# Haskell: Why is ((.).(.)) f g equal to f . g x?

Could you please explain the meaning of the expression ((.).(.))? As far as I know (.) has the type (b -> c) -> (a -> b) -> a -> c.

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`((.).(.)) f g` is not equal to `f . g x` (but `((.).(.)) f g x` is). –  Frerich Raabe Feb 5 '13 at 13:06

`(.) . (.)` is the composition of the composition operator with itself.

If we look at

``````((.) . (.)) f g x
``````

we can evaluate that a few steps, first we parenthesise,

``````((((.) . (.)) f) g) x
``````

then we apply, using `(foo . bar) arg = foo (bar arg)`:

``````~> (((.) ((.) f)) g) x
~> (((.) f) . g) x
~> ((.) f) (g x)
~> f . g x
``````

More principled,

``````(.) :: (b -> c) -> (a -> b) -> (a -> c)
``````

So, using `(.)` as the first argument of `(.)`, we must unify

``````b -> c
``````

with

``````(v -> w) -> (u -> v) -> (u -> w)
``````

That yields

``````b = v -> w
c = (u -> v) -> (u -> w)
``````

and

``````(.) (.) = ((.) .) :: (a -> v -> w) -> a -> (u -> v) -> (u -> w)
``````

Now, to apply that to `(.)`, we must unify the type

``````a -> v -> w
``````

with the type of `(.)`, after renaming

``````(s -> t) -> (r -> s) -> (r -> t)
``````

which yields

``````a = s -> t
v = r -> s
w = r -> t
``````

and thus

``````(.) . (.) :: (s -> t) -> (u -> r -> s) -> (u -> r -> t)
``````

and from the type we can (almost) read that `(.) . (.)` applies a function (of one argument) to the result of a function of two arguments.

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good old mental gymnastic –  David Unric Feb 5 '13 at 15:19

You've got an answer already, here's a slightly different take on it.

In combinatory logic `(.)` is B-combinator : `Babc = a(bc)`. When writing combinator expressions it is customary to assume that every identifier consists of one letter only, and omit white-space in application, to make the expressions more readable. Of course the usual currying applies: `abcde` is `(((ab)c)d)e` and vice versa.

`(.)` is B, so `((.) . (.))` == `(.) (.) (.)` == BBB. So,

``````BBBfgxy = B(Bf)gxy = (Bf)(gx)y = Bf(gx)y = (f . g x) y
abc        a  bc                 a b  c
``````

We can throw away both `y`s at the end (this is known as eta-reduction: `Gy=Hy` --> `G=H`, if `y` does not appear inside `H`1). But also, another way to present this, is

``````BBBfgxy = B(Bf)gxy = ((f .) . g) x y = f (g x y)     -- (.) f == (f .)
-- compare with:       (f .) g x = f (g x)
``````

`((f .) . g) x y` might be easier to type in than `((.).(.)) f g x y`, but YMMV.

1 For example, with S combinator, defined as `Sfgx = fx(gx)`, without regard for that rule we could write

``````Sfgx = fx(gx) = B(fx)gx = (f x . g) x
Sfg = B(fx)g = (f x . g)   --- WRONG, what is "x"?
``````

which is nonsense.

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