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I have a question. Is there an efficient way to get the Hamiltonian paths between two nodes in a grid graph, leaving some predefined nodes out?

eg. (4*3 grid)

1 0 0 0
0 0 0 0
0 0 2 3

finding a Hamiltonian paths in this grid b/w vertices 1 and 2, but not covering 3? It seems bipartite graphs are a way, but what according to you must be the most efficient way. The problem itself is NP complete.

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What is your graph representation? Are these rows adjacency lists? –  user334856 Dec 26 '11 at 20:40
Oh, actually, I think I got it. You have nodes that are laid out on a grid, and you've marked three vertices on that grid that are of interest. Is that correct? –  user334856 Dec 26 '11 at 20:42
Well, I have to find the hamiltonian path between vertex numbered 1(starting point) and vertex numbered 2(end point). but I should not include vertex number 3 in my path. –  Arun Shyam Dec 26 '11 at 20:44
What is the connectivity on this graph? Just left-right-up-down? Or diagonals also? Are all edge-weights equal? –  user334856 Dec 26 '11 at 20:45
according to this paper the problem as stated is indeed np-complete (cf. Sect.2, Cor.2 [p.681]). –  collapsar Jan 24 '12 at 8:52

2 Answers 2

up vote 3 down vote accepted

Delete the nodes you dont need to include and run the brute force algorithm to find Hamiltonian path. This will take O((n-h)!+n), which is NP, where h is the number of nodes deleted, but that is the best you can do. Also to find Hamiltonian path, there is a dynamic approach but that too is exponential( O(2^n*n^2))

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There's no need to leave those predefined nodes out: just consider them visited and you can still work your graph as a rectangular grid graph. I'd recommend a bitset or bitvector representation for the grid if efficiency is important.

When the grid is this small, 4x3, a brute force approach is the fastest. Dynamic programming makes it actually slower unless you have a bigger graph (6x7+). You can also use heuristics to prune your search tree, but again, the graph has to be bigger before it helps.

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