# Composing function composition: How does (.).(.) work?

`(.)` takes two functions that take one value and return a value:

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

Since `(.)` takes two arguments, I feel like `(.).(.)` should be invalid, but it's perfectly fine:

``````(.).(.) :: (b -> c) -> (a -> a1 -> b) -> a -> a1 -> c
``````

What is going on here? I realize this question is badly worded...all functions really just take one argument thanks to currying. Maybe a better way to say it is that the types don't match up.

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`(.)` actually takes one argument and returns a function that takes one argument. –  Wes Jul 11 '13 at 8:02
@Wes deending on how you look at it, you could say it takes three arguments `(.) f g a = f (g a)` –  Ingo Jul 11 '13 at 10:40
good point, because `(.) (+1) (*2) 3` works :) –  Wes Jul 11 '13 at 13:48
You should read Conal Elliott's Semantic Editor Combinators where this is called `(return.return)`, with `return = (.)` to get the general idea of this sort of thing. –  AndrewC Jul 15 '13 at 20:12
@AndrewC is right. For another summary of SEC's see luqui's nice answer to another question. –  ntc2 Dec 31 '13 at 13:46

Let's first play typechecker for the mechanical proof. I'll describe an intuitive way of thinking about it afterward.

I want to apply `(.)` to `(.)` and then I'll apply `(.)` to the result. The first application helps us to define some equivalences of variables.

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

let b = (b' -> c')
c = (a' -> b') -> a' -> c'

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

Then we begin the second, but get stuck quickly...

``````let a = (b'' -> c'')
``````

This is key: we want to `let b = (a'' -> b'') -> a'' -> c''`, but we already defined `b`, so instead we must try to unify --- to match up our two definitions as best we can. Fortunately, they do match

``````UNIFY b = (b' -> c') =:= (a'' -> b'') -> a'' -> c''
which implies
b' = a'' -> b''
c' = a'' -> c''
``````

and with those definitions/unifications we can continue the application

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

then expand

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

and clean it up

``````substitute b'' -> b
c'' -> c
a'  -> a
a'' -> a1

(.).(.) :: (b -> c) -> (a -> a1 -> b) -> (a -> a1 -> c)
``````

which, to be honest, is a bit of a counterintuitive result.

Here's the intuition. First take a look at `fmap`

``````fmap :: (a -> b) -> (f a -> f b)
``````

it "lifts" a function up into a `Functor`. We can apply it repeatedly

``````fmap.fmap.fmap :: (Functor f, Functor g, Functor h)
=> (a -> b) -> (f (g (h a)) -> f (g (h b)))
``````

allowing us to lift a function into deeper and deeper layers of `Functors`.

It turns out that the data type `(r ->)` is a `Functor`.

``````instance Functor ((->) r) where
fmap = (.)
``````

which should look pretty familiar. This means that `fmap.fmap` translates to `(.).(.)`. Thus, `(.).(.)` is just letting us transform the parametric type of deeper and deeper layers of the `(r ->)` `Functor`. The `(r ->)` `Functor` is actually the `Reader` `Monad`, so layered `Reader`s is like having multiple independent kinds of global, immutable state.

Or like having multiple input arguments which aren't being affected by the `fmap`ing. Sort of like composing a new continuation function on "just the result" of a (>1) arity function.

It's finally worth noting that if you think this stuff is interesting, it forms the core intuition behind deriving the Lenses in Control.Lens.

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Holy balls. Your intuition section suddenly made this a lot more clear. –  Vlad the Impala Jul 11 '13 at 21:38
Haha, I'm glad! It's definitely the "right" way to think about it :) –  J. Abrahamson Jul 11 '13 at 21:47
Hi J. Abrahamson, I don't follow your step of "((.) (.) (.) :: (b'' -> c'') -> (a' -> b') -> (a' -> c'))", which I highlighted in my question/answer stackoverflow.com/questions/24029422/how-to-derive-the-type-of Any pointer will be greatly appreciated! –  Jerry Jun 4 at 7:00
That's me using the unification results from a few steps prior which unified `b' = a'' -> b''` and `c' = a'' -> c''`. It had to hold to get this far, so replacing expressions with their unions is a valid step. –  J. Abrahamson Jun 4 at 9:41

Let’s ignore types for a moment and just use lambda calculus.

• Desugar infix notation:
`(.) (.) (.)`

• Eta-expand:
`(\ a b -> (.) a b) (\ c d -> (.) c d) (\ e f -> (.) e f)`

• Inline the definition of `(.)`:
`(\ a b x -> a (b x)) (\ c d y -> c (d y)) (\ e f z -> e (f z))`

• Substitute `a`:
`(\ b x -> (\ c d y -> c (d y)) (b x)) (\ e f z -> e (f z))`

• Substitute `b`:
`(\ x -> (\ c d y -> c (d y)) ((\ e f z -> e (f z)) x))`

• Substitute `e`:
`(\ x -> (\ c d y -> c (d y)) (\ f z -> x (f z)))`

• Substitute `c`:
`(\ x -> (\ d y -> (\ f z -> x (f z)) (d y)))`

• Substitute `f`:
`(\ x -> (\ d y -> (\ z -> x (d y z))))`

• Resugar lambda notation:
`\ x d y z -> x (d y z)`

And if you ask GHCi, you’ll find that this has the expected type. Why? Because the function arrow is right-associative to support currying: the type `(b -> c) -> (a -> b) -> a -> c` really means `(b -> c) -> ((a -> b) -> (a -> c))`. At the same time, the type variable `b` can stand for any type, including a function type. See the connection?

