# Anonymous recursive function in Scala

Is there a way to write an anonymous function that is recursive in Scala? I'm thinking of something like this:

((t: Tree) => {
print(t.value);
for (c <- t.children)
thisMethod(c)
})(root)

(Related question: Which languages support *recursive* function literals / anonymous functions?)

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As described in the link you posted. You can use Y-combinator. Here is example:

scala> def fix[A,B](f: (A=>B)=>(A=>B)): A=>B = f(fix(f))(_)
fix: [A,B](f: ((A) => B) => (A) => B)(A) => B

scala> val fact = fix[Int,Int](f => a => if(a<=0) 1 else f(a-1) * a)
fact: (Int) => Int = <function1>

scala> fact(12)
res0: Int = 479001600

Note it doesn't work with big numbers. Be careful with tail call optimization.

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Wow, amaizing. Thanks. –  aioobe Mar 17 '11 at 11:55
"Amazing" in the original sense of making me feel like I'm lost in a maze. fix is a function takes as input a function that itself takes a single argument and returns another function that takes a single argument, and then it ... OK, I'm going to need a better explanation from somebody... –  Malvolio Mar 17 '11 at 22:59
But this does not allow tail call optimization, am I correct? –  x3ro Jun 2 '11 at 21:36
@Malvolio: fix is a function which takes another function f as its argument and returns a fixed point for that function, i.e. a value x for which f(x) == x. Functions which compute fixed points for other functions are called fixed point combinators. The Y-combinator is just one example of a fixed point combinator. Fixed point combinators offer a way to describe recursion in languages such as the lambda calculus which don't allow self-referential definitions. –  Tom Crockett Jun 25 '11 at 1:14

If you don't want to hit the "Amazing mathematics" you could just revert to the object aspects of scala.

val fact = new Function1[Int,Int]{
def apply(x:Int):Int = if(x==1) x else x * apply(x-1)
}
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in order to make it look geekier you can also use this code style:

val fact = new ((Int) => Int){
def apply(x:Int):Int = if(x==1) x else x * apply(x-1)
}
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Adding to the many good responses here in this thread, the fact that Scala is not giving us tail call optimizable Fixed-point combinator has been bothering me so much so that I've decided to write a macro to translate Y-combinator-like call to an ordinary, idiomatic recursive call (with tail call optimization, of course). The idea is that a call like

fix[Int,Int]((next) => (y) => ...body...)

({(input) =>
object next {
def apply(y:Int):Int = ...body...
}
next(input)
})

I've put up macro implementation targeting Scala 2.11 (with minor tweak should also work with 2.10) into this gist.

With this macro, we can perform ordinary recursive tasks in anonymous manner without fearing stack overflow e.g.

import asia.blip.ymacro.YMacro._
(y[BigInt,BigInt]((xx) => (y) => if(y==1) 1 else y * xx(y-1)))(2000)

gives

res0: BigInt = 33162750924506332411753933805763240382811...
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