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In an acyclic graph, I am trying to find out whether or not a path of length L exists between two given nodes. My questions is, what is the best and the simplest Algorithm to use in this case.

Note that the graph has a maximum of 50 nodes and 100 edges.

I have tried to find all the paths using DFS and then to check if that path exists between the two nodes but I got the answer "Time Limit Exceeded" from the online judge.

I also used the Uniform Cost Search Algorithm but I also a got a negative response.

I need a more efficient way for solving such problem. Thank you.

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Is graph weighted? – kilotaras Jun 20 '12 at 17:15
no, it's not weighted. – Traveling Salesman Jun 20 '12 at 20:05

4 Answers 4

I don't know if it will be faster then a DFS approach - but it will give a feasible solution:

Represent the graph as a matrix A, and calculate A^L - a path of length L between i and j exists if and only if A[i][j] != 0

Also, regarding DFS solution: You do not need to find all paths in the DFS - you should limit yourself to paths of length <= L, and by this trim some searches, once the length have exceeded the needed length. You could also escape the search once a path of length L is reaching the target.

Another possible optimization could be bi-directional search.

  • Find all vertices which have path of length L/2 from the source to them.
  • Next, find all vertices which have paths of length L/2 from them to the target (DFS on the reverse graph)
  • Then, check if there is a vertex that is common to both sets, if there is - you got a path of length L from the source to the target.
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Since the graph is acyclic you can order vertices topologicaly. Let's name starting vertex A and finish vertex B.

Now the core algorithm starts: For each vertex count all possible distances from A to this vertex. At start there is one path from A to A with length zero. Then take vertices in topological order. When you pick vertex x: Look at each predecessor and update possible distances here.

This should run in O(N^3) time.

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the starting and the ending nodes are specified in the problem. – Traveling Salesman Jun 20 '12 at 19:45

You can use a modified Dijkstra algorithm where instead of saving for every vertex the minimum distance to the origin, you save all the possible distances less or equal to the one desired.

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I believe that you can use the following algorithm to find the longest path in a tree. This assumes that your graph is connected, if it is not you would need to rerun this on each connected component:

  1. Pick an arbitrary node, A.
  2. Do a BFS (or DFS) from A to find the node in the tree farthest from A, call this node B.
  3. Do a BFS (or DFS) from B to find the node in the tree farthest from B, call this node C.
  4. The path from B to C is the longest path in the tree (possibly tied for longest).

Obviously if this path is longer than L then you can shorten it to find a path of length L.

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According to your algorithm, if you can go from B to another node, then why did we stop at B in step 2? aren't we suppose to keep going to the farthest one? What's your definition of "a node being the farthest" ? What's the name of the algorithm you are suggesting here? – Traveling Salesman Jun 20 '12 at 18:59
We stop at B because we have to, it's a leaf node and there is no where else to go. Then we do a different search starting from B, we'll reach A, but then we'll go further and get to C. A node X is furthest from node Y if there is no node Z such that the distance from X to Z is greater than X to Y. – Running Wild Jun 20 '12 at 19:09
I don't know if this algorithm has a name - I came up with it back when I was in school. I had to prove it at the time, but I remember the proof being a bit tedious so I didn't want to try to redo it here. – Running Wild Jun 20 '12 at 19:11
A don't think the question is about trees. – usamec Jun 20 '12 at 19:12
@usamec, I can't agree more! – Traveling Salesman Jun 20 '12 at 19:43

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