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 :)

Psuedocode:

```
# 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 ):
print_path(i,k,j)
```

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
break
return last_parent
```