Finding the shortest path between two points in a graph is a classic algorithms question with many good answers (Dijkstra's algorithm, Bellman-Ford, etc.) My question is whether there is an efficient algorithm that, given a directed, weighted graph, a pair of nodes s and t, and a value k, finds the kth-shortest path between s and t. In the event that there are multiple paths of the same length that all tie for the kth-shortest, it's fine for the algorithm to return any of them.

I suspect that this algorithm can probably be done in polynomial time, though I'm aware that there might be a reduction from the longest path problem that would make it NP-hard.

Does anyone know of such an algorithm, or of a reduction that show that it is NP-hard?

strictly-second shortest path (I know you indicated the opposite), the non-simple version is in P, the simple undirected version is in P (Krasikov-Noble/Zhang-Nagamochi), and the simple directed version is NP-hard (Lalgudi-Papaefthymiou). Also, for what it's worth, I haven't seen any very good descriptions of Yen's algorithm, but I'd like one! – daveagp Apr 2 '12 at 21:18