I don't know if this will be useful, but if anything, I think you could use this property:
Take a pair
(A,B) for which such a path exists. We then know that the sum of the edge weights (which I will call the distance of the end vertices) of the path
A -> ... -> B := d(A,B) = 0, because
d(A,B) = d(A,X) + d(X,B) = 0 + 0 = 0
As you remarked, we only care about paths of even length; this suggests that when actually checking the pairs, we first color the tree in two colors (since all trees are bipartite) which can be done greedily in Θ(n), and only consider pairs of vertices within each color group. Of course this doesn't improve the complexity of the number of pairs we will have to consider since we still have (n/2)*(n-1)/2 vertices in each color, and the term is in Θ(n^2) where
n is the number of vertices.
Now as you said, you can count the paths in Θ(n^2) using BFS and checking all pairs of vertices in each color group. Here is another thought that might help you:
Say we have two vertices V and U for which
d(A,V) = d(A,U). We have two cases:
A -> ... -> V = A -> ... -> U -> ... -> V, meaning U (WLOG) lies on the unique path from A to V. Then we have
d(A,V) = d(A,U) + d(U,V) <=> d(A,V) = d(A,V) + d(U,V) <=> d(U,V) = 0
So if U and V lie on the same path and have equal distance to A, the distance
d(U,V) = 0.
The two paths fork somewhere; let the vertex where the paths fork be K. We then have
d(A,V) = d(A,K) + d(K,V) <=> d(K,V) = d(A,V) - d(A,K) and
d(A,U) = d(A,K) + d(K,U) <=> d(K,U) = d(A,U) - d(A,K) and
d(U,V) = d(K,U) + d(K,V) = d(A,U) + d(A,V) - 2*d(A,K) = 2*(d(A,U) - d(A,K)) = 2 * d(K,U)
V don't lie on the same path, their distance to each other depends on the distance either vertex has to
A and the distance
A has to
K; or, simplified, just on the distance of either vertex to
K. More generally, the fact that
d(A,U) = d(A,V) only implies
d(U,V) = 0 in the case that either vertex lies on the path from
A to the other one, so you can't really tell anything by equal distances if the latter condition isn't the case.
Whether any of this will help you, I don't know. I couldn't figure out how to achieve what you ask for in subquadratic time, and I assume it's not possible; to me, the problem feels distantly related to all pairs shortest paths, which has time complexity in O(n^2) using BFS for each vertex as a start vertex. That is more a fuzzy feeling than anything even dimly resembling a convincing argument though.