# Can all recursive functions be re-written as tail-recursions? [duplicate]

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Are there problems that cannot be written using tail recursion?

From my understanding, tail recursion is an optimization you can use when a recursive call does not need information from the recursive calls that it will spam. Is it possible then to implement all recursive functions using tail-recursion? What about something like DFS, where you need the innermost child to return before the parent can?

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## marked as duplicate by Pete Kirkham, Mooing Duck, rene, johannes, sdcvvcAug 5 '12 at 23:59

Similar question? stackoverflow.com/questions/1888702/… – River Aug 1 '12 at 22:28

as the other answers show, it depends on exactly what you are asking.

if you want to keep all functions as functions (no mutable state) with the same signatures, then no. the most obvious example is the quicksort one given by jerry - both calls can't be tail calls.

but if you can modify the function in various ways then yes.

sometimes a local modification is sufficient - often you can add an "accumulator" that builds some expression that is returned (although if the result involves non-commutative operations then you need to be careful (for example, when naively constructing linked lists, the order is reversed). or you can add a stack (see comments).

alternatively, you can do a global modification of the entire program, in which each function takes as an extra argument the function that contains future actions. this is the continuation passing that pete is talking about.

if you are working by hand then the local modification is often fairly easy. but if you're doing automated rewriting (in a compiler for example) then it's simpler to take the global approach (it requires less "smarts").

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quicksort can be programmed tail-recursively, maintaining additional explicit stack of positions of the second half, for later processing. – Will Ness Aug 5 '12 at 23:08
you don't have to call the continuation itself that you receive, in the tail position. you can call whatever function you want in the tail position, in CPS. you'd just pass that continuation, as-was or modified, to that tail call. – Will Ness Aug 5 '12 at 23:20
a stack would be mutable state. i've tried to correct the cps description. – andrew cooke Aug 6 '12 at 0:03
no it's not. you push and pop as you pass it along. and array itself in quicksort is mutable, or else it is not a quicksort, because partition can't be done that way otherwise. Jerry Coffin's answer is plainly wrong. – Will Ness Aug 6 '12 at 0:05
then it's changing the signature. the part where i discuss quicksort says withiut mutation and keeping the same signature (i agree with you on the argument that quicksort as whole should be mutable, but we both lost that argument a long time ago - everyone else and their dog calls that kind of functional recursive sort quicksort). – andrew cooke Aug 6 '12 at 0:21

Yes and no.

Yes, used in conjunction with other control flow mechanisms (e.g., continuation passing) you can express any arbitrary control flow as tail recursion.

No, it is not possible to express all recursion as tail recursion unless you do supplement the tail recursion with other control flow mechanisms.

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I'm curious, can't all recursive algorithms be written using iteration, and can't all iterative algorithms be expressed using tail-recursion? Perhaps it's more a matter of direct/indirect ways of expressing it, or perhaps it's possible just with side-effects? – aioobe Jul 30 '12 at 4:10
Yes, recursive function can be computed by using iteration and managing the (call) stack manually. If the function can be transformed into a tail-recursive representation you can eliminate the stack. That's what a certain form of tail-recursion optimization does: It reuses the stack frame from the current call for the next call. If you have an iteration which does not use a stack you can transform it into a tail-recursive function. If it uses a stack the stack remains, i.e. there is no upper bound on the memory use of the stack, which is the point in tail-recursion optimization. – Stefan Jul 30 '12 at 7:06
Sorry, this is simply false. It is a fact that all programs can be rewritten as tail calls using continuations. – Pete Kirkham Aug 1 '12 at 21:04
@PeteKirkham: Claiming that it's "simply false" is misleading at best (and probably the worst excuse for a downvote I've seen the whole time I've been on SO). Yes, tail recursion in conjunction with something else (of which continuations are only one well known possibility) can do the trick. Tail recursion by itself is rather a different story. – Jerry Coffin Aug 1 '12 at 21:14
@AndreyT given you can implement a complete language (scheme), or perform optimisations in compilers by making the transformation to a tail call, what is not 'meaningful' about the transformation of a not tail recursive operation using O(f(N)) stack to a tail-recursive one using O(f(N)) heap? In the real world, it gives you certain desirable features, such as allowing you to operate using a single garbage collected allocation mechanism so storage for unreachable stack objects are reclaimed. – Pete Kirkham Aug 2 '12 at 11:09

I don't know if all recursive functions can be rewritten to be tail-recursive, but many of them can. One standard method of doing this is to use an accumulator. For example, the factorial function can be written (in Common Lisp) like so:

``````(defun factorial (n)
(if (<= n 1)
1
(* n (factorial (1- n)))))
``````

This is recursive, but not tail recursive. It can be made tail-recursive by adding an accumulator argument:

``````(defun factorial-accum (accum n)
(if (<= n 1)
accum
(factorial-accum (* n accum) (1- n))))
``````

Factorials can be calculated by setting the accumulator to 1. For example, the factorial of 3 is:

``````(factorial-accum 1 3)
``````

Whether all recursive functions can be rewritten as tail-recursive functions using methods like this isn't clear to me, though. But certainly many functions can be.

