# Rosetta Stone: Y-combinator

The Y-combinator is defined as:

``````Y = λf. (λx. f (x x)) (λx. f (x x))
``````

Using this combinator, you can write recursive lambda functions or intercept recursive methods with custom code.

How is the Y-combinator written in various languages?

I'd be interested in seeing the Y-combinator defined and used to implement a recursive factorial function. For example, in F#:

``````let rec y f x = f (y f) x
let factorial = y (fun f -> function 0 -> 1 | n -> n * f(n - 1))
``````

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I want to see one in written in DOS batch files. –  Tamas Czinege Jan 5 '10 at 12:47
I've finally put a finger on what didn't sit right with me when I looked at your F# version: the `Y` function is supposed to be completely standalone, being able to function (pun intended) without referring to any external symbols, including the symbol `Y`. It'd be cool to see a version in F# that does just that. :-D –  Chris Jester-Young Jan 5 '10 at 13:01
F# simply can't without losing static types. I wonder whether Haskell can ... –  Dario Jan 5 '10 at 13:59
@Chris: I actually asked a question about writing the Y-combinator without `let rec...`: stackoverflow.com/questions/1998407/… . It turns out you can't write `Y` in a statically typed language without jumping through a lot of hoops. –  Juliet Jan 6 '10 at 18:58
@Juliet: Static typing putting roadblocks up again? :-P (I thought that Wikipedia had an example of Y combinator for typed lambda calculus, but I don't know how that relates (or not) to statically typed languages or what not.) –  Chris Jester-Young Jan 6 '10 at 21:11

# PostScript

The Y combinator as a nameless function with no explicit variable bindings (squeezed to fit on one line :D):

``````{[{[exch{dup exec exec}aload pop]cvx exec}aload pop 10 9 roll exch]cvx dup exec}
``````

Actually, this is the applicative-order Y combinator, adapted from Scheme.

As an example, here's how to use it to compute the factorial of a nonnegative integer:

``````%%% Read from stdin (input should be a nonnegative integer)
(%stdin) run

%%% Factorializer -- a function that takes a function as input;
%%% this computes the factorial by doing everything except the recursive step
%%% and then calling the input function as the recursive step
{[{dup 0 eq exch {1} exch [exch dup 1 sub exec mul} aload pop
[6 1 roll 16 15 roll 3 1 roll] cvx {aload pop] cvx ifelse} aload pop] cvx}

%%% Y combinator -- takes the factorializer as input and returns a function that
%%% computes the factorial of any nonnegative integer
{[{[exch {dup exec exec} aload pop] cvx exec} aload pop 10 9 roll exch]
cvx dup exec}

%%% Apply Y combinator to factorializer to produce factorial function;
%%% then apply factorial function to input number and print the result
exec exec =
``````

Usage: `\$ echo 20 | gs -q -dNODISPLAY -dNOPROMPT -dBATCH thisfile.ps`

Output: `2432902008176640000`

No iterative looping constructs, no function names, not even local variable bindings.*

PostScript is the ultimate functional programming language.

*You can also use any of these in PostScript, but this nameless version is way cool.

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Nuts, totally nuts! You PS people are crazy! –  leppie Jan 5 '10 at 12:35
This is absolutely outrageous. I can't possibly put it into words any other way. –  Tamas Czinege Jan 5 '10 at 12:46

``````y f = f (y f)
``````

With type

``````y :: (a -> a) -> a
``````

Usage:

``````fact = y (\f n -> if n <= 1 then 1 else n * f (n - 1))
``````
-
Try making an "anonymous lambda" version of the Y combinator. It's much more fun that way. :-) –  Chris Jester-Young Jan 5 '10 at 13:05
I'm trying - Apparently it needs to make heavy use of higher-ranked types in order to preserve Haskell's static typing ... –  Dario Jan 5 '10 at 13:07
Oh yeah...ouch! And good luck! :-D –  Chris Jester-Young Jan 5 '10 at 13:29
–  Greg Bacon Jan 5 '10 at 16:20
In other words, `Control.Monad.Fix.fix`? –  ephemient Nov 28 '10 at 3:39
show 1 more comment

