# Is there a problem that has only a recursive solution? [duplicate]

Is there a problem that has only a recursive solution, that is, a problem that has a recursive solution, but an iterative solution has yet to be found, or better yet, has proven to be non-existing (obviously, this is not a tail-recursion)?

• that depends what you call recursive. every recursive function can be translated to a non-recursive one by implementing a stack.. Commented Jul 7, 2009 at 20:36
• Yes; it is described in detail here: stackoverflow.com/questions/1094679 Commented Jul 7, 2009 at 20:37
• @Marc Gravell: That's absolutely great! Commented Jul 7, 2009 at 20:39
• @Marc Gravell:Brilliant, we can find the same thing when looking at the index for Recursion in the K&R. (The index references a bunch of pages and the index page...)
– LB40
Commented Jul 7, 2009 at 20:58
• I think that's more of "do any problems exist where iteration is terribly bad compared to recursion" rather that "are there problems that absolutely require recursion" Commented Jul 7, 2009 at 21:13

replace function calls with pushing arguments onto a stack, and returns with popping off the stack, and you've eliminated recursion.

Edit: in response to "using a stack does not decrease space costs"

If a recursive algorithm can run in constant space, it can be written in a tail-recursive manner. if it is written in tail-recursive format, then any decent compiler can collapse the stack. However, this means the "convert function calls to explicit stack-pushes" method also takes constant space as well. As an example, lets take factorial.

factorial:

``````def fact_rec(n):
' Textbook Factorial function '
if n < 2:  return 1
else:      return n * f(n-1)

def f(n, product=1):
' Tail-recursive factorial function '
if n < 2: return product
else:     return f(n-1, product*n)

def f(n):
' explicit stack -- otherwise same as tail-recursive function '
stack, product = [n], 1
while len(stack):
n = stack.pop()
if n < 2: pass
else:
stack.append(n-1)
product *= n
return product
``````

because the stack.pop() follows the stack.append() in the loop, the stack never has more than one item in it, and so it fulfills the constant-space requirement. if you imagine using a temp variable instead of a 1-length stack, it becomes your standard iterative-factorial algorithm.

of course, there are recursive functions that can't be written in tail-recursive format. You can still convert to iterative format with some kind of stack, but I'd be surprised if there were any guarantees on space-complexity.

• That is not recursion elimination. When one replace recursive function with non-recursive one it is supposed to use limited memory instead of theoretically unlimited stack. Commented Jul 7, 2009 at 20:43
• "Guaranteed to use a finite amount of memory" is not the definition of a nonrecursive function. It might be a desirable property, but it's not a definitional requirement. An iterative algorithm with a memory leak will use a potentially unlimited amount of memory, but nobody would argue that alone makes the algorithm recursive. Commented Jul 7, 2009 at 21:10
• @jia3ep: this is recursion elimination. in fact, it already has a tangible benefit in some situations by moving the load from the operating system's call stack (which in many architectures has a limited space) into the heap, and avoiding the overhead of a function call. Commented Jul 7, 2009 at 21:44
• This doesn't change the idea of the recursion in my opinion, you can as well implant a virtual machine in some non-stack way, and run your recursion code on top of it, I was thinking more in the spirit of a different algorithm. nice idea nonetheless. Commented Jul 8, 2009 at 4:06
• @Jimmy, Hardware stack is much faster then using heap, so stack emulation has no obvious advantage. Commented Jul 8, 2009 at 4:24

In Response to the Ackermann function answer, this is a pretty straightforward convert-the-call-stack-into-a-real-stack problem. This also shows one benefit of the iterative version.

on my platform (Python 3.1rc2/Vista32) the iterative version calculates ack(3,7) = 1021 fine, while the recursive version stackoverflows. NB: it didn't stackoverflow on python 2.6.2/Vista64 on a different machine, so it seems to be rather platform-dependant,

(Community wiki because this is really a comment to another answer [if only comments supported code formatting .... ])

``````def ack(m,n):
s = [m]
while len(s):
m = s.pop()
if m == 0:
n += 1
elif n == 0:
s.append(m-1)
n = 1
else:
s.append(m-1)
s.append(m)
n -= 1
return n
``````
• I assume the 'append' is really a 'push'? Commented Jul 8, 2009 at 4:19
• well, this is a list in python heh. Commented Jul 8, 2009 at 5:59
• How does it compare between the non-recursive impl and recursive impl compare? In other words, is there a performance or readability improvement to using recursion? Commented Dec 14, 2022 at 8:41

The Ackermann function cannot be expressed without recursion

edit: As noted in another answer, this is incorrect.

• Counter: "The Ackermann function can also be expressed nonrecursively using Conway chained arrow notation" (see wikipedia) Commented Jul 7, 2009 at 21:05
• Interesting. The Ackermann function is not a primitive recursive function: en.wikipedia.org/wiki/Primitive_recursive_function. According to this page, a language with basic arithemetic, comparison, and bounded for-loops can't express this type of function. But if you add in WHILE or GOTO you're Turing-complete again. Commented Jul 7, 2009 at 21:21
• see my response at stackoverflow.com/questions/1094679/… Commented Jul 8, 2009 at 0:28
• I think it's important to differentiate between problems whose "mathematical" definition involves a recursive form ... vs. whose computation can only be achieved recursively. You can compute the Ackermann function using non-recursive programming form - however you will to store state for each iteration. Commented Jul 8, 2009 at 12:42
• @LBushkin I fully agree
– LB40
Commented Jul 8, 2009 at 13:41

You can define a Turing Machine without recursion (right?) So recursion isn't required for a language to be Turing-complete.

• in computational linguistics, the Turing Machine is above the Stack based automatas because it can emulate those (the strip can be used as a stack) Commented Jul 7, 2009 at 21:07

In programming, recursion is really a special case of iteration - one where you use the call stack as a special means of storing state. You can rewrite any recursive method to be an iterative one. It may be more complicated or less elegant, but it's equivalent.

In mathematics, there are certain problems that require recursive techniques to arrive at an answer - some examples are finding roots (Newton's Method), computing primes, graph optimization, etc. However, even here, there's just a question of how you differentiate between the terms "iteration" and "recursion".

EDIT: As others have pointed out, there exist many functions whose definition is recursive - ex. the Ackermann function. However, this does not mean that they cannot be computed using iterative constructs - so long as you have a turing complete operation set and unlimited memory.

All non np-complete problems can be solved with just sequence, decision, and iteration. Recursion should not be required, though it usually greatly simplifies the problem.

• So can the NP-complete ones. It just takes longer.
– Ian
Commented Aug 15, 2010 at 11:54
• This answer is wrong. Undecidable problems are not NP-Complete (and they cannot be solved with iteration or recursion).
– Paul
Commented Aug 30, 2012 at 13:42

It comes down to how many lines of code is it going to take to solve the problem...

List all the files on your C:\ using recursion and then without. Sure you can do it both ways - but one way is going to be a lot simpler to understand and debug.

• Search in a tree can be Depth-first or Breadth-first. The former is naturally translated with recursion, but the later is more natural to implement with an iterative method. Commented Jul 7, 2009 at 20:55

No. Recursion is nothing more than a stack and you can achieve the same results by implementing a stack explicitly.

That may not be an especially satisfying answer, but you'd have to ask a much more specific question to get a better answer. For example, theory dictates that in the levels of computing there is quite a difference in the range of problems that can be solved if you have a while loop vs. only having (traditional) for loops.

I put "traditional" in there because they really mean loops that iterate a certain number of times whereas C style for (...;...;...) loops are while loops in disguise.