强连通分量+缩点(poj2553)
http://poj.org/problem?id=2553
The Bottom of a Graph
Time Limit: 3000MS | Memory Limit: 65536K | |
Total Submissions: 8748 | Accepted: 3625 |
Description
We will use the following (standard) definitions from graph theory. Let V be a nonempty and finite set, its elements being called vertices (or nodes). Let E be a subset of the Cartesian product V×V, its elements being called edges.
Then G=(V,E) is called a directed graph.
Let n be a positive integer, and let p=(e1,...,en) be a sequence of length n of edges ei∈E such that ei=(vi,vi+1) for a sequence of vertices (v1,...,vn+1). Then p is called a path from vertex v1 to vertex vn+1 inG and we say that vn+1 is reachable from v1, writing (v1→vn+1).
Here are some new definitions. A node v in a graph G=(V,E) is called a sink, if for every node w in G that is reachable from v, v is also reachable from w. The bottom of a graph is the subset of all nodes that are sinks, i.e., bottom(G)={v∈V|∀w∈V:(v→w)⇒(w→v)}. You have to calculate the bottom of certain graphs.
Let n be a positive integer, and let p=(e1,...,en) be a sequence of length n of edges ei∈E such that ei=(vi,vi+1) for a sequence of vertices (v1,...,vn+1). Then p is called a path from vertex v1 to vertex vn+1 inG and we say that vn+1 is reachable from v1, writing (v1→vn+1).
Here are some new definitions. A node v in a graph G=(V,E) is called a sink, if for every node w in G that is reachable from v, v is also reachable from w. The bottom of a graph is the subset of all nodes that are sinks, i.e., bottom(G)={v∈V|∀w∈V:(v→w)⇒(w→v)}. You have to calculate the bottom of certain graphs.
Input
The input contains several test cases, each of which corresponds to a directed graph G. Each test case starts with an integer number v, denoting the number of vertices of G=(V,E), where the vertices will be identified by the integer
numbers in the set V={1,...,v}. You may assume that 1<=v<=5000. That is followed by a non-negative integer e and, thereafter, e pairs of vertex identifiers v1,w1,...,ve,we with
the meaning that (vi,wi)∈E. There are no edges other than specified by these pairs. The last test case is followed by a zero.
Output
For each test case output the bottom of the specified graph on a single line. To this end, print the numbers of all nodes that are sinks in sorted order separated by a single space character. If the bottom is empty, print an empty line.
Sample Input
3 3 1 3 2 3 3 1 2 1 1 2 0
Sample Output
1 3 2
求出连通块里的点满足下面条件:所有能到达点v的点w,v也能到达所有的w,因此要求的是联通块,然后缩点,求出度为零的连通块里的点,然后按照升序输出元素;
程序:
#include"stdio.h" #include"string.h" #include"queue" #include"stack" #include"iostream" #define M 5009 #define inf 100000000 using namespace std; struct node { int v; node(int vv) { v=vv; } }; vector<node>edge[M]; stack<int>q; int use[M],low[M],dfn[M],belong[M],num,index,in[M],out[M]; void tarjan(int u) { dfn[u]=low[u]=++index; q.push(u); use[u]=1; for(int i=0;i<(int)edge[u].size();i++) { int v=edge[u][i].v; if(!dfn[v]) { tarjan(v); low[u]=min(low[u],low[v]); } else if(use[v]) { low[u]=min(low[u],dfn[v]); } } if(dfn[u]==low[u]) { num++; int p; do { p=q.top(); q.pop(); use[p]=0; belong[p]=num; }while(p!=u); } } void slove(int n) { num=index=0; memset(use,0,sizeof(use)); memset(dfn,0,sizeof(dfn)); for(int i=1;i<=n;i++) if(!dfn[i]) tarjan(i); } int main() { int n,m,i; while(scanf("%d",&n),n) { scanf("%d",&m); for(i=1;i<=n;i++) edge[i].clear(); for(i=1;i<=m;i++) { int u,v; scanf("%d%d",&u,&v); edge[u].push_back(node(v)); } slove(n); if(num==1) { for(i=1;i<=n;i++) { if(i==1) printf("%d",i); else printf(" %d",i); } printf("\n"); continue; } memset(in,0,sizeof(in)); memset(out,0,sizeof(out)); for(int u=1;u<=n;u++) { for(int j=0;j<(int)edge[u].size();j++) { int v=edge[u][j].v; if(belong[u]!=belong[v]) { out[belong[u]]++; in[belong[v]]++; } } } int ff=0; for(i=1;i<=n;i++) { if(!out[belong[i]]) { if(ff==0) printf("%d",i); else printf(" %d",i); ff++; } } printf("\n"); } }