Understanding `ap` in a point-free function in Haskell

I am able to understand the basics of point-free functions in Haskell:

``````addOne x = 1 + x
``````

As we see x on both sides of the equation, we simplify it:

``````addOne = (+ 1)
``````

Incredibly it turns out that functions where the same argument is used twice in different parts can be written point-free!

Let me take as a basic example the `average` function written as:

``````average xs = realToFrac (sum xs) / genericLength xs
``````

It may seem impossible to simplify `xs`, but http://pointfree.io/ comes out with:

``````average = ap ((/) . realToFrac . sum) genericLength
``````

That works.

As far as I understand this states that `average` is the same as calling `ap` on two functions, the composition of `(/) . realToFrac . sum` and `genericLength`

Unfortunately the `ap` function makes no sense whatsoever to me, the docs http://hackage.haskell.org/package/base-4.8.1.0/docs/Control-Monad.html#v:ap state:

``````ap :: Monad m => m (a -> b) -> m a -> m b

In many situations, the liftM operations can be replaced by uses of ap,
which promotes function application.

return f `ap` x1 `ap` ... `ap` xn

is equivalent to

liftMn f x1 x2 ... xn
``````

But writing:

``````let average = liftM2 ((/) . realToFrac . sum) genericLength
``````

does not work, (gives a very long type error message, ask and I'll include it), so I do not understand what the docs are trying to say.

How does the expression `ap ((/) . realToFrac . sum) genericLength` work? Could you explain `ap` in simpler terms than the docs?

• `let average = liftM2 ((/) . realToFrac) sum genericLength` works. – Ørjan Johansen Oct 31 '15 at 18:02
• @ØrjanJohansen Interesting, could you explain why in an answer? – Caridorc Oct 31 '15 at 18:08
• Have a look at the `ap` implementation of the Monad instance for functions – Bergi Oct 31 '15 at 18:12
• As a fun exercise, `ap` can be defined as `(. ((. (return .)) . (>>=))) . (>>=)`. :-) – awllower Mar 10 '18 at 9:04

When the monad `m` is `(->) a`, as in your case, you can define `ap` as follows:

``````ap f g = \x -> f x (g x)
``````

We can see that this indeed "works" in your pointfree example.

``````average = ap ((/) . realToFrac . sum) genericLength
average = \x -> ((/) . realToFrac . sum) x (genericLength x)
average = \x -> (/) (realToFrac (sum x)) (genericLength x)
average = \x -> realToFrac (sum x) / genericLength x
``````

We can also derive `ap` from the general law

``````ap f g = do ff <- f ; gg <- g ; return (ff gg)
``````

that is, desugaring the `do`-notation

``````ap f g = f >>= \ff -> g >>= \gg -> return (ff gg)
``````

If we substitute the definitions of the monad methods

``````m >>= f = \x -> f (m x) x
return x = \_ -> x
``````

we get the previous definition of `ap` back (for our specific monad `(->) a`). Indeed:

``````app f g
= f >>= \ff -> g >>= \gg -> return (ff gg)
= f >>= \ff -> g >>= \gg -> \_ -> ff gg
= f >>= \ff -> g >>= \gg _ -> ff gg
= f >>= \ff -> \x -> (\gg _ -> ff gg) (g x) x
= f >>= \ff -> \x -> (\_ -> ff (g x)) x
= f >>= \ff -> \x -> ff (g x)
= f >>= \ff x -> ff (g x)
= \y -> (\ff x -> ff (g x)) (f y) y
= \y -> (\x -> f y (g x)) y
= \y -> f y (g y)
``````
• So defining `ap' f g = \x -> f x (g x)` will give it a subset of the power that the normal `ap` has? – Caridorc Oct 31 '15 at 18:12
• @Caridorc: Yes, normal `ap` works on all monads, your `ap'` only on functions – Bergi Oct 31 '15 at 18:14
• Is `ap'` in a way similar to `.`? While `.` composes two functions that both take one argument, `ap'` composes two functions one taking two arguments and one taking one argument. – Caridorc Oct 31 '15 at 18:26
• @Caridorc Only vaguely. It is known as "combinator S" in lambda calculus and combinatory logic.en.wikipedia.org/wiki/Combinatory_logic#Examples_of_combinators – chi Oct 31 '15 at 19:04
• @chi Indeed! `Applicative` can be considered a generalization of the SKI calculus: `(<*>)` is S, `pure` is K, and I = S K K. – Rein Henrichs Nov 1 '15 at 6:41

Any lambda term can be rewritten to an equivalent term that uses just a set of suitable combinators and no lambda abstractions. This process is called abstraciton elimination. During the process you want to remove lambda abstractions from inside out. So at one step you have `λx.M` where `M` is already free of lambda abstractions, and you want to get rid of `x`.

• If `M` is `x`, you replace `λx.x` with `id` (`id` is usually denoted by `I` in combinatory logic).
• If `M` doesn't contain `x`, you replace the term with `const M` (`const` is usually denoted by `K` in combinatory logic).