Which recursive functions cannot be rewritten using loops?

As far as I know, most recursive functions can be rewritten using loops. Some maybe harder than others, but most of them can be rewritten. So the question is, under which conditions does it become impossible to rewrite a recursive function using a loop (if such conditions exist)?

Clarification: I know how to convert a recursive function to use a loop, but I am asking whether there are (corner) cases where this is impossible.

-
Clarification: I know how to convert a recursive function to use a loop, but I am asking whether there are (corner) cases where this is impossible. –  Hosam Aly Feb 10 '09 at 9:41
I suspect you actually mean which can't be rewritten without some form of stack, is that so? –  AnthonyWJones Feb 10 '09 at 9:42
Instead of adding clarification as a comment edit your question. –  AnthonyWJones Feb 10 '09 at 9:43
Actually no. I mean if it's totally impossible to rewrite it using a loop. I'm thinking of indirect recursion as an example. –  Hosam Aly Feb 10 '09 at 9:44
@AnthonyWJones: Done. Question edited. –  Hosam Aly Feb 10 '09 at 9:45

When you use a function recursively, the compiler takes care of stack management for you, which is what makes recursion possible. Anything you can do recursively, you can do by managing a stack yourself (for indirect recursion, you just have to make sure your different functions share that stack). So no, there is nothing that can be done with recursion and that cannot be done with a loop and a stack.

-
I have a related question: can all recursive functions be represented as a single loop? –  Abhinav Sarkar Jun 3 '10 at 11:48
@Abhinav: sorry to reply to a very old thread, but this caught my eye and there's a simple proof that the answer is yes: A Turing machine does everything it does by executing a single loop: 1. fetch an instruction, 2. evaluate it, 3. goto 1. –  mokus Jan 21 '11 at 3:35
@mokus Your proof seems incomplete. The aim is to prove that every recursive function can be represented as a single loop. You're saying that a TM executes in a single loop. Where does recursion come into this? –  Vicky Chijwani May 5 '13 at 23:45
@VickyChijwani: mokus' proof is perfectly complete for the scope he mentions, and less confusingly, he could have said, "all programs and subroutines are executed in a simple single loop...", so, recursion is an abstraction that takes care of stack management similar to how any higher level programming control construct is an abstraction for what the processor pipeline will eventually do, fetch instructions and execute them. So, at some level of removed abstractions, all programs are a single loop. –  marr75 Jun 6 '14 at 20:16

In SICP, the authors challenge the reader to come up with a purely iterative method of implementing the 'counting change' problem (here's an example one from Project Euler).

But the strict answer to your question was already given - loops and stacks can implement any recursion.

-
By "SICP", do you mean "Structure and Interpretation of Computer Programs" (mitpress.mit.edu/sicp)? –  Hosam Aly Aug 8 '09 at 20:29
@Hosam - yes, this name is an accepted acronym –  Eli Bendersky Aug 9 '09 at 16:55
@eliben: This may be true for many people, but it's not the same for many others, especially new developers. If you use the acronym, I'd suggest making it a link. –  Hosam Aly Aug 13 '09 at 12:57

Every recursive function can be implemented with a single loop.

Just think what a processor does, it executes instructions in a single loop.

-
while(computer.on()) processNextInstruction(); –  Carson Myers Jul 18 '09 at 3:01
Actually it doesn't work as a loop. The pipeline in a modern CPU is much more like a assembly line. Start at instruction one, go to the next instruction on the instruction pointer++. Some instructions modify the instruction pointer itself which results in a loop or a jump occuring. –  Spence Sep 6 '12 at 13:00
@Spence The instruction pointer is just data. –  starblue Sep 7 '12 at 19:31
It's a little more than just data. Most of the branch prediction cache runs off the position and previous future instructions based on the pointer. Although it can be modified through assembly, it's a fundamental part of the processor. –  Spence Sep 9 '12 at 11:35

Indirect recursion comes to mind...

Edit: Mile's answer shows how to inline indirect recursion, so I was wrong.

-
them maybe Miles deserves a +1 :) –  Learning Feb 10 '09 at 13:00
He got it. :) I usually wait till responses are stabilised, so that I can assess different answers. –  Hosam Aly Feb 10 '09 at 13:03

Indirect recursion is still possible to convert to a non-recursive loop; just start with one of the functions, and inline the calls to the others until you have a directly recursive function, which can then be translated to a loop that uses a stack structure.

-

One example which would be extremely difficult to convert from recursive to iterative would be the Ackermann function.

-
Nice example. But a question remains: is it impossible, or just extremely difficult? –  Hosam Aly Feb 10 '09 at 9:53
Not even too difficult if you know the general techniques. –  Brian Feb 10 '09 at 9:59
I tried to do this, and it doesn't seem difficult to me. Check this code (and please tell me anything wrong with it): ... –  Hosam Aly Feb 10 '09 at 12:47
push(m); push(n); while (stackSize > 1) { n = pop(); m = pop(); if (m == 0) push(n+1); else if (m > 0 && n == 0) { push(m-1); push(1); } else if (m > 0 && n > 0) { push(m-1); push(m); push(n-1); } } –  Hosam Aly Feb 10 '09 at 12:49
Looks good to me –  1800 INFORMATION Feb 11 '09 at 6:43

Any recursive function can be made to iterate (into a loop) but you need to use a stack yourself to keep the state.

Normally, tail recursion is easy to convert into a loop:

``````A(x) {
if x<0 return 0;
return something(x) + A(x-1)
}
``````

Can be translated into:

``````A(x) {
temp = 0;
for i in 0..x {
temp = temp + something(i);
}
return temp;
}
``````

Other kinds of recursion that can be translated into tail recursion are also easy to change. The other require more work.

The following:

``````treeSum(tree) {
if tree=nil then 0
else tree.value + treeSum(tree.left) + treeSum(tree.right);
}
``````

Is not that easy to translate. You can remove one piece of the recursion, but the other one is not possible without a structure to hold the state.

``````treeSum(tree) {
walk = tree;
temp = 0;
while walk != nil {
temp = temp + walk.value + treeSum(walk.right);
walk = walk.left;
}
}
``````
-
Your original tail-recursive example is not quite tail-recursive (but still illustrates the point that 'linear' recursion is often easy to translate, whereas higher arities are often not so easy). –  Brian Feb 10 '09 at 9:51
Thanks. The last example seems to be what I am looking for. Is it really impossible to remove recursion from it? –  Hosam Aly Feb 10 '09 at 9:52
No, you can always rewrite it with loops. It is almost mechanical to transform into code that uses continuations, which can be compiled into loops (not use the stack) in a language like F#, see e.g. lorgonblog.spaces.live.com/blog/cns!701679AD17B6D310!256.entry –  Brian Feb 10 '09 at 9:56

I don't know about impossible but impractical->extremely inefficient examples are:

• tree traversal (a bitch in any loop)

• fast fourier

• quicksorts (and some others iirc)

Basically anything where you have to start keeping track of boundless potential states

-
+1 for mentioning fast fourier !! –  Jay D Dec 28 '10 at 21:53

It's not so much a matter of that they can't be implemented using loops, it's the fact that the way the recursive algorithm works, it's much clearer and more concise (and in many cases mathematically provable) that a function is correct.

Many recursive functions can be written to be tail loop recursive, which can be optimised to a loop, but this is dependent on both the algorithm and the language used.

-

You can always use a loop, but you may have to create more data structure (e.g. simulate a stack).

-

They all can be written as an iterative loop (but some might still need a stack to keep previous state for later iterations).

-