Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

'Length' of a path is the number of edges in the path.

Given a source and a destination vertex, I want to find the number of paths form the source vertex to the destination vertex of given length k.

  • We can visit each vertex as many times as we want, so if a path from a to be goes like this: a -> c -> b -> c -> b it is considered valid. This means there can be cycles and we can go through the destination more than once.

  • Two vertices can be connected by more than one edge. So if vertex a an vertex b are connected by two edges, then the paths , a -> b via edge 1 and a -> b via edge 2 are considered different.

  • Number of vertices N is <= 70, and K, the length of the path, is <= 10^9.

  • As the answer can be very large, it is to be reported modulo sum number.

Here is what I have thought so far:

We can use breadth-first-search without marking any vertices as visited, at each iteration, we keep track of the number of edges 'n_e' we required for that path and product 'p' of the number of duplicate edges each edge in our path has.

The search search should terminate if the n_e is greater than k, if we ever reach the destination with n_eequal to k, we terminate the search and add p to out count of number of paths.

I think it we could use a depth-first-search instead of breadth first search, as we do not need the shortest path and the size of Q used in breadth first search might not be enough.

The second algorithm i have am thinking about, is something similar to Floyd Warshall's Algorithm using this approach . Only we dont need a shortest path, so i am not sure this is correct.

The problem I have with my first algorithm is that 'K' can be upto 1000000000 and that means my search will run until it has 10^9 edges and n_e the edge count will be incremented by just 1 at each level, which will be very slow, and I am not sure it will ever terminate for large inputs.

So I need a different approach to solve this problem, and any help would be greatly appreciated.

share|improve this question
    
Do all of the edges have weight 1? – Dennis Meng Jan 11 '13 at 5:45
    
@DennisMeng Yes, its an unweighted graph, i'll add it in the question – 2147483647 Jan 11 '13 at 5:48
up vote 13 down vote accepted

So, here's a nifty graph theory trick that I remember for this one.

Make an adjacency matrix A. where A[i][j] is 1 if there is an edge between i and j, and 0 otherwise.

Then, the number of paths of length k between i and j is just the [i][j] entry of A^k.

So, to solve the problem, build A and construct A^k using matrix multiplication (the usual trick for doing exponentiation applies here). Then just look up the necessary entry.

EDIT: Well, you need to do the modular arithmetic inside the matrix multiplication to avoid overflow issues, but that's a much smaller detail.

share|improve this answer
    
+1 Beautiful solution. – templatetypedef Jan 11 '13 at 5:55
    
"Then, the number of paths of length k between i and j is just the [i][j] entry of A^k." As every entry will be either 1 or 0, the number of paths will be either 0 or k? – 2147483647 Jan 11 '13 at 5:58
    
No. You can do a quick induction proof to show correctness if you'd like, but A^k will not have only 0s and ks. – Dennis Meng Jan 11 '13 at 6:00
    
"A[i][j] is 1 if there is an edge between i and j, and 0 otherwise." you said that yourself – 2147483647 Jan 11 '13 at 6:01
2  
well, allocate more matrices via self-multiplication, say A0=A, A1=A0*A0, A2=A1*A1, etc, you'll end up only needing to multiply at most 2*ceil(log2(K)) times. – Vesper Jan 11 '13 at 7:40

Actually the [i][j] entry of A^k shows the total different "walk", not "path", in each simple graph. We can easily prove it by "mathematical induction". However, the major question is to find total different "path" in a given graph. We there are a quite bit of different algorithm to solve, but the upper band is as follow:

(n-2)(n-3)...(n-k) which "k" is the given parameter stating length of path.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.