# Counting Number of Paths (Length N) in Bipartite Graph

I am currently counting the number of paths of length \$n\$ in a bipartite graph by doing a depth first search (up to 10 levels). However, my implementation of this takes 5+ minutes to count 7 million paths of length 5 from a bipartite graph with 3000+ elements. I am looking for a more efficient way to do this counting problem, and I am wondering if there is any such algorithm in the literature.

These are undirected bipartite graphs, so there can be cycles in the paths.

My goal here is to count the number of paths of length \$n\$ in a bipartite graph of 1 million elements under a minute.

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Are you looking for paths from one source to one target? one source multiple targets? multiple source multiple targets? – amit Jun 30 '12 at 5:39
No requirements on the paths. They can have multiple sources and multiple targets. Paths with cycles are also counted. – swtdrgn Jun 30 '12 at 13:09

I agree with the first idea but it's not quite a BFS. In a BFS you go through each node once, here you can go a large number of times.
You have to keep 2 arrays (let's call it Cnt1, and Cnt2, Cnt1 is the number of times you have reached an element and you have a path of length i, and Cnt2 is the same but for length i + 1). First time all the elements are 0 in Cnt2 and 1 in Cnt1( because you have one path of length zero starting at each node).

Repeat N times:
Go through all the nodes
For the current node you go through all his connected nodes and for each you add at there position on Cnt2 the number of times you reached the current node in Cnt1.
When you finished all the nodes you just Copy Cnt2 in Cnt1 and make Cnt2 zero.
At the end you just add all the numbers of Cnt1 and that is the answer.

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Thanks. I actually tried this out and got a significant speed increase. – swtdrgn Jul 1 '12 at 11:11

Convert to a breadth-first search, and whenever you have 2 paths that lead to the same node at the same length, just keep track of how many such ways there are and not how you got there.

This will avoid a lot of repeated work and should provide a significant speedup. (If `n` is not small, there are better speedups, read on.)

My goal here is to count the number of paths of length `n` in a bipartite graph of 1 million elements under a minute.

Um, good luck?

An alternate approach to look into is if you take the adjacency matrix of the graph, and raise it to the n'th power, all of the entries of the matrix you get are the number of paths of length end starting in one place, ending in another. So you can take shortcuts like repeated squaring. Convenient, isn't that?

Unfortunately a million element graph gives rise to an adjacency matrix with 10^12 entries. Multiplying two such matrices with a naive algorithm should require 10^18 operations. Of course we have better matrix multiplication algorithms, but you're still not getting below, say, 10^15 operations. Which will most assuredly not complete in 1 minute. (If your matrix is sparse enough you might have a chance, but you should do some researching on the topic.)

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I did some reading on adjacency matrices. They are only applicable to DAG or up to n=2 with undirected matrices. Correct me if that is wrong though. The bipartite graph in this problem is an undirected graph. If it is converted to a directed graph, it is not a DAG. I am not quite sure how the number of paths that lead to the same node is related to the number of paths of length \$n\$ in a bipartite graph. Thank you for answering. – swtdrgn Jun 30 '12 at 13:40
@swtdrgn I'm correcting you because it is wrong. If you're admitting cycles as part of paths, then the adjacency matrix raised to a power does what you want. As for how it relates, the sum of the entries of that matrix is the total number of paths. – btilly Jun 30 '12 at 14:46
Thanks. It will be a sparse symmetrical matrix if I convert the graph to an adjancy matrix. – swtdrgn Jun 30 '12 at 16:27