Let say you need to go from src to dest.
With each vertex x, associate two values count and val, where count is the number of shortest paths from src to x and val is the shortest distance from src to x. Also maintain a visited variable telling whether this is the first time visiting the node or not.
Apply usual BFS algorithm,
Initialize u = src
visited[u] = 1,
val[u] = count[u] = 1
For each child v of u,
if v is not visited
The first time a node is visited, it has only one path from src to now via u, so the shortest path up to v is (1 + shortest path up to u), and number of ways to reach v via shortest path is same as count[u] because say u has 5 ways to reach from source, then only these 5 ways can be extended up to v as v is encountered first time via u, so
val[v] = val[u]+1,
count[v] = count[u],
visited[v] = 1
if v is visited
If v is already visited, which means, there exists some other path up to v via some other vertices, then three cases arise:
1 :if val[v] == val[u]+1
if current val[v] (which is dist up to v via some other path) is equal to val[u]+1, i.e we have equal shortest distances for reaching v using current path through u and the other path up to v, then the shortest distance up to v remains same, but the number of paths increase by number of paths of reaching u.
count[v] = count[v]+count[u]
2: val[v] > val[u]+1
If current path of reaching v is smaller than previous value of val[v], then val[v] is stored current path and count[v] is also updated
val[v] = val[u]+1
count[v] = count[u]
The third case is if current path has a distance greater than the previous path. In this case, there is no need to change the values of val[v] and count[v] as this path does not count as a shortest path
Do this algorithm till the BFS is complete.
In the end val[dest] contain the shortest distance from source and count[dest] contain the number of ways from src to dest.