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The A star algorithm is known to be complete. However, all the implementations that I have found searching the web seem to only return only the first (optimal) solution.

For example, this implementation: A star algoritthm implementation

Since the algorithm always expands the node with the minimum f value, and the implementations seem to stop when the first node is a solution, how would one adapt the aforementioned code so as to output all (or the first n) paths that lead to a goal, without taking into account duplicate actions (that is, paths that contain the same action over and over again)?

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Simply do not stop after you found less than n solutions and you will get the n best solutions. –  MrSmith42 Jan 30 '13 at 19:03
    
Surely that will not work? –  flup Jan 30 '13 at 19:05
    
@flup: Why? The search space is a tree, the A*-algorithm guarantees to find one optimal solution, if you cut this solution from the tree, the A*-algorithm will find one optimal solution for the reduced tree. You do not need to start the search again, because the calculations for each node of the tree have not changed. –  MrSmith42 Jan 30 '13 at 19:10
    
@MrSmith42 Finding the optimal solution lies very much at the core of the algorithm. The nodes in the closed set all know only the optimal way to get there. Do you wish to cut all nodes that are on the optimal path from the tree? –  flup Jan 30 '13 at 19:11
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@MrSmith42 Speaking in terms of the wikipedia description of astar, the value of the came_from arrows in the closed set that point at the optimal way to reach them will be pointless. The entire internal data structure is attuned to the optimal solution you just found. I really do not see how you could keep going or skip one solution. –  flup Jan 30 '13 at 19:27
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2 Answers

For all paths, it probably makes a lot more sense to use breath first search. Alternatively, you can try Dijkstra's algorithm if you want to find the top n shortest paths.

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It's complete which means it will find a solution if one exists, but the algorithm specifically only returns one path. A breadth-first search will find all non-cyclical paths between two nodes, however: http://en.wikipedia.org/wiki/Breadth-first_search

Update - Here is the k-shortest paths algorithm which will return a list of n (or in this case, k) shortest paths in order of shortest to longest. http://code.google.com/p/k-shortest-paths/

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This has in most cases much much worse performance than A`search. –  MrSmith42 Jan 30 '13 at 19:14
    
A* is faster, but it doesn't do what he wants. If you make it do what he wants, it's going to be slower because it will no longer be looking for a single path, but all paths. –  Pete Jan 30 '13 at 19:19
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Search all path is exactly what breadth first search does. I do not know where your wisdom about the behavior of all possible modifications of A* comes. but I doubt it. –  MrSmith42 Jan 30 '13 at 19:24
    
-1 not sure why you'd think BFS can do it but not A*. –  BlueRaja - Danny Pflughoeft Jan 30 '13 at 19:36
    
The poster asked for "how would one adapt the aforementioned code so as to output all (or the first n) paths that lead to a goal." How do you think A* can accomplish that? It doesn't do either of those things. –  Pete Jan 30 '13 at 19:38
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