I was thinking about an extension to the Shortest Hamiltonian Path (SHP) problem, and I couldn't find a way of solving it. I know it is NP-complete, but I figured I'd ask here for ideas, since I do not want to simply brute force the problem.

The extension is fairly simply: Given an undirected, complete, weighted graph with *n* vertices, find the shortest hamiltonian path with end vertices *v* and *u*.

So, bruteforce would still take O(*n*!) time, since the remaining *n*-2 vertices can be visited in (*n*-2)! ways. I was trying to find a way to maybe solve this *slightly* faster. My efforts for finding a way to solve this problem in a beneficial manner has so far been fruitless.

Would anyone have an idea how to exploit the knowledge of the end-vertices? Preferably explained alongside some pseudocode. It is required for the solution found to be optimal.

I guess it could be solved by integer programming, since the knowledge of end nodes are fairly limiting, and makes it easy to avoid cycles, but it wouldn't really exploit the composition of the problem.