This task is solved by matrix multiplication.
n containing 0s and 1s (1 for a cell
mat[i][j] if there is path from
j). Multiply this matrix by itself
k times (consider using fast matrix exponentiation). Then in the matrix's cell
mat[i][j] you have the number of paths with length
k starting from
i and ending in
NOTE: The fast matrix exponentiation is basically the same as the fast exponentiation, just that instead you multiply numbers you multiply matrices.
NOTE2: Lets assume
n is the number of vertices in the graph. Then the algorithm I propose here runs in time complexity O(log k * n3) and has memory complexity of O(n 2). You can improve it a bit more if you use optimized matrix multiplication as described here. Then the time complexity will become O(log k * nlog27).
EDIT As requested by Antoine I include an explanation why this algorithm actually works:
I will prove the algorithm by induction. The base of the induction is obvious: initially I have in the matrix the number of paths of length 1.
Let us assume that until the power of
k if I raise the matrix to the power of
k I have in
mat[i][j] the number of paths with length
Now lets consider the next step
k + 1. It is obvious that every path of length
k + 1 consists of prefix of length
k and one more edge. This basically means that the paths of length
k + 1 can be calculated by (here I denote by
mat_pow_k the matrix raised to the
num_paths(x, y, k + 1) = sumi=0i<n mat_pow_k[x][i] * mat[i][y]
n is the number of vertices in the graph. This might take a while to understand, but basically the initial matrix has 1 in its
mat[i][y] cell only if there is direct edge between
y. And we count all possible prefixes of such edge to form path of length
k + 1.
However the last thing I wrote is actually calculating the
k + 1st power of
mat, which proves the step of the induction and my statement.