Well, `y`

has to be of type `(a -> b) -> c`

, for some `a`

, `b`

and `c`

we don't know yet; after all, it takes a function, `f`

, and applies it to an argument, so it must be a function taking a function.

Since `y f = f x`

(again, for some `x`

), we know that the return type of `y`

must be the return type of `f`

itself. So, we can refine the type of `y`

a bit: it must be `(a -> b) -> b`

for some `a`

and `b`

we don't know yet.

To figure out what `a`

is, we just have to look at the type of the value passed to `f`

. It's `y f`

, which is the expression we're trying to figure out the type of right now. We're saying that the type of `y`

is `(a -> b) -> b`

(for some `a`

, `b`

, etc.), so we can say that this application of `y f`

must be of type `b`

itself.

So, the type of the argument to `f`

is `b`

. Put it all back together, and we get `(b -> b) -> b`

— which is, of course, the same thing as `(a -> a) -> a`

.

Here's a more intuitive, but less precise view of things: we're saying that `y f = f (y f)`

, which we can expand to the equivalent `y f = f (f (y f))`

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

, and so on. So, we know that we can always apply another `f`

around the whole thing, and since the "whole thing" in question is the result of applying `f`

to an argument, `f`

has to have the type `a -> a`

; and since we just concluded that the whole thing is the result of applying `f`

to an argument, the return type of `y`

must be that of `f`

itself — coming together, again, as `(a -> a) -> a`

.

`?banner=none`

to Wikipedia URLs :) – ehird Jan 18 '12 at 23:59`λf.(λx.f (x x)) (λx.f (x x))`

. However, this cannot be simply typed in Haskell (and is impossible to type in simply-typed lambda calculus; pun intended). The need for self application`(x x)`

requires recursion at type level. In Haskell, you can avoid type recursion`a = a -> a`

by wrapping it into`newtype Rec a = In { out :: Rec a -> a }`

. – Vitus Jan 19 '12 at 9:30