# Optimizing recursive calls over data structures

Is there an algorithm to optimize a highly recursive function into an iteration over a data structure? For example, given the following function...

``````// template <typename T> class BSTNode is defined somewhere else
// It's a generic binary search tree.
template <typename T, typename R>
void in_order(BSTNode<T>* root, R (*routine)(T))
{
if (root)
{
in_order(root->leftChild);
routine(root->data);
in_order(root->rightChild);
}
}
``````

... is it possible to optimize it into...

``````// template <typename> class Stack is defined somewhere else
// It's a generic LIFO array (aka stack).

template <typename T, typename R>
void in_order(BSTNode<T>* root, R (*routine)(T))
{
if (!root) return;

Stack<BSTNode*> stack;
stack.push(NULL);

line1:
while (root->leftChild)
{
stack.push(root);
root = root->leftChild;
}

line2:
routine(root->data);
if (root->rightChild)
{
root = root->rightChild;
goto line1;
}

else if (root = stack.pop())
goto line2;
}
``````

(Of course, the difference is that, instead of filling the call stack, the latter fills another stack in the heap.)

EDIT: I meant an algorithm that can be executed by the compiler, so I don't have to optimize it by hand.

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When you ask "is there an algorithm", are you asking whether there is a general algorithm that a human can follow to perform the transformation, or are you asking if there's some STL or other function to do this automatically? –  Charlie Jun 21 '09 at 18:41
An algorithm that can be executed by a compiler for any language, not necessarily the C++ compiler. –  Eduardo León Jun 21 '09 at 18:45
This won't be an optimization on most CPU architectures and languages as the processor based call-stack is a much faster stack (as it's processor-internal) than the custom build Stack which you're using in your second example. You should go with the shorter, recursive variant of your iteration, as it's probably faster and much easier to read. If there is a faster implementation possible, most compilers nowaday already unroll such loops to a certain extend. You should rely on the compiler itself here. If in doubt, use the first rule of optimisation: Measure. –  Kosi2801 Jun 21 '09 at 18:49
If "any language" is what you want, here's one for LISP: user.it.uu.se/~torer/publ/remrec.html -- and here one for PL/I: portal.acm.org/citation.cfm?id=359344 -- it's a long-lived, still active field of research, but I don't know of any compilers for popular languages that actually offer such tools. –  Alex Martelli Jun 21 '09 at 18:54

You're asking for the continuation-passing-style transformation with defunctionalized continuations; it's covered in chapter 6 of Essentials of Programming Languages, with code in Scheme. But it'd be a huge pain to implement for C++. Maybe if you have a compiler frontend that converts C++ into reasonably accessible datastructures, though, and you need to do this to a lot of code. The book also explains how to do this transformation systematically by hand, which is more likely to be practical in your situation.

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Yes, you can do this.

However, aside from possibly exhausting stack space with very deep trees, there is no "optimization" here. If you need speed gains, consider threading your trees instead.

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Thanks for the solution, IMHO, a very intelligent one. However, the in-order traversal code I wrote was just an example. I have some VERY big data structures in the actual program I'm writing. –  Eduardo León Jun 21 '09 at 18:58
+1 for the threaded trees. thanks! –  cube Jun 21 '09 at 19:01
The meta-answer to your meta-question is probably similar: redesign/enhance your structures to (a) support non-recursive iteration or (b) not require iteration in the first place. –  HUAGHAGUAH Jun 21 '09 at 19:12

The only general recursive optimisation I've come across is that of optimising tail recursion. This is frequently done in functional languages and basically involves the compiler/interpreter changing a function where the final operation is the recursive call into a fully iterative function (so no problems with stack, etc).

For other forms of recursion, I'm not aware that any general purpose algorithm for optimising them into iterative functions has been found/created. You can certainly always express such functions in an iterative manner, but the transformation is not a general purpose one.

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Tail recursion is rather easy: first overwrite the parameters, then goto to the first line of code. My actual problem is not as easy: I have a really big and complex data structure in a program I'm writing, which I would like to traverse it in a civilized way (recursion, not iteration). But all I get are stack overflows. –  Eduardo León Jun 21 '09 at 19:04

Technically the answer to this is "yes": any algorithm which can be expressed recursively (i.e. with an implicit stack) can also be reformulated to use iteration (i.e. with an explicit stack or other tracking structure).

