# algorithm - Path finding given vertex constraints

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