# What does '((->) a)' mean?

I've seen this type before without knowing what it means. Does it mean something and/or does it have a name?

``````Prelude> :m Data.Functor
Prelude Data.Functor> :t flip . (flip (<\$>))
flip . (flip (<\$>))
:: Functor ((->) b) => (b -> a) -> b -> (a -> c) -> c
``````
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It's the ordinary function arrow written in prefix form. That is, `(->) a b` is the same as `a -> b`. –  Vitus Dec 17 '12 at 0:43
If you like `(3+)` instead of `((+) 3)`, you can think of `((->) a)` as `(a ->)` - even though that's not valid syntax, it gives you an idea of what it is. –  AndrewC Dec 17 '12 at 22:19

To add to Matt Fenwick and josefg's more technical answers, the `((->) a` can be read as the type constructor that forms values that depend on an `a`. One example: suppose you have teams whose membership varies over time. One possible way to represent this is like this:

``````-- | The type of a's that depend on a point in time, using t as the timeline type.
type Historical t a = t -> a

observe :: Historical t a -> t -> a
observe = (\$)

-- | The membership of a team is a list of persons whose composition can change
-- from day to day.
membership :: Team -> Historical Day [Person]
membership = ...
``````

`((->) a)` is a `Functor`, `Applicative` and `Monad`, which means that the type class operations are available, and they have very useful interpretations when used with `Historical t`.

First example: `fmap` applies a function to a time-dependent value. So for example,

``````-- The number of persons in a Team, depending on the Day:
membershipCount :: Team -> Historical Day Int
membershipCount = fmap length . membership
``````

The Applicative `<*>` operation gives you simultaneity:

``````-- The joint membership of team1 and team2, depending on the Day:
(++) <\$> membership team1 <*> membership team2 :: Historical Day [Person]
``````

Though actually, since we have `instance Monoid [a]` and `instance Monoid m => Monoid t -> m`, the previous example can be written like this:

``````import Data.Monoid

membership team1 ++ membership team2
``````

``````personToManager :: Person -> Historical Day Manager
personToManager = ...

managerToVP :: Manager -> Historical Day VP
managerToVP = ...

personToVP :: Person -> Historical Day VP
personToVP p = personToManager p >>= managerToVP
``````

Note also that `((->) r` is exactly the same as the `Reader r` monad. If you understand the code above you pretty much understand `Reader`.

EDIT: I should clarify that time-dependent values is just one use of the function/Reader monad. There are other uses; the classic example use case of the Reader monad is to thread configuration values through a computation. It's got rather more uses than just that, as the example above shows.

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Actually, `((->) a)` is not a type but a partially applied type constructor.

Just like functions, type constructors can be partially applied in Haskell.

You can check the kind of something in GHCi:

``````ghci> :k (->)
(->) :: * -> * -> *

ghci> :k (->) Int
(->) Int :: * -> *
``````

All values have types of kind `*`; type constructors have kinds like `* -> *`, `* -> * -> *`, etc.

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Pedantry mode: all values have types of kind `*`. –  Daniel Wagner Dec 17 '12 at 1:31
@Daniel thank you; fixed. –  Matt Fenwick Dec 17 '12 at 12:29
In Haskell, `(->) a` is from `a -> something`. Remember that you can turn an operator to a prefixed function by using parans. ie `(+) 1 1 == 2`. So in this case the "operator" is the type constructor `->`. It's used this way because a functor needs a type constructor with 1 variable, but `->` has 2. So we partially apply it.
It may help you to realize that `<\$>` for `((->) a)` is just `(.)`
I see, so `((->) a)` has type `*->*`? –  Carlos Eduardo López Camey Dec 17 '12 at 0:46
To be a bit more explicit, I would add that `(->)` has kind `* -> * -> *` while `(->) a` has kind `* -> *`. –  Jon Purdy Dec 17 '12 at 0:47
@Carlos no, `((->) a` is not a type! But if you s/type/kind/, it's correct. –  Matt Fenwick Dec 17 '12 at 0:47