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I'm going to give the general case of this problem, because this is the 2nd time I've seen something that can be reduced to this and I haven't been able to find anything better than checking every path.

Suppose we have a directed graph G with vertices V such that there are no cycles and no self-edges. Additionally, each vertex has a color. Find the longest path starting from a given vertex such that the path goes through at most 1 vertex of each color.

I've implemented what is essentially depth-first search by removing all vertices of the added vertex's color in the recursive step, and I'm wondering if there's a better way to do it. The issue I keep running into is that storing past results is difficult because of the color restriction, so shortest path algorithms like Dijkstra's don't give the right result.

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I can come up with O(n*2^k) algorithm where n = max { |E|, |V|} and k = #colors. Note that this problem is very different from shortest path, because in here you are talking about longest path (which is generally NP-Hard problem, but the graph is a DAG, so there might be efficient solutions). –  amit Oct 6 '13 at 7:30
Backtracking (DFS) sounds good. There is no need to store past states, just colours that are visited with a current branch. Colour and vertex ordering is needed for a backtrecking, to know visit order from a current vertex. Solution is found when current branch has number of colours length. –  Ante Oct 6 '13 at 20:24
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The answer to you problem is No.

If you assign each vertex with distinct color, your problem will be reduced to Hamiltonian path problem which is NP-hard.

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That makes sense. For the record, what I ended up doing was depth first search with a globally updated top score and a upper-bound function to avoid traversing some nodes. It didn't improve time complexity, but in practice it was around 3x as fast. –  Titandrake Oct 13 '13 at 21:47
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