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Can you explain a bit how to use this `boobs operator`? –  eccstartup Dec 24 '13 at 15:08
@eccstartup: `(.:) = (.) . (.); countWhere = length .: filter; countWhere = (length .) . filter; countWhere (>5) [1..10] == 5` –  Jon Purdy Dec 24 '13 at 18:47

Here is a simpler example of the same phenomenon:

``````id :: a -> a
id x = x
``````

The type of id says that id should take one argument. And indeed, we can call it with one argument:

``````> id "hello"
"hello"
``````

But it turns out what we can also call it with two arguments:

``````> id not True
False
``````

Or even:

``````> id id "hello"
"hello"
``````

What is going on? The key to understanding `id not True` is to first look at `id not`. Clearly, that's allowed, because it applies id to one argument. The type of `not` is `Bool -> Bool`, so we know that the `a` from id's type should be `Bool -> Bool`, so we know that this occurrence of id has type:

``````id :: (Bool -> Bool) -> (Bool -> Bool)
``````

Or, with less parentheses:

``````id :: (Bool -> Bool) -> Bool -> Bool
``````

So this occurrence of id actually takes two arguments.

The same reasoning also works for `id id "hello"` and `(.) . (.)`.

-

You're right, `(.)` only takes two arguments. You just seem to be confused with the syntax of haskell. In the expression `(.).(.)`, it's in fact the dot in the middle that takes the other two dots as argument, just like in the expression `100 + 200`, which can be written as `(+) 100 200`.

``````(.).(.) === (number the dots)
(1.)2.(3.) === (rewrite using just syntax rules)
(2.)(1.)(3.) === (unnumber and put spaces)
(.) (.) (.) ===
``````

And it should be even more clear from `(.) (.) (.)` that the first `(.)` is taking the second `(.)` and third `(.)` as it's arguments.

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Right, I'm clear on that. My point is, the first argument has the type `(b -> c)`, which is not `(.)`'s type. –  Vlad the Impala Jul 11 '13 at 5:52
@VladtheImpala, the type of `(.)` is `(y -> z) -> (x -> y) -> (x -> z)`. If you let `b` be `(y -> z)` and `c` be `(x -> y) -> (x -> z)`, you'll see that the two types are compatible after all. –  amalloy Jul 11 '13 at 7:10

This is one of those neat cases where I think it's simpler to grasp the more general case first, and then think about the specific case. So let's think about functors. We know that functors provide a way to map functions over a structure --

``````class Functor f where
fmap :: (a -> b) -> f a -> f b
``````

But what if we have two layers of the functor? For example, a list of lists? In that case we can use two layers of `fmap`

``````>>> let xs = [[1,2,3], [4,5,6]]
>>> fmap (fmap (+10)) xs
[[11,12,13],[14,15,16]]
``````

But the pattern `f (g x)` is exactly the same as `(f . g) x` so we could write

``````>>> (fmap . fmap) (+10) xs
[[11,12,13],[14,15,16]]
``````

What is the type of `fmap . fmap`?

``````>>> :t fmap.fmap
:: (Functor g, Functor f) => (a -> b) -> f (g a) -> f (g b)
``````

We see that it maps over two layers of functor, as we wanted. But now remember that `(->) r` is a functor (the type of functions from `r`, which you might prefer to read as `(r ->)`) and its functor instance is

``````instance Functor ((->) r) where
fmap f g = f . g
``````

For a function, `fmap` is just function composition! When we compose two `fmap`s we map over two levels of the function functor. We initially have something of type `(->) s ((->) r a)`, which is equivalent to `s -> r -> a`, and we end up with something of type `s -> r -> b`, so the type of `(.).(.)` must be

``````(.).(.) :: (a -> b) -> (s -> r -> a) -> (s -> r -> b)
``````

which takes its first function, and uses it to transform the output of the second (two-argument) function. So for example, the function `((.).(.)) show (+)` is a function of two arguments, that first adds its arguments together and then transforms the result to a `String` using `show`:

``````>>> ((.).(.)) show (+) 11 22
"33"
``````

There is then a natural generalization to thinking about longer chains of `fmap`, for example

``````fmap.fmap.fmap ::
(Functor f, Functor g, Functor h) => (a -> b) -> f (g (h a)) -> f (g (h b))
``````

which maps over three layers of functor, which is equivalent to composing with a function of three arguments:

``````(.).(.).(.) :: (a -> b) -> (r -> s -> t -> a) -> (r -> s -> t -> b)
``````

for example

``````>>> import Data.Map
>>> ((.).(.).(.)) show insert 1 True empty
"fromList [(1,True)]"
``````

which inserts the value `True` into an empty map with key `1`, and then converts the output to a string with `show`.

These functions can be generally useful, so you sometimes see them defined as

``````(.:) :: (a -> b) -> (r -> s -> a) -> (r -> s -> b)
(.:) = (.).(.)
``````

so that you can write

``````>>> let f = show .: (+)
>>> f 10 20
"30"
``````

Of course, a simpler, pointful definition of `(.:)` can be given

``````(.:) :: (a -> b) -> (r -> s -> a) -> (r -> s -> b)
(f .: g) x y = f (g x y)
``````

which may help to demystify `(.).(.)` somewhat.

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Cool! Those examples are interesting and helpful! –  eccstartup Dec 24 '13 at 15:15

Yes this is due to currying. `(.)` as all functions in Haskell only takes one argument. What you are composing is the first partial call to each respective composed `(.)` which takes its first argument (the first function of the composition).

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