Welcome to OGeek Q&A Community for programmer and developer-Open, Learning and Share
Welcome To Ask or Share your Answers For Others

Categories

0 votes
530 views
in Technique[技术] by (71.8m points)

f# - How do I define y-combinator without "let rec"?

In almost all examples, a y-combinator in ML-type languages is written like this:

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

This works as expected, but it feels like cheating to define the y-combinator using let rec ....

I want to define this combinator without using recursion, using the standard definition:

Y = λf·(λx·f (x x)) (λx·f (x x))

A direct translation is as follows:

let y = fun f -> (fun x -> f (x x)) (fun x -> f (x x));;

However, F# complains that it can't figure out the types:

  let y = fun f -> (fun x -> f (x x)) (fun x -> f (x x));;
  --------------------------------^

C:UsersJulietAppDataLocalTempstdin(6,33): error FS0001: Type mismatch. Expecting a
    'a    
but given a
    'a -> 'b    
The resulting type would be infinite when unifying ''a' and ''a -> 'b'

How do I write the y-combinator in F# without using let rec ...?

See Question&Answers more detail:os

与恶龙缠斗过久,自身亦成为恶龙;凝视深渊过久,深渊将回以凝视…
Welcome To Ask or Share your Answers For Others

1 Reply

0 votes
by (71.8m points)

As the compiler points out, there is no type that can be assigned to x so that the expression (x x) is well-typed (this isn't strictly true; you can explicitly type x as obj->_ - see my last paragraph). You can work around this issue by declaring a recursive type so that a very similar expression will work:

type 'a Rec = Rec of ('a Rec -> 'a)

Now the Y-combinator can be written as:

let y f =
  let f' (Rec x as rx) = f (x rx)
  f' (Rec f')

Unfortunately, you'll find that this isn't very useful because F# is a strict language, so any function that you try to define using this combinator will cause a stack overflow. Instead, you need to use the applicative-order version of the Y-combinator (f.(x.f(y.(x x)y))(x.f(y.(x x)y))):

let y f =
  let f' (Rec x as rx) = f (fun y -> x rx y)
  f' (Rec f')

Another option would be to use explicit laziness to define the normal-order Y-combinator:

type 'a Rec = Rec of ('a Rec -> 'a Lazy)
let y f =
  let f' (Rec x as rx) = lazy f (x rx)
  (f' (Rec f')).Value

This has the disadvantage that recursive function definitions now need an explicit force of the lazy value (using the Value property):

let factorial = y (fun f -> function | 0 -> 1 | n -> n * (f.Value (n - 1)))

However, it has the advantage that you can define non-function recursive values, just as you could in a lazy language:

let ones = y (fun ones -> LazyList.consf 1 (fun () -> ones.Value))

As a final alternative, you can try to better approximate the untyped lambda calculus by using boxing and downcasting. This would give you (again using the applicative-order version of the Y-combinator):

let y f =
  let f' (x:obj -> _) = f (fun y -> x x y)
  f' (fun x -> f' (x :?> _))

This has the obvious disadvantage that it will cause unneeded boxing and unboxing, but at least this is entirely internal to the implementation and will never actually lead to failure at runtime.


与恶龙缠斗过久,自身亦成为恶龙;凝视深渊过久,深渊将回以凝视…
OGeek|极客中国-欢迎来到极客的世界,一个免费开放的程序员编程交流平台!开放,进步,分享!让技术改变生活,让极客改变未来! Welcome to OGeek Q&A Community for programmer and developer-Open, Learning and Share
Click Here to Ask a Question

...