# Shortest Path to Cover All nodes in a graph given a starting and ending node

I am trying to solve a problem in which there is an undirected graph with positive weighted edges and I need to find the shortest path that covers all the nodes exactly once given the start and end node. In addition the graph is complete(each node is connected to all the other nodes in the graph). I have tried searching for an algorithm that could solve this problem but I haven't found one that solves this problem. This is not exactly the traveling sales man problem because of the restriction of the start and end node. I will appreciate any kind of help.

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google travelling salesman problem –  ashley Dec 15 '13 at 21:01
I already did that, but I haven't found an algorithm that can calculate a good approximation of my problem. The traveling salesman is to find a path that comes back to the start point. I don't want to come back to the start point, the path has to finish at the end point. –  anishk25 Dec 15 '13 at 21:16
travelling salesman is in NP and well-studied. it's for you to do the work. –  ashley Dec 15 '13 at 21:19
Given the graph is complete, solve TSP and remove one edge. –  stark Dec 15 '13 at 22:52
@stark How are you going to get it to end at the given end vertex? –  Dukeling Dec 15 '13 at 22:53

If you're starting at node `S` and ending at `T`, add a dummy node `D` that has zero-weight edges to only `S` and `T`. Find an optimal travelling salesman tour on this graph, then remove the dummy node from the tour to get your path.
If you'd like to preserve the graph's completeness property, you can implement the above by adding the dummy node with zero-weight edges to `S` and `T`, and with edges to all other nodes having weights larger than the sum of the weights of the `n` heaviest edges in the graph. For practical purposes, this means setting their weights to `Integer.Max` or similar.