However, I suspect that most compilers can't or won't attempt to do this for you. Coming up with a general-purpose automatic algorithm for performing the transformation is likely to be pretty difficult, although I've never tried it, so I shouldn't say that it's intractable.

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It is possible to traverse a tree depth-first, without using recursion.

A good example is the following: http://code.activestate.com/recipes/461776/.

The compiler won't do this optimization for you, though. However, the concept is not so hard to grasp. What you're doing is creating a call stack and nodelist yourself, instead of using a function call to go deeper into the tree.

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It is possible to traverse a mutable ordered tree iteratively, by recording the node's parent in the branches you take, and knowing the direction you approach a node from ( down, or up from the left or right, which the ordered property of the tree lets you test ):

``````template <typename T, typename R>
void in_order ( BSTNode<T>* root, R (*routine)(T) ) {
typedef BSTNode<T>* Node;

Node current = root;
Node parent  = 0;

bool going_down = true;

while ( current ) {
Node next = 0;

if ( going_down ) {
if ( current -> leftChild ) {
// navigate down the left, swapping prev with the path taken
Node next_child = current -> leftChild;
current -> leftChild = parent;
parent = current;
current = next_child;
} else if ( current -> rightChild ) {
// navigate down the right, swapping prev with the path taken
Node next_child = current -> rightChild;
current -> rightChild = parent;
parent = current;
current = next_child;
} else {
// leaf
routine ( current -> data );
going_down = false;
}
} else {
// moving up to parent
if ( parent ) {
Node next_parent = 0;

// came from the left branch
if ( parent -> data > current -> data ) {
// visit parent after left branch
routine ( parent -> data );

// repair parent
next_parent = parent -> leftChild;
parent -> leftChild = current;

// traverse right if possible
if ( parent -> rightChild ) {
going_down = true;
// navigate down the right, swapping prev with the path taken
Node next_child = parent -> rightChild;
parent -> rightChild = next_parent;
//parent = current;
current = next_child;
continue;
}
} else {
// came from the right branch
next_parent = parent -> rightChild;
parent -> rightChild = current;
}

current = parent;
parent = next_parent;
} else {
break;
}
}
}
}
``````

If rather than storing the children, you store the XOR of the parent and child, then you can get the next node in whatever direction you approach from without having to mutate the tree.

I don't know of anything with automatically transforms non-tail recursive functions into such code. I do know of environments where the call stack is allocated on the heap, which transparently avoid a stack overflow in cases where you can't perform such mutations and have a fixed small stack size. Usually recording the state on a stack takes less space that the call stack, as you're selecting only the essential local state to record, and are not recording return addresses or any caller-save registers ( if you used a functor rather than a function pointer, then it's more likely that the compiler might be able to inline `routine` and so not save the caller save registers in the simple recursive case, so reducing the amount of stack required for each recursion. YMMV ).

Since you're using templates you should only need to do the traversal code once, and combine it with strategy templates to switch between pre, post and inorder, or whatever other iteration modes you want.

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The idea is nice. However, after your code runs, the tree's depth grows, so ordinary operations like inserts and lookups become computationally more complex. But I guess that's the price I would have to pay to not use a stack in this particular case. –  Eduardo León Jun 23 '09 at 21:01

Of course, the difference is that, instead of filling the call stack, the latter fills another stack in the heap.

You answered yourself. What is cheaper, stack or heap? (unless you are running out of stack space)

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I want an algorithm that, given the first code snippet, outputs the second one, so I don't have to write the optimized but long code by hand! :) –  Eduardo León Jun 21 '09 at 18:50
Given the stack is way cheaper than the heap in most cases, I dont see why :) –  leppie Jun 21 '09 at 18:53
I have some VERY big data structures. –  Eduardo León Jun 21 '09 at 18:57

Sure you can make your own stack.

You want speed? Unless `routine(root->data)` does almost nothing, you'll never notice the difference.

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I want to avoid stack overflows. –  Eduardo León Jun 23 '09 at 20:58
@Eduardo: I understand - that's why i said sure you can make your own stack. Even though your own stack will probably be less efficient than the CPU stack, it may not make a noticeable difference if routine(root->data) spends many more cycles per node than the time you spend pushing & popping each node, i.e. routine() will dominate in that case. –  Mike Dunlavey Jun 24 '09 at 0:50