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Given a binary search tree and a target value, find all the paths (if there exists more than one) which sum up to the target value. It can be any path in the tree. It doesn't have to be from the root.

For example, in the following binary search tree:

 / \ 
1   3 

when the sum should be 6, the path 1 -> 2 -> 3 should be printed.

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@ the root is 2, the left subtree is 1, and the right subtree is 3 in the example posted – TimeToCodeTheRoad Jan 4 '11 at 8:30
I'd rather use a bidirectional graph (with limited node connections) for that purpose. Bin trees (at least for me) imply a fixed, single direction. – fjdumont Jan 4 '11 at 9:11
How does this help? – marcog Jan 4 '11 at 10:10
I was suggesting a different approach on the problem. Bintrees are useful for (relatively) just a few problems, for this particular problem a different data structure might work better. I must admit that I didnt see the homework tag, though ;) – fjdumont Jan 4 '11 at 10:18
up vote 12 down vote accepted

Traverse through the tree from the root and do a post-order gathering of all path sums. Use a hashtable to store the possible paths rooted at a node and going down-only. We can construct all paths going through a node from itself and its childrens' paths.

Here is psuedo-code that implements the above, but stores only the sums and not the actual paths. For the paths themselves, you need to store the end node in the hashtable (we know where it starts, and there's only one path between two nodes in a tree).

function findsum(tree, target)
  # Traverse the children
  if tree->left
    findsum(tree.left, target)
  if tree->right
    findsum(tree.right, target)

  # Single node forms a valid path
  tree.sums = {tree.value}

  # Add this node to sums of children
  if tree.left
    for left_sum in tree.left.sums
      tree.sums.add(left_sum + tree.value)
  if tree.right
    for right_sum in tree.right.sums
      tree.sums.add(right_sum + tree.value)

  # Have we formed the sum?
  if target in tree.sums
    we have a path

  # Can we form the sum going through this node and both children?
  if tree.left and tree.right
    for left_sum in tree.left.sums
      if target - left_sum in tree.right.sums
        we have a path

  # We no longer need children sums, free their memory
  if tree.left
    delete tree.left.sums
  if tree.right
    delete tree.right.sums

This doesn't use the fact that the tree is a search tree, so it can be applied to any binary tree.

For large trees, the size of the hashtable will grow out of hand. If there are only positive values, it could be more efficient to use an array indexed by the sum.

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Can you get the following case when the 'answer' path starts from a non-leaf and ends at a non-leaf. From my understanding of your code, it doesn't seem so. – Ritesh Nov 3 '11 at 4:29
I re-read the code, I guess you are storing all paths in the subtree to the root node of the subtree, then non-leaf paths are also possible. Sorry for the confusion. – Ritesh Nov 3 '11 at 5:00
shouldn't it be if target - left_sum - tree.value in tree.right.sums? – Pan Aug 21 '14 at 15:28

My answer is O(n^2), but I believe it is accurate, and takes a slightly different approach and looks easier to implement.

Assume the value stored at node i is denoted by VALUE[i]. My idea is to store at each node the sum of the values on the path from root to that node. So for each node i, SUM[i] is sum of path from root to node i.

Then for each node pair (i,j), find their common ancestor k. If SUM(i)+SUM(j)-SUM(k) = TARGET_SUM, you have found an answer.

This is O(n^2) since we are looping over all node pairs. Although, I wish I can figure out a better way than just picking all pairs.

We could optimize it a little by discarding subtrees where the value of the node rooted at the subtree is greater than TARGET_SUM. Any further optimizations are welcome :)


# Skipping code for storing sum of values from root to each node i in SUM[i]
for i in nodes:
    for j in nodes:
        k = common_ancestor(i,j)
        if ( SUM[i] + SUM[j] - SUM[k] == TARGET_SUM ):

Function common_ancestor is a pretty standard problem for a binary search tree. Psuedocode (from memory, hopefully there are no errors!):

sub common_ancestor (i, j):
  parent_i = parent(i)
  # Go up the parent chain until parent's value is out of the range. 
  # That's a red flag.
  while( VAL[i] <= VAL[parent_i] <= VAL[j] ) : 
    last_parent = parent_i
    parent_i = parent(i)
    if ( parent_i == NULL ): # root node
return last_parent
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Old question, but here's my stab at it - should be O(n) time as your visiting each node only once:

  public static List<ArrayList<Integer>> pathSum(Node head, int sum) {
    List<Integer> currentPath = new ArrayList<Integer>();
    List<ArrayList<Integer>> validPaths = new ArrayList<ArrayList<Integer>>();

    dfsSum(head, sum, currentPath, validPaths);

    return validPaths;

  public static void dfsSum(Node head, int sum, List<Integer> currentPath, List<ArrayList<Integer>> validPaths) {
    if (head == null) return;


    if (head.left == null && head.right == null && sum == head.val) {
      validPaths.add(new ArrayList<Integer>(currentPath));

    dfsSum(head.left, sum - head.val, new ArrayList<Integer>(currentPath), validPaths);
    dfsSum(head.right, sum - head.val, new ArrayList<Integer>(currentPath), validPaths);

And the node class:

class Node {
    public int val;
    public Node left;
    public Node right;

    public Node(int val) {
      this.val = val;
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