# Traversal to print two BSTs ordered using recursion. Use of extra memory like arrays is not allowed

I was asked this question in an interview. Given are two BST (Binary Search Tree). We need to traverse the two trees in such a way that a merged sorted output is the result. Constraint is that we cannot use extra memory like arrays. I suggested a combined inorder traversal of both the trees. The approach was correct but I got stuck in recursion and was not able to write the code.

Note: We cant merge the two trees into one.

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Besides the two trees, you also need a comparison operator (or fonction) to merge the trees. –  wildplasser Feb 20 '13 at 12:59
You need to merge the trees OR a traversal that prints the elements of both trees ordered? –  Jim Feb 20 '13 at 13:14
@Jim: Thanks for your reply. I need a traversal that prints the elements of both trees ordered. –  user1225752 Feb 20 '13 at 13:21
@Jim : I have updated the question title. Hope it is more clear now. –  user1225752 Feb 20 '13 at 13:23
@user1225752:Post the algorithm approach that you suggested but could not code –  Cratylus Feb 20 '13 at 18:13

I am assuming that there are no links to parent or next nodes in the tree, because otherwise this would be quite easy: Your just iterate your trees by following these links and write your merge algorithm as you would for linked lists.

If you don't have next or parent links, you cannot write simple recursion. You'll need two "recursion" stacks. You can implement the following structure, which allows you to iterate the each of the trees separately.

``````class Iterator
{
stack<Node> st;
int item(){
return st.top().item();
}
if (st.top().right != null)
st.push(st.top().right);
// Go as far left as possible
while (st.top().left != null) st.push(st.top().left);
else {
int x = st.top().item();
// we pop until we see a node with a higher value
while(st.top().item()<=x) st.pop();

}
}
};
``````

Then write your merge algorithm using two of these iterators.

You will need O(log n) space, but asymptotically this isn't more than any recursive iteration.

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The OP specifically asks for a solution with no extra space. –  Cratylus Feb 24 '13 at 11:17
Any recursion of the tree uses O(log n) space. There is simply no possible solution that uses constant extra space. Logarithmic space for linear time operation is not a big deal. –  RareBox Feb 24 '13 at 12:17

The "simplest" way would be to:

1. Convert tree A to a doubly linked list (sorted)
2. Convert tree B to a doubly linked list (sorted)
3. Traverse the sorted lists printing minimum (easy)
4. Convert list A to tree A
5. Convert list B to tree B

You can find algorithms for this steps online.
I don't think doing a parallel traversal of trees is possible. You would need additional information e.g. a visited flag to eliminate left subtree as visited and even then you would run into other problems.
If anyone knows how this would be possible with a parallel traversal I would be happy to know it.

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I've upd'd my answer with the solution. Whaddya think? –  Will Ness Feb 24 '13 at 14:31
BTW whether your solution is acceptable or not, is predicated on the question about `Leaf` representation in this BST: Is leaves are represented by `Nodes` with two NULL child node pointers, then it's OK and you can reuse them for the DL links. But if leaves are represented by a special linkless `Leaf` structure, then you will have to allocate new memory for the links in doubly linked list for the leaves. –  Will Ness Feb 24 '13 at 14:48
@WillNess:I am not sure what is the algorithm for the parallel traversal.From my point of view doing parallel traversal of both trees will not work as you can not know whether you have already visited a subtree or not –  Cratylus Feb 25 '13 at 9:46
I've clarified my answer. Please respond there. :) Thank you. Here I made another claim. –  Will Ness Feb 25 '13 at 10:36
to your question: each traversal is done separately, one does not know about the other. The results are interleaved. For that to be possible on non-parallel hardware, each must be stoppable - and restartable from the point where it was previously stopped. This is the essence of generators concept, achieved with `yield` statement in Python. Or with continuations, in Scheme. Or via lazy semantics of Haskell. –  Will Ness Feb 25 '13 at 10:40
``````print \$ merge (inorder treeA) (inorder treeB)
``````

what's the problem?

(notice, the above is actual Haskell code which actually runs and performs the task). `inorder` is trivial to implement with recursion. `merge` is a nearly-standard feature, merging its two argument ordered (non-decreasing) lists, producing an ordered output list, keeping the duplicates.

Because of lazy evaluation and garbage collection, the lists are not actually created - at most one produced element is retained for each tree, and is discarded when the next one is produced, in effect creating iterators for the traversals (each with its own internal state).

Here's the solution (if your language does not support the above, or the equivalent `yield` mechanism, or the explicit continuations of Scheme which allow to switch between two contexts deep inside control stack each (thus making it possible to have "two recursions" in parallel, as in the above)):

They don't say anything about time complexity, so we can do a recursive traversal of 1st tree, and traverse the 2nd tree anew, for each node of the 1st tree - while saving `previous` value on 1st. So, we have two consecutive values on 1st tree, and print all values from 2nd tree between them, with fresh recursive traversal, restarting from the top of the 2nd tree for each new pair of values from the 1st tree.

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Very interesting for me who don't know Haskell.But in the context of an interview question, I am not sure this is what the interview expected. –  Cratylus Feb 24 '13 at 11:17
@Cratylus if you allowed to use Python this basically means just use `yield` instead of `return` inside your recursive traversal functions, that's all. –  Will Ness Feb 24 '13 at 11:21
May be you are right.I don't know scripting languages so perhaps you could get away with it for a Python position. –  Cratylus Feb 24 '13 at 11:27
@Cratylus there is no specific language tag on this question, right? If you don't have `yield` in your language, you will have to do some reification yourself (i.e. convert implicit call stack of recursion into explicit stack of pointers into the tree as you traverse it, like the other answer shows). Or use standard iterators, if in C++. –  Will Ness Feb 24 '13 at 11:31
Then you go back to my original comment.To implement what you written in a one line of code yourself. –  Cratylus Feb 24 '13 at 11:44