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And why was this voted down? – River Aug 2 '12 at 4:44
the perceived problem is not with singly-recursive processes like the factorial calculation, but with doubly-recursive processes like binary tree traversal. Tail call or not is a feature of syntax, not of algorithm. – Will Ness Aug 5 '12 at 23:45
That interpretation of the question is in now way obvious. – River Aug 6 '12 at 6:17
did you mean to say "in no way obvious"? My interpretation of the question is straightforward. It asks, can any recursive code be written as tail-recursive code. TR code is a matter of syntax - whether all function calls it makes that can lead to it being called again are in tail position. TR code may not get optimized, if the implementation does not apply TCO. TR code with TCO applied can run in constant stack, that's all that is claimed about TCO. the re-write of singly-recursive code like `factorial` is simple, is what I meant, for doubly-recursive code it is more involved. – Will Ness Aug 6 '12 at 7:17

Yes you can. The transformation usually involves maintaining the necessary information explicitly, which would otherwise be maintained for us implicitly spread among the execution stack's call frames during run time.

As simple as that. Whatever the run time system does during execution implicitly, we can do explicitly by ourselves. There's no big mystery here. PCs are made of silicon and copper and steel.

It is trivial to implement DFS as a loop with explicit queue of states/positions/nodes to process. It is in fact defined that way - DFS replaces the popped first entry in the queue with all the arcs coming from it; BFS adds these arcs to the end of the queue.

The continuation-passing style transformation leaves all the function calls in a program as tail calls after it is done. This is a simple fact of life. The continuations used will grow and shrink, but calls will all be tail calls.

We can further reify the state of process spread in continuations, as explicitly maintained data on the heap. What this achieves in the end, is explication and reification, moving implicit stuff on stack to the explicit stuff living in the heap, simplifying and demystifying the control flow.

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Does this lose the optimizations the OP mentions? – WolframH Aug 6 '12 at 0:08
@WolframH what optimizations? he doesn't mention any. he says he thinks it is an optimization, and it is. it explicates things, moving implicit things hidden on the stack among call frames, into the open, on heap. This exactly makes explicit the information buildup which he mentions. i.e. when the information from recursive call down the chain is needed by the upper level calls, it is usually coded as non-tail recursive; but that information flow can be made explicit, and control flow turned into iterative. – Will Ness Aug 6 '12 at 0:14

Recursive algorithm is an algorithm that implemented in accordance with Divide & Conquer strategy, where solving each intermediate sub-problem produces 0, 1 or more new smaller sub-problems. If these sub-problems are solved in LIFO order, you get a classic recursive algorithm.

Now, if your algorithm is known to produce only 0 or 1 sub-problem at each step, then this algorithm can be easily implemented through tail recursion. In fact, such algorithm can easily be rewritten as an iterative algorithm and implemented by a simple cycle. (Needless to add, tail recursion is just another less explicit way to implement iteration.)

A schoolbook example of such recursive algorithm would be recursive approach to factorial calculation: to calculate `n!` you need to calculate `(n-1)!` first, i.e. at each recursive step you discover only one smaller sub-problem. This is the property that makes it so easy to turn factorial computation algorithm into a truly iterative one (or tail-recursive one).

However, if you know that in general case the number of sub-problems generated at each step of your algorithm is more than 1, then your algorithm is substantially recursive. It cannot be rewritten as iterative algorithm, it cannot be implemented through tail recursion. Any attempts to implement such algorithm in iterative or tail-recursive fashion will require additional LIFO storage of non-constant size for storing "pending" sub-problems. Such implementation attempts would simply obfuscate the unavoidable recursive nature of the algorithm by implementing recursion manually.

For example, such simple problem as traversal of a binary tree with parent->child links (and no child->parent links) is a substantially recursive problem. It cannot be done by tail-recursive algorithm, it cannot be done by an iterative algorithm.

