I was reading the graph algorithms about BFS and DFS. When I was analyzing the algorithm for finding strongly connected component in a Graph through DFS, a doubt came to my mind. For finding the strongly connected component, what book(Coremen)does, first it ran the DFS on the Graph in order to get the finish time of the vertices then again ran the DFS on the transpose of the graph in decreasing order of the finish time which we got from the first DFS. But I am not able to grasp why the second DFS must be run according to finish time. What I mean is that even if we directly run the DFS (ignoring the finish time) on the transpose of the graph, could it also have given us the connected components because by doing the transpose we have already blocked the path to other components.
Edit- Here's some good in-depth videos from stanford university on the topic:
http://openclassroom.stanford.edu/MainFolder/CoursePage.php?course=IntroToAlgorithms (See 6. CONNECTIVITY IN DIRECTED GRAPHS)
It's possible that you would incorrectly identify the entire graph as a single strongly connected component(SCC) if you don't run the second dfs according to decreasing finish times of the first dfs.
Notice that in my example, node
Now, if you ran the second dfs starting with node
If you look at cormens code for DFS,
if you didn't use decreasing finish time, then line 6 of DFS would only be true once, because DFS-VISIT would visit the entire graph recursively. This produces a single tree in the depth first forest, and each tree is an SCC. The reasoning for a single tree is because a tree is identified by its root node having a nil predecessor.