# Counting Subgraph Instances

Let's say I have a large (several thousand node) directed graph G and a much smaller (3-5 node) directed graph g. I want to count how many isomorphisms of g are in G. In other words, I want to know how many unique sets of nodes in G match g. I realize that this is an instance of the subgraph isomorphism problem and is therefore NP-complete. However, given that you may assume that g is small, is there any reasonably efficient algorithm for doing this?

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Maybe the math.stackexchange.com would give you better results - I know what you seek is an algorithm, but you could probably devise an algorithm from theory –  veljkoz Nov 23 '10 at 19:34
Is your problem "one case" or you want a general algorithm. I ask just because some feature on the cardinality of the edges of g may help a lot ... –  belisarius Nov 23 '10 at 19:36
If the size of your smaller graph doesn't grow as a function of N, then even a brute force algorithm should be polynomial time, because N choose k is O(N^k). –  mbeckish Nov 23 '10 at 19:53
@mcbeckish: I thought of the O(N^k) algorithm, and that probably won't cut it. –  dsimcha Nov 23 '10 at 21:02
Yes, even polynomial-time algorithms can take too long. I just wanted to clarify that if the size of the smaller graph is fixed, then this is not NP-Complete. –  mbeckish Dec 1 '10 at 15:50

Although graph isomorphism is NP-complete in general, problems you come across in the real world are often pretty easy. A simple brute-force should suffice: Let `M_i` be a set of maps from the first i nodes of g to nodes of G. Start with `m_0` containing the empty map and extend it one node at a time, discarding any maps which violate the constraint `x->y` iff `m(x)->m(y)`.