# What is the best way to realize `(->) ((->) a b)` as an applicative functor?

I'm working on Problem 19 in Ninety-Nine Haskell Problems, and I've encountered the following difficulty. The problem asks to "rotate a list N places to the left." This could easily be achieved in a pointed way, e.g.,

``````rotate :: [a] -> Int -> [a]
rotate xs n = drop n xs ++ take n xs
``````

However, for my own edification and for the challenge, I'd like to implement this in a point-free way using applicative functors. For instance, one can eliminate one of the arguments by using the fact that `(->) [a]` is an `Applicative` functor and implement `rotate` as follows:

``````rotate :: Int -> [a] -> [a]
rotate n = (++) <\$> drop n <*> take n
``````

Ideally, one should be able to eliminate both arguments, and write it as

``````rotate :: [a] -> Int -> [a]
rotate :: (++) <\$> drop <*> take
``````

but this causes a type error. (I'm not sure exactly how the type are being inferred, but the problem seems to be coming from the fact that the inferred `Applicative` functor is `(->) Int` rather than `(->) ((->) Int [a])`.)

One way to solve this would be to manually implement `(->) ((->) a b)` as an instance of `Applicative`, and, in particular, set

``````<*> f g x y = f x y (g x y)
``````

but it seems that there should be a cleaner way to do this inline. What is the "right" way to solve this problem?

• For what its worth, pointfree.io give `rotate = ap ((<*>) . ((++) <\$>) . drop) take`. Commented Aug 20, 2019 at 17:48
• You can always ask pointfree to do it for you. It uses `ap` instead of `<*>` but it's the same thing. Commented Aug 20, 2019 at 17:50
• Maybe I'm missing something, but it seems to me that `(->) (-> a) b` is not even a valid type, because `(->)` expects first type argument of kind `*`, but `(-> a) :: * -> *` Commented Aug 20, 2019 at 18:06
• Sorry, you're absolutely right. It should have been `(->) a (-> b)`. Thanks for the correction. Commented Aug 20, 2019 at 20:36
• @jgaeb `(->) a (-> b)` is also invalid (ill-kinded) since the second argument of `(->)` must have kind `*` but `(-> b)` has kind `* -> *`.
– chi
Commented Aug 20, 2019 at 21:12

There's an "optimal" way of doing this without using the Applicative instance.

``````import Data.Semigroup
rotate = drop <> take
``````

We can be explicit about the type `(<>)` is instantiated at

``````{-# Language ScopedTypeVariables #-}
{-# Language TypeApplications    #-}

rotate :: forall a. Int -> [a] -> [a]
rotate = (<>) @(Int -> [a] -> [a]) drop take
``````

Resolved using these instances:

``````instance Semigroup b => Semigroup (a -> b)
instance                Semigroup [a]
``````

Two choices:

``````rotate = liftA2 (liftA2 (++)) drop take
rotate = getCompose (liftA2 (++) (Compose drop) (Compose take))
``````

The latter becomes the former after inlining the instance method definitions for `Compose`'s `Applicative` instance.

You may revert to spelling your `liftA2`s with `(<\$>)` and `(<*>)` if you prefer it, of course.

• You can use curry and uncurry instead of getCompose and Compose. Not sure if it's more readable or less :) Commented Aug 20, 2019 at 18:40
• For the first, I've grown rather accustomed to the phrasing `(liftA2 . liftA2) (++) drop take`. It implies (correctly) that you can put as many `liftA2`s as you need to get an appropriate combinator. Commented Aug 21, 2019 at 6:02