I'm trying to find out an efficient way of finding the shortest path between 2 nodes in a graph with positive edge costs that goes trough a subset of nodes.

More formally:

Given a graph G = (U, V) where U is the set of all nodes in the graph and V is the set of all edges in the graph, a subset of U called U' and a cost function say:

```
f : UxU -> R+
f(x, y) = cost to travel from node x to node y if there exists an edge
between node x and node y or 0 otherwise,
```

I have to find the shortest path between a source node and a target node that goes trough all the nodes in U'.

The order in which I visit the nodes in U' doesn't matter and I am allowed to visit a node more than once.

My original idea was to make use of Roy-Floyd algorithm to generate the cost matrix.
Then, for each permutation of the nodes in U' I would be computing the cost between the source and the target like this: f(source_node, P_{1}) + f(P_{1}, P_{2}) + ... + f(P_{k}, target) saving the configuration for the lowest cost and then reconstructing the path.

The complexity for this approach is ~~O(n~~ O(n^{3} + k!)^{3} + k*k!), where n is the number of nodes in the graph and k the number of nodes in the subset U', which is off limits since I'll have to deal with graphs with maximum n = 2000 nodes out of which maximum n - 2 nodes will be part of the U' subset.

`O(n^3 + k*k!)`

because the summation for each combination will cost at least`O(k)`

. – davin Oct 6 '11 at 19:03