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You missed 'immutable' from the constraints for your binary tree traversal, otherwise it is possible using a well known approach stackoverflow.com/a/791378/1527 – Pete Kirkham Aug 2 '12 at 11:15
for some, tail recursion is more explicit and natural way to express iteration than countless varying loop constructs. :) – Will Ness Aug 5 '12 at 23:26
what's wrong with maintaining LIFO storage explicitly which would otherwise be maintained implicitly on call stack frames for us? Potato, potato. Complexity isn't added by that transformation, it is inherent to the algorithm at hand itself. And traversal of immutable binary tree is easily done in a loop with explicit stack of nodes-to-visit. – Will Ness Aug 5 '12 at 23:33
@Will Ness: There's nothing "wrong" with that. It is just that it doesn't produce an iterative algorithm. Just because you used a "loop" in your code, does not mean that you magically found an iterative algorithm. As long as your algorithm follows D&C strategy with additional storage for pending tasks, your algorithm is recursive, period. How you implement it doesn't really matter. A parent->child tree is a classic example of a recursive data structure, which is why any traversal algorithm will be recursive. There's no way around it. – AnT Aug 6 '12 at 5:21
Meanwhile, "tail recursion" is a term that refers to a specific optimization strategy, not just an algorithm that happen to invoke itself at the end. One of the requirements of that optimization strategy is static storage size. Dynamically sized continuation is a non-solution. – AnT Aug 6 '12 at 5:24

All programs can be rewritten as tail calls using continuation passing. Simply add one parameter to the tail call representing the continuation of the current execution.

Any Turning complete language perform the same transformation as continuation passing provides - create a Gödel number for a the program and input parameters that the non-tail call returns to, and pass that as a parameter to the tail call - though obviously environments where this is done for you with a continuation, co-routine or other first-class construct makes it much easier.

CPS is used as a compiler optimisation and I have previously written interpreters using continuation passing. The scheme programming language is designed to allow it to be implemented in such a fashion with requirements in the standard for tail call optimisation and first class continuations.

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Taken as an answer to the question, as asked, this is simply false. Yes, it's possible to use continuations to simulate essentially any flow control you wish. The question, however, was only about tail recursion, not continuations. – Jerry Coffin Aug 1 '12 at 21:19
@Pete Kirkham: If you can find a way to encode the continuation state using `O(1)` memory, then it will indeed constitute a valid way to turn recursive algorithm onto a tail-recursive or iterative one. But if your continuation requires non-constant amount of memory, then the approach does not qualify as tail recursion in the sense of the original question. – AnT Aug 1 '12 at 22:45
@JerryCoffin the question as asked makes not mention of O(1) memory. – Pete Kirkham Aug 2 '12 at 10:42
@JerryCoffin that's not far off saying you're using an integer counter not just iteration. AFAIK, the only language which has a standard where there is a guarantee of tail call optimisation is scheme, which also provides continuations. The two fit together, just like having a stack with non-tail call recursion, or having a counter with iteration. – Pete Kirkham Aug 2 '12 at 14:53
@AndreyT you say "a valid way to turn recursive algorithm onto a tail-recursive or iterative one" but the two concepts are not the same at all. you conflate tail recursion as a syntactic property of a code with the process described by that code being iterative or not. you're absolutely right, TR code can describe a recursive, i.e. no-iterative process. but the question was about re-writing of code. this re-write is syntactical, it does not change the nature of the algorithm at hand. double-rec fibonacci can be made linear, but that is algorithmic change, rearranging the information flow. – Will Ness Aug 6 '12 at 7:38

No it can be done "naturally" only for calls with one recursive call. For two or more recursive calls you can of course mimic stack frame yourself. But it will be very ugly and will effectively won't be tail recursive, in the sense of optimizing memory.

The point with tail-recursion is you don't want to come back to parent stack. So simply pass on that information to child stack which can completely replace parent stack, instead of stack growing.

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Sorry, this is simply false. It is a fact that all programs can be rewritten as tail calls using continuations. – Pete Kirkham Aug 1 '12 at 21:04
@Pete - while using constant memory? That's the question. – Fakrudeen Aug 2 '12 at 7:29
It wasn't the question asked. I've added a comment, but having written interpreters and compilers using CPS there is no problem using continuations to transform any recursive algorithm into a tail call one with the same space requirements. If your recursive algorithm was constant memory, then the CPS tail call version will be. If it consumed 'stack' space, the CPS tail call version will consume a similar amount of 'heap' space. – Pete Kirkham Aug 2 '12 at 10:51
@PeteKirkham - if it takes the same memory why bother? – Fakrudeen Aug 3 '12 at 6:14
In compilers, rewriting everything to tail calls means you only have to write your optimisations for one form of control flow. In actor based languages, having explicit continuations means you can create massive concurrency. In garbage collected environments, it means you don't have to treat the stack and heap differently, and can reclaim stack space as part of normal gc. In environments where the stack size is smaller than the heap, you can operate on more deeply nested constructs. – Pete Kirkham Aug 3 '12 at 9:50