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I have a directed acyclic graph on which every vertex has a weight >= 0. There is a vertex who is the "start" of the graph and another vertex who is the "end" of the graph. The idea is to find the path from the start to the end whose sum of the weights of the vertices is the greater. For example, I have the next graph:

I(0) -> V1(3) -> F(0)
I(0) -> V1(3) -> V2(1) -> F(0)
I(0) -> V3(0.5) -> V2(1) -> F(0)

The most costly path would be I(0) -> V1(3) -> V2(1) -> F(0), which cost is 4.

Right now, I am using BFS to just enumerate every path from I to F as in the example above, and then, I choose the one with the greatest sum. I am afraid this method can be really naive.

Is there a better algorithm to do this? Can this problem be reduced to another one?

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2 Answers 2

up vote 2 down vote accepted

Since your graph has no cycles* , you can negate the weights of your edges, and run Bellman-Ford's algorithm.


* Shortest path algorithms such as Floyd-Warshall and Bellman-Ford do not work on graphs with negative cycles, because you can build a path of arbitrarily small weight by staying in a negative cycle.

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In general longest path problem is NP-hard, but since the graph is a DAG, it can be solved by first negating the weights then do a shortest path. See here.

Because the weights reside on the vertices, before computing, you might want to move the weights to the in edges of the vertices.

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