# Is it possible to use call/cc to implement recursion?

I wonder if it is possible to define a recursive function without calling the function itself in its body but somehow using call/cc instead? Thanks.

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You can implement a Y combinator using `call/cc`, as described here. (Many thanks to John Cowan for mentioning this neat post!) Quoting that post, here's Oleg's implementation:

Corollary 1. Y combinator via `call/cc` -- Y combinator without an explicit self-application.

``````(define (Y f)
((lambda (u) (u (lambda (x) (lambda (n) ((f (u x)) n)))))
(call/cc (call/cc (lambda (x) x)))))
``````

Here, we used a fact that

``````((lambda (u) (u p)) (call/cc call/cc))
``````

and

``````((lambda (u) (u p)) (lambda (x) (x x)))
``````

are observationally equivalent.

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Amazing, exactly what I want. Thanks a lot. –  day Mar 30 '12 at 8:08
@wberry I've decided to find a way to quote that code snippet that's hopefully more "fair use"-compliant. –  Chris Jester-Young May 21 at 20:33
Very good, thank you. –  wberry May 22 at 15:29

Your question is a bit vague. In particular, it sounds like you want a system that models recursive calls without directly making recursive calls, using call/cc. It turns out, though, that you can model recursive calls without making recursive calls and also without using call/cc. For instance:

``````#lang racket

(define (factorial f n)
(if (= n 0) 1 (* n (f f (- n 1)))))

(factorial factorial 3)
``````

That may seem like cheating, but it's the foundation of the Y combinator. Perhaps you can tighten up the set of restrictions you're thinking of?

P.S.: if this is homework, please cite me!

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Well, I have already known this trick to do recursion. What I wonder is if a non-self-referring way using call/cc exists to define a recursive function, say your `factorial`. This is not a homework exercise! Thanks. –  day Mar 29 '12 at 17:16
@plmday John's solution is already not self-referencing. What more would you need from `call/cc`? –  Sam Tobin-Hochstadt Mar 29 '12 at 18:50
@SamTobin-Hochstadt Well, it is, `f` refers to itself, doesn't it? I wanna see how far we can go with `call/cc`, in particular, given its ability, can we employ it to simulate the usual or unusual way of defining a recursive function. –  day Mar 29 '12 at 20:33
What do your mean by "refer to itself"? Self-reference in a (self-) recursive function definition is of this form: you have a function definition whose body contains an occurrence of an identifier that's lexically bound to the enclosing function itself. The definition of `factorial` that John provides does not have `factorial` appearing in the body, nor any identifier that's lexically bound to it. –  Luis Casillas Mar 29 '12 at 21:49
Ah, OK, you are right. I mixed it with self-application. Thanks for clarifying it. –  day Mar 30 '12 at 8:25
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I'm afraid `call/cc` doesn't really have much to do with this. There really are only two ways of defining a recursive function:

• Suppose your language allows recursive function definitions; i.e., a function body can refer to the enclosing function, or the body of a function `f` can refer to a function `g` whose body refers to `f`. In this case, well, you just write it in the usual way.
• If your language forbids both of these, but it still has first-class functions and lambdas, then you can use a fixed-point combinator like the Y combinator. You write your function so that it takes as an extra argument a function that's meant to represent the recursive step; every place where you would recurse, instead you invoke that argument.

So for `factorial`, you write it like this:

``````(define (factorial-step recurse n)
(if (zero? n)
1
(* n (recurse (- n 1)))))
``````

The magic of the Y combinator is that it constructs the `recurse` function that would be fed to `factorial-step`.

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