Here's a single-argument Y-combinator in C#:

``````public static Func<T, U> YCombinator<T, U>(Func<Func<T, U>, Func<T, U>> f) {
return yc => x => f(yc(yc)(f))(x);
}
``````

Your factorial example would look like this:

``````Func<Func<int, int>, Func<int, int>> factorial =
(inject) => (x) => x == 0 ? 1 : x * inject(x - 1);
``````

This isn't the only way to do it, of course. Here's a much more comprehensive example.

-
Try writing a version that doesn't refer back to its original name. :-) i.e., `YCombinator` should not make any references to the name `YCombinator` in its definition. –  Chris Jester-Young Jan 5 '10 at 12:56

Ruby version based on my R version:

``````def Y
lambda {|f| f.call(f)}.call(lambda {|f| yield lambda {|x| f.call(f).call(x)}})
end
``````

Example:

``````def factorial
lambda {|x| x < 2 ? 1 : x * yield(x - 1)}
end

Y {|f| factorial &f}.call(5)    # should return 120
``````
-

R version based on The Little Schemer:

``````Y <- function (fun) (function (f) f(f))(function (f) fun(function (x) f(f)(x)))
``````

Quick example:

``````factorial <- function (fun) (function (x) if (x < 2) 1 else x * fun(x - 1))
Y(factorial)(5)    # should return 120
``````
-

## Lua

``````y = function (f)
local function g(h) return f (function (x) return (h(h))(x) end) end
return g(g)
end
``````

Example:

``````fac = function (f)
return function (x) if x < 2 then return x else return x * f(x-1) end end
end

=y(fac)(5) -- should print 120
``````
-

JavaScript version based on my R version; most of the verbosity comes from all the `return` keywords:

``````Y = function (fun) {
return (function (f) {return f(f)})(function (f) {return fun(function (x) {return f(f)(x)})})
}
``````

Example:

``````factorial = function (fun) {
return function (x) {return x < 2 ? 1 : x * fun(x - 1)}
}

Y(factorial)(5)    # should return 120
``````

## JavaScript 1.8 (SpiderMonkey)

Strips out all the verbose `return` and makes it even more fun to read!

``````Y=function(fun)(function(f)f(f))(function(f)fun(function(x)f(f)(x)))
factorial=function(fun)function(x)x<2?1:x*fun(x-1);
Y(factorial)(5)
``````
-

PHP 5.3

``````function Y(\$F) {
\$func =  function (\$f) { return \$f(\$f); };
return \$func(function (\$f) use(\$F) {
return \$F(function (\$x) use(\$f) {
\$ff = \$f(\$f);
return \$ff(\$x);
});
});
}
``````
-

I had some trouble mapping some of these implementations to the Y-combinator definition given in the question. The obvious translation to Perl looped. Then I discovered, with the help of the Wikipedia article on fixed point combinators, that this definition assumes call-by-name or lazy evaluation. For call-by-value languages, such as Scheme, C, and Perl, you need an extra layer of lambda to make it work. The Wikipedia article calls this fixed point combinator Z.

``````Y = λf. (λx. f (x x)) (λx. f (x x))
Z = λf. (λx. f (λy. x x y)) (λx. f (λy. x x y))
``````

Here is an implementation in Perl.

``````# Y-combinator, implemented as Z above since Perl is call by value.
\$Y = sub { my (\$f) = @_;
# g is shorthand for the repeated lambda x function in Z
my \$g = sub { my (\$x) = @_;
\$f->(sub { my (\$y) = @_;
\$x->(\$x)->(\$y) }) };
\$g->(\$g) };

# Factorial function for use with Y-combinator
\$F = sub { my (\$fact) = @_;
sub { my (\$n) = @_;
\$n <= 0 ? 1 : \$n * \$fact->(\$n - 1) } };

printf "%d! => %d\n", 5, \$Y->(\$F)->(5);
``````

