# Algorithm to compute every path in a N by N grid, non-repeating [closed]

I have a grid of NxN cells (think of a 2 dimensional array defined as follows Array[N][N]).

Which algorithm will compute every path from every cell a[i][j] to every cell a[k][l] where:

1. No cell is included twice within a single path.
2. Only adjacent diagonal, horizontal and vertical moves all legal.
3. The algorithm is the fastest, on average.
4. The least amount of memory is used.
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## closed as not a real question by mah, dasblinkenlight, luke, Marcin, Matthew FarwellMay 8 '12 at 13:57

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Good question. Seems like a dynamic programming problem. –  aioobe May 8 '12 at 11:28
I would change `5 by 5` to `N by N` before someone answer with an algorithm with a pre-calculated hard-coded answer. –  aioobe May 8 '12 at 11:29
Djkistra's shortest path algorithm I'd imagine, take a quick look here for more information, it might help you come up with a solution. en.wikipedia.org/wiki/Dijkstra%27s_algorithm –  David K May 8 '12 at 11:33
That would be O(1) time! :-) –  David Buck May 8 '12 at 11:33
"3. The algorithm is the fastest, on average. 4. The least amount of memory is used." This kind of "requirement" is meaningless. The fastest and the most space-efficient algorithm are usually not the same algorithm. –  svinja May 8 '12 at 12:09

I assume you want the actual paths, and not just the number of them.

You can achieve it by using DFS that maintains `visited` set on the vertices explored in the same path, and avoids exploring a vertex that was already discovered in the same path.

Pseudo code:

``````DFS(v,target,visited):
if (v == target):
print path to v from the initial sorce
return
for each vertex u such that u is a neighbor of v:
if (u is not in visited):
u.parent <- v
DFS(u,target,visited)
visited.remove(v)
``````

invoke `with DFS(source,target,{})` [where `{}` is an empty `visited` set].

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The breadth-first search will do exactly what you want. When generating all paths there's no fastest

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How will breadth-first search all paths. It typically terminates one path when it reaches a node which is already in the visited set. –  aioobe May 8 '12 at 11:30
I am sorry, but BFS without modifications will fail to find all paths. For example: find paths between (0,0) and (1,2): assume BFS yields the feasible path `(0,0)->(1,1)->(1,2)`, then it will not yield `(0,0)->(1,0)->(0,1)->(1,1)->(1,2)`, since BFS maintains `visited` set, and thus `(1,1)` will not be re-explored in the second path. If you have specific modification to BFS - please explain it with details, as standard BFS fails here. –  amit May 8 '12 at 12:13
Will get back to you later for the BFS solution - for now I've found in my lectures this source - recursive algorithm for finding all paths - pastebin.com/V0wNEpqY - it's publicly available as part of Telerik Academy's lectures ( academy.telerik.com/academy/csharp-programming-fundamentals/… ) –  t3hn00b May 8 '12 at 12:34
@t3hn00b: The algorithm there is a DFS, not a BFS. –  amit May 8 '12 at 19:14