How do I find the distance between two nodes in a binary tree? Equivalently, what algorithms are there for finding the most recent common ancestor (lowest common ancestor) of two nodes?




Finding the common ancestor is almost certainly the easier task. This is a pretty simple one: start from the root of the tree, and descend the tree until you reach a node where you would have to descend to different children to get to the two nodes in question. That node is the common parent (assuming the tree contains both nodes, of course). 


As everybody here seems to know, if you keep a note of the distance each node is from the root, then once you have found the lowest common ancestor of the two nodes you can work out the distance they are from each other in constant time. If you do one time work only linear in the size of the tree it turns out that you can then find the lowest common ancestor of any two nodes in constant time (no matter how deep the tree is). See http://en.wikipedia.org/wiki/Lowest_common_ancestor The Baruch Schieber and Uzi Vishkin algorithm for lowest common ancestor is entirely practical to use and to program. 


Make two sets consisting of the ancestors of each: while the union of the sets is empty, add the next ancestor of each node to the appropriate list. Once there is a common node, that's the common ancestor. 


First, search for the height of the first element. Also, return the path to get there using a linked list. You can do this in O(logN) time . Assume tree is balanced, where height is logN. let H1 = height of first element. Then, search for the heigh to the second element. Also, return the path to get there using a linked list. You can do this in O(logN) time. Let H2 = height of second element. Trace through both linked list collected until the values are no longer equal (paths diverge) The point before they diverge, call the height of that node H3. Thus, the longest path is H1 + H2  2*H3 (since you need H1 to go to H1, and H2 to go to H2. But really, you can trace back from H1 up till H1H3. and then move to H2 from H3. So it's (H1H3) + (H2H3) = H1+H2 2*H3. Implementation details should be straight forward
Thus,
Time Complexity: O(logN)+ O(logN) + O(logN) = O(logN) Space Complexity: O(logN) (to store both linked list of distances) 

