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By now, I have used the following algorithm for finding the strongly connected components of a graph.

  1. call DFS(G) to compute the finishing time f[v] for every vertex v, sort the vertices of G in decreasing order of their finishing time;

  2. compute the transpose GT of G;

  3. Perform another DFS on G, this time in the main for-loop we go through the vertices of G in the decreasing order of f[v];

  4. output the vertices of each tree in the DFS forest (formed by the second DFS) as a separate strongly connected component.

.

But I was wondering if it is possible to find all the strongly connected components in only one DFS.

Any help in this regard would be highly appreciated.

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2 Answers 2

up vote 2 down vote accepted

Check out, Algorithm Design Manual by Steven Skiena. It calculates SCC in one DFS. It's based on the concept of oldest reachable vertex.

Initialize each vertex's reachable vertex and SCComponent# to itself in the beginning.

low[i] = i;
scc[i] = -1;

Do a DFS on the digraph, you are interested only in back edges and cross edges because these two edges will tell you if you've encountered a back edge and entering 1 component from another.

  int edge_classification(int x, int y)
  {
    if (parent[y] == x) return(TREE);
    if (discovered[y] && !processed[y]) return(BACK);
    if (processed[y] && (entry_time[y]>entry_time[x])) return(FORWARD);
    if (processed[y] && (entry_time[y]<entry_time[x])) return(CROSS);
     printf("Warning: unclassified edge (%d,%d)\n",x,y);
  }

So when you encounter these edges, you set reachable vertex[] recursively, based on the entry times. if (class == BACK) { if (entry_time[y] < entry_time[ low[x] ] ) low[x] = y; }

if (class == CROSS) 
{
            if (scc[y] == -1)  /* component not yet assigned */
                    if (entry_time[y] < entry_time[ low[x] ] )
                            low[x] = y;
}

A new strongly connected component is found whenever the lowest reachable vertex from vertex 'v' is itself (loop can say, a->b->c->a, lowest reachable vertex of a is a).

process_vertex_early(int v)
{
    push(&active,v);
}

After DFS for a vertex is complete (DFS for it's neighbors would have been completed too), check the lowest reachable vertex for it:

if (low[v] == v) 
{     /* edge (parent[v],v) cuts off scc */
          pop_component(v);
}

if (entry_time[low[v]] < entry_time[low[parent[v]]])
          low[parent[v]] = low[v];

pop_component(...) just pops from the stack until this component is found. If a->b->c->a is scanned the stack will have a(bottom)->b->c(top).. pop until vertex 'a' is seen. You get an SCC for 'a'..and similarly you get all connected components in one DFS.

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1071840 can u give me the link from where u read this material. I would like to go through complete topic as it has said some new things here. –  LAP Oct 24 '12 at 4:28
    

I found this on the Wikipedia page for Strongly connected component:

Kosaraju's algorithm, Tarjan's algorithm and the path-based strong component algorithm all efficiently compute the strongly connected components of a directed graph, but Tarjan's and the path-based algorithm are favoured in practice since they require only one depth-first search rather than two.

I think this quite answers your question :)

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