i] = 0; 42 ind[i] = oud[i] = 0; 43 } 44 for(int i = scc = 0; i < m; ++i) { 45 scanf("%d%d",&u,&v); 46 g[u].push_back(v); 47 } 48 for(int i = 1; i <= n; ++i) 49 if(!dfn[i]) tarjan(i); 50 for(int i = 1; i <= n; ++i){ 51 for(int j = g[i].size()-1; j >= 0; --j){ 52 if(belong[i] == belong[g[i][j]]) continue; 53 ++ind[belong[g[i][j]]]; 54 ++oud[belong[i]]; 55 } 56 } 57 int x = INF,y = n; 58 for(int i = 0; i < scc; ++i) 59 if(!ind[i] || !oud[i]) x = min(x,cnt[i]); 60 y -= x; 61 LL ret = (LL)x*(x - 1) + (LL)y*(y - 1) + (LL)x*y - m; 62 printf("Case %d: %I64d ",cs++,scc == 1?-1LL:ret); 63 } 64 return 0; 65 }