# Writing in pointfree style f x = g x x

I am learning Haskell. I'm sorry for asking a very basic question but I cant seem to find the answer. I have a function f defined by :

f x = g x x


where g is an already defined function of 2 arguments. How do I write this pointfree style? Edit : without using a lambda expression.

Thanks

-

f can be written with Control.Monad.join:

f = join g


join on the function monad is one of the primitives used when constructing point-free expressions, as it cannot be defined in a point-free style itself (its SKI calculus equivalent, SIIap id id in Haskell — doesn't type).

-
I think you mean f = join g –  dflemstr Feb 6 '12 at 23:52
@user1188374, the join function is a fundamental function for monads, the monad in this case being the function monad, (->) r for some r. The definition of join :: Monad m => m (m a) -> m a; substituting (->) r for m yields join :: (r -> r -> a) -> (r -> a). –  dflemstr Feb 7 '12 at 0:01
@user1188374: join is a primitive of point-free style because the translation of SII to Haskell, ap id id, isn't valid — it has a type error (specifically, it fails the occurs check). It works in the SKI combinator calculus because it's untyped. –  ehird Feb 7 '12 at 0:04
join is equal to flip ap id, so it could be argued that it is not a primitive. Be aware that while some SKI expressions don't type, they are not usually unique, and sometimes an alternative will do better. For example, I = SKK = SKS, but of those two only ap const const has the type that you want. –  Ben Millwood Feb 16 '12 at 11:33
@misterbee it is declared in Control.Monad.Instances. –  dflemstr Feb 17 '12 at 0:40

This is known as "W" combinator:

import Control.Monad
import Control.Applicative

f = join g       -- = Wg          , or
= (g ap id)  -- = CSIg = SgI
= (<*> id) g


S,K,I are one basic set of combinators; B,C,K,W are another - you've got to stop somewhere (re: your "no lambda expression" comment):

_B = (.)     -- _B f g x = f (g x)     = S(KS)K
_C = flip    -- _C f x y = f y x       = S(S(K(S(KS)K))S)(KK)
_K = const   -- _K x y   = x
_W = join    -- _W f x   = f x x       = CSI = SS(KI) = SS(SK)
_S = ap      -- _S f g x = f x (g x)   = B(B(BW)C)(BB) = B(BW)(BBC)
= (<*>)                                -- from Control.Applicative
_I = id      -- _I x     = x           = WK = SKK = SKS = SK(...)

{-
Wgx = gxx
= SgIx = CSIgx
= Sg(KIg)x = SS(KI)gx
= gx(Kx(gx)) = gx(SKgx) = Sg(SKg)x = SS(SK)gx

-- _W (,) 5 = (5,5)
-- _S _I _I x = x x = _omega x         -- self-application, untypeable
-}

-
The stopping point is one combinator. One example is the ι (iota) combinator - λf.fSK, SKI is then expressed as S = ι(ι(ι(ιι))), K = ι(ι(ιι)) and I = ιι. This base is not so friendly for simply typed λ-calculus, ιι doesn't even typecheck. U = λf.fKSK is a bit better (I don't know if it has a name, so I'm just calling it U as universal); S = U(UU) and K = UUU –  Vitus Jun 15 '12 at 14:11
@Vitus yes, yes. It's more a question of convenience I guess, where to stop, in a practical setting. In Haskell for instance, it's convenient that we have SKI and BCKW combinators. –  Will Ness Jun 15 '12 at 14:33