# Find distance between two nodes in binary tree

Many answers on the net for 'finding Least Common Ancestor in binary tree' and its supplementary question 'find distance between 2 nodes' have 4 issues:

1. Does not consider duplicates
2. Does not consider if input node is invalid/absent/not in tree
3. Use extra / aux storage
4. Not truncating the traversal although answer is obtained.

I coded this sample to overcome all handicaps. but since I did not find 'a single' answer in this direction, I would appreciate if my code has a significant disadvantage which I am missing. Maybe there is none. Additional eyeballs appreciated.

``````  public int distance(int n1, int n2) {

int distance = foundDistance (root, lcaData, n1,  n2, new HashSet<Integer>());

return distance;
} else {
throw new IllegalArgumentException("The tree does not contain either one or more of input data. ");
}
}

TreeNode lca;
int count;

public LCAData(TreeNode parent, int count) {
this.lca = parent;
this.count = count;

}
}

private int foundDistance (TreeNode node, LCAData lcaData, int n1, int n2, Set<Integer> set) {
assert set != null;

if (node == null) {
return 0;
}

// when both were found
return 0;
}

// when only one of them is found
if ((node.item == n1 || node.item == n2) && lcaData.count == 1) {
// second element to be found is not a duplicate node of the tree.
if (!set.contains(node.item)) {
return 1;
}
}

int foundInCurrent = 0;
// when nothing was found (count == 0), or a duplicate tree node was found (count == 1)
if (node.item == n1 || node.item == n2) {
if (!set.contains(node.item)) {
}
// replace the old found node with new found node, in case of duplicate. this makes distance the shortest.
foundInCurrent = 1;
}

int foundInLeft = foundDistance(node.left, lcaData, n1, n2, set);
int foundInRight = foundDistance(node.right, lcaData, n1, n2, set);

// second node was child of current, or both nodes were children of current
if (((foundInLeft > 0 && foundInRight > 0) ||
(foundInCurrent == 1 && foundInRight > 0) ||
(foundInCurrent == 1 && foundInLeft > 0)) &&
// least common ancestor has been obtained
return foundInLeft + foundInRight;
}

// first node to match is the current node. none of its children are part of second node.
if (foundInCurrent == 1) {
return foundInCurrent;
}

// ancestor has been obtained, aka distance has been found. simply return the distance obtained
return foundInLeft + foundInRight;
}

// one of the children of current node was a possible match.
return (foundInLeft + foundInRight) > 0 ? (foundInLeft + foundInRight) + 1 : (foundInLeft + foundInRight);
}
``````
-
This question might be better suited on Code Review. –  Dukeling Sep 16 '13 at 2:36
@Dukeling It really appears to be an algorithmic question, rather than a code review question. But a description of the algorithm rather than just the code would have been more useful. –  David Sainty Sep 16 '13 at 3:07
@DavidSainty The question seems to be asking whether the code has a significant disadvantage, which seems a lot like code review to me. A question with largely the same content, though phrased a little differently, may have been on topic for Stack Overflow, but, as stated, I don't quite feel that it is. –  Dukeling Sep 16 '13 at 3:15
@Dukeling - i dont expect any formal comments/feedbacks like a code review. I just need to understand if -'some obvious handicaps' which I miss. An example would be just like one of the 4 points i observed on the other codes for such a problems. –  JavaDeveloper Sep 16 '13 at 3:26
Code-wise, I'd avoid using a HashSet<Integer> - that's a very heavy-weight object when you could just use a couple of booleans, or perhaps a two-element array of booleans. Every lookup in the hash set implies a `new Integer(n)` - which means a lot of costly memory management (in the case of very large numbers of duplicates). –  David Sainty Sep 16 '13 at 12:25