'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 -> bit 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
bare connected by two edges, then the paths ,
a -> bvia edge 1 and
a -> bvia 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 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.