# Longest Simple Path

So, I understand the problem of finding the longest simple path in a graph is NP-hard, since you could then easily solve the Hamiltonian circuit problem by setting edge weights to 1 and seeing if the length of the longest simple path equals the number of edges.

My question is: What kind of path would you get if you took a graph, found the maximum edge weight, `m`, replaced each edge weight `w` with `m - w`, and ran a standard shortest path algorithm on that? It's clearly not the longest simple path, since if it were, then NP = P, and I think the proof for something like that would be a bit more complicated =P.

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Here's a hint: if you find a path of length L in the new graph, and it contains k edges, what is the length of the corresponding path in the old graph? –  ShreevatsaR Apr 4 '09 at 20:22
It'd be "mk - [sum(weight(i)) for each i in the path]"... I think I need another hint –  Claudiu Apr 4 '09 at 20:49
What do you mean by "what kind of path"? I don't think it has any special significance. –  v3. Apr 5 '09 at 18:40
@v3: I think that's the right answer. It won't be the longest simple path or the shortest path of anything, that's for sure. –  Claudiu Apr 6 '09 at 3:27

The graph above is transformed to below using your algorithm.

The Longest path is the red line in the above graph.And depending on how ties are broken and algorithm you use, the shortest path in the transformed graph could be the blue line or the red line. So transforming graph edge weights using the constant that you mentioned yields no significant results. This is why you cannot find the longest path using the shortest path algorithms no matter how clever you are. A simpler transformation could be to negate all the edge weights and run the algorithm. I dont know if I have answered your question but as far as the path property goes the transformed graph doesnt have any useful information regarding the distance.

However this particular transformation is useful in other areas. For example you could force the algorithm to select a particular edge weight in bipatrite matching if you have more than one constraint by adding a huge constant.

• Edit: I have been told to add this statement: The above graph is not just about the physical distance. They need not hold the triangle inequality. Thanks.
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I'm sorry, but it seems the pic you attached does not work now. Maybe you removed it from your dropbox? –  ibread Oct 8 '10 at 3:42
Ah, I set the new weight to `m-w`, not `-w`. The smallest weight will be 0. –  Claudiu Apr 4 '09 at 20:45