This isn't too hard to explain. The call \$Y->(\$F) produces the factorial function, which comes from Y's call to \$g passing itself as the argument, and inside \$g, \$x is bound to \$g as well, so \$x->(\$x) is the same as \$g->(\$g) and \$Y->(\$F). The factorial function comes from the lambda n returned by \$F, with \$fact properly bound. This result is also returned by \$g inside \$Y and then returned by \$Y itself. Finally, how is \$fact, referenced by the lambda n factorial function, properly bound? That is the lambda y, not the factorial function exactly, but one that uses \$x->(\$x) to get factorial and returns the result of passing factorial whatever it is passed.

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Perl

``````sub Y {
my \$h = shift;
my \$g = sub {
my \$f = shift;
return sub {
my \$n = shift;
\$h->( \$f->( \$f ) )->( \$n );
};
};
\$g->( \$g );
}

my \$fact = Y( sub {
my \$q = shift;
sub {
my \$n = shift;
return 1 if \$n < 2;
return \$n * \$q->( \$n - 1 );
}
}
);

print \$fact->( 10 ), "\n";
``````

My derivation of this is available at http://web.archiveorange.com/archive/v/bNpYiS0jF5zTwoayJQy0 "A derivation of the Y combinator implemented in perl".

This version only used '=' for initialization, mostly unpacking function arguments, which Perl 5 doesn't do for you.

The Y function is declared in the main namespace. This, and several other critiques could be fixed, but once I got to this point I stopped.

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Python (translated from Lua example above, still not completely sure how it works xD)

``````def y(f):
def g(h):
return f(lambda x: (h(h))(x))
return g(g)

#factorial example
fact = y(lambda f: (lambda x: x if x < 2 else x * f(x-1)))

fact(5) # returns 120
``````
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J Version (one line version)

``````1:`(]*\$:@<:) @. * "0 i.
``````

usage:

``````1:`(]*\$:@<:) @. * "0 i. 4
``````

result:

``````1 1 2 6
``````

reference:

http://www.jsoftware.com/help/dictionary/intro22.htm

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Scala: (taken from here)

``````def Y[A, B](f: (A => B) => (A => B)) = {
case class W(wf: W => A => B) {
def apply(w: W) = wf(w)
}
val g: W=>A=>B = w => f(w(w))(_)
g(W(g))
}
``````
-

This article shows how you can write a Y combinator in Java:

``````package com.google.functional;

import junit.framework.TestCase;

public class YCFun extends TestCase {
public static interface BranchType<F, T> extends
Function<BranchType<F, T>, Function<F, T>> {
}

public static <F, T> Function<Function<Function<F, T>,
Function<F, T>>, Function<F, T>> y() {
return new Function<Function<Function<F, T>, Function<F, T>>,
Function<F, T>>() {
public Function<F, T> apply(
final Function<Function<F, T>, Function<F, T>> f) {
return new BranchType<F, T>() {
public Function<F, T> apply(final BranchType<F, T> x) {
return f.apply(new Function<F, T>() {
public T apply(F y) {
return x.apply(x).apply(y);
}
});
}
}.apply(new BranchType<F, T>() {
public Function<F, T> apply(final BranchType<F, T> x) {
return f.apply(new Function<F, T>() {
public T apply(F y) {
return x.apply(x).apply(y);
}
});
}
});
}
};
}

// To get proper type inference
public static <F, T> Function<F, T> yapply(
final Function<Function<F, T>, Function<F, T>> f) {
return YCFun.<F, T> y().apply(f);
}

public void testFactorial() {
Function<Integer, Integer> factorial =
yapply(new Function<Function<Integer, Integer>,
Function<Integer, Integer>>() {
public Function<Integer, Integer> apply(
final Function<Integer, Integer> f) {
return new Function<Integer, Integer>() {
public Integer apply(Integer i) {
if (i <= 0) {
return 1;
} else {
return f.apply(i - 1) * i;
}
}
};
}
});
assertEquals(720, factorial.apply(6).intValue());
}
}
``````
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