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I am trying to get the list of connected components in a graph with 100 million nodes. For smaller graphs, I usually use the connected_components function of the Networkx module in Python which does exactly that. However, loading a graph with 100 million nodes (and their edges) into memory with this module would require ca. 110GB of memory, which I don't have. An alternative would be to use a graph database which has a connected components function but I haven't found any in Python. It would seem that Dex (API: Java, .NET, C++) has this functionality but I'm not 100% sure. Ideally I'm looking for a solution in Python. Many thanks.

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How dense is your graph? What's the average vertex degree? –  NPE Jun 13 '12 at 13:49
Is the graph directed? If it is - are you looking for Strongly connected components or connected components? Also - I assume you are looking for Maximal [strongly?] connected components, and not all of them (since their number is exponential) - is it true? –  amit Jun 13 '12 at 13:50
@aix: the graph has on average 1.5 vertex/node. –  David M. Jun 13 '12 at 14:07
@amit: the graph is undirected. I am looking for a way to get the list of connected components, exactly as networkx.connected_components does but on a larger scale. –  David M. Jun 13 '12 at 14:11

2 Answers 2

up vote 4 down vote accepted

SciPy has a connected components algorithm. It expects as input the adjacency matrix of your graph in one of its sparse matrix formats and handles both the directed and undirected cases.

Building a sparse adjacency matrix from a sequence of (i, j) pairs adj_list where i and j are (zero-based) indices of nodes can be done with

i_indices, j_indices = zip(*adj_list)
adj_matrix = scipy.sparse.coo_matrix((np.ones(number_of_nodes),
                                     (i_indices, j_indices)))

You'll have to do some extra work for the undirected case.

This approach should be efficient if your graph is sparse enough.

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My graph is pretty sparse but this solution works only for a (relatively) small graph, because the time penalty of scipy.sparse.csgraph.connected_components is not linear. In my test it took 0.4 second to process 10,000 nodes; 30 seconds for 100,000 nodes and 51 minutes for 1 million (then I stopped testing). Thanks for suggesting this anyway, it is an interesting approach. –  David M. Jun 19 '12 at 16:40
@user1453508: that's odd. I checked the code and at first glance it seems to me that it should be linear when |E| = O(|V|). I must admit that my graphs tend to be a bit smaller. Maybe you should start looking at MapReduce solutions to your problem. –  larsmans Jun 19 '12 at 18:09
Just in case I have misunderstood something, here is my code: i_indices = []; j_indices = []; file = open ('adjacency_file.txt', 'r'); for line in iter(file): i_index, j_index = line.strip('\n').split('\t'); i_indices.append(i_index); j_indices.append(j_index); file.close(); adjacency_matrix = scipy.sparse.coo_matrix((np.ones(len(i_indices)),(i_indices, j_indices)), shape=(10000,10000)); connected_components = scipy.sparse.csgraph.connected_components(adjacency_matrix, directed=False) –  David M. Jun 20 '12 at 17:34
@user1453508: looks like you're assigning strings to i_index and j_index, and then storing those in the index lists. I'm not sure how the coo_matrix constructor will handle that, but it sure isn't the intended input. –  larsmans Jun 20 '12 at 21:34
Originally my nodes are 10-digit numbers and I have converted them into indices from 0 to 10,000, which are stored into adjacency_file.txt (e.g. if node 5 is linked to node 22, the file will contain the line 5[tab]22[\n]). Is that the correct way to do it? –  David M. Jun 20 '12 at 21:48


this tool as you can see from performance is very fast. It's written in C++ but the interface is in Python.

If this tool isn't good enough for you. (Which I think it will) then you can try Apache Giraph (http://giraph.apache.org/).

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