The question is to find whether a given sum exists over any path in a BST. The question is damn easy if a path means root to leaf, or easy if the path means a portion of a path from root to leaf that may not include the root or the leaf. But it becomes difficult here, because a path may span both left and right child of a node. For example, in the given figure, a sum of 132 exists over the circled path. How can I find the existence of such a path? Using hash to store all possible sums under a node is frowned upon!

You can certainly generate all possible paths, summing incrementally as you go. The fact that the tree is a BST might let you save time by bounding out certain sums, though I'm not sure that will give an asymptotic speed increase. The problem is that a sum formed using the left child of a given node will not necessarily be less than a sum formed using the right child, since the path for the former sum could contain many more nodes. The following algorithm will work for all trees, not just BSTs. To generate all possible paths, notice that the topmost point of a path is special: it's the only point in a path which is allowed (though not required) to have both children contained in the path. Every path contains a unique topmost point. Therefore the outer layer of recursion should be to visit every tree node, and to generate all paths that have that node as the topmost point.
The above pseudocode only reports the topmost node in the path. The entire path can be reconstructed by having The above pseudocode calculates sum lists multiple times for each node: It is possible to get rid of the temporary lists of sums by rearranging 


i would in order traverse the left subtree and in reverse order traverse the right subtree at the same time kind of how merge sort works. each time move the iterator that makes the aum closer.like merge sort almost. its order n 


Not the fastest, but simple approach would be to use two nested depthfirst searches. Use normal depthfirst search to get starting node. Use second, modified version of depthfirst search to check sums for all paths, starting from this node. Second depthfirst search is different from normal depthfirst search in two details:
Time complexity of each DFS in O(N), so total time complexity is O(N^{2}). Space requirements are O(N) (space for both DFS stacks). If original BST contains "parent" pointers, space requirements are O(1) ("parent" pointers allow traversing the tree in any direction without stacks). Other approach is based on ideas by j_random_hacker and robert king (maintaining lists of sums, matching them, then merging them together). It processes the tree in bottomup manner (starting from leafs). Use DFS to find some leaf node. Then go back and find the last branch node, that is a grand...grandparent of this leaf node. This gives a chain between branch and leaf nodes. Process this chain:
Continue DFS and search other leaf chains. When two chains, coming from the same node are found, possibly preceded by another chain (red and green chains on diagram, preceded by blue chain), process these chains:
Do the same wherever any two lists of sums or a chain and a list of sums are descendants of the same node. This process may be continued until a single list of sums, belonging to root node, remains. 


Is there any complexity restrictions? As you stated: "easy if a path means root to leaf, or easy if the path means a portion of a path from root to leaf that may not include the root or the leaf". You can reduce the problem to this statement by setting the root each time to a different node and doing the search n times. That would be a straightforward approach, not sure if optimal. Edit: if the tree is unidirectional, something of this kind might work (pseudocode):
Probably lots of mistakes here, but hopefully it clarifies the idea. 

