The following is an O(n log n) algorithm that work for graphs in which each child has at most one parent (EDIT: this algorithm does not extend to the two-parent case with O(n log n) performance). It is worth noting that I believe the performance can be improved to O(n log(max level label)) with extra work.
One parent case:
For each node x, in reverse topological order, create a binary search tree T_x that is strictly increasing both in date of birth and in number of generations removed from x. (T_x contains the first born child c1 in the subgraph of the ancestry graph rooted at x, along with the next earliest born child c2 in this subgraph such that c2's 'great grandparent level' is a strictly greater than that of c1, along with the next earliest born child c3 in this subgraph such that c3's level is strictly greater than that of c2, etc.) To create T_x, we merge the previously-constructed trees T_w where w is a child of x (they are previously-constructed because we are iterating in reverse topological order).
If we are careful with how we perform the merges, we can show that the total cost of such merges is O(n log n) for the entire ancestry graph. The key idea is to note that after each merge, at most one node of each level survives in the merged tree. We associate with each tree T_w a potential of h(w) log n, where h(w) is equal to the length of the longest path from w to a leaf.
When we merge the child trees T_w to create T_x, we 'destroy' all of the trees T_w, releasing all of the potential that they store for use in building the tree T_x; and we create a new tree T_x with (log n)(h(x)) potential. Thus, our goal is to spend at most O((log n)(sum_w(h(w)) - h(x) + constant)) time to create T_x from the trees T_w so that the amortized cost of the merge will be only O(log n). This can be achieved by choosing the tree T_w such that h(w) is maximal as a starting point for T_x and then modifying T_w to create T_x. After such a choice is made for T_x, we merge each of the other trees, one by one, into T_x with an algorithm that is similar to the standard algorithm for merging two binary search trees.
Essentially, the merging is accomplished by iterating over each node y in T_w, searching for y's predecessor z by birth date, and then inserting y into T_x if it is more levels removed from x than z; then, if z was inserted into T_x, we search for the node in T_x of the lowest level that is strictly greater than z's level, and splice out the intervening nodes to maintain the invariant that T_x is ordered strictly both by birth date and level. This costs O(log n) for each node in T_w, and there are at most O(h(w)) nodes in T_w, so the total cost of merging all trees is O((log n)(sum_w(h(w))), summing over all children w except for the child w' such that h(w') is maximal.
We store the level associated with each element of T_x in an auxiliary field of each node in the tree. We need this value so that we can figure out the actual level of x once we've constructed T_x. (As a technical detail, we actually store the difference of each node's level with that of its parent in T_x so that we can quickly increment the values for all nodes in the tree. This is a standard BST trick.)
That's it. We simply note that the initial potential is 0 and the final potential is positive so the sum of the amortized bounds is an upper bound on the total cost of all merges across the entire tree. We find the label of each node x once we create the BST T_x by binary searching for the latest element in T_x that was born before x died at cost O(log n).
To improve the bound to O(n log(max level label)), you can lazily merge the trees, only merging the first few elements of the tree as necessary to provide the solution for the current node. If you use a BST that exploits locality of reference, such as a splay tree, then you can achieve the above bound.
Hopefully, the above algorithm and analysis is at least clear enough to follow. Just comment if you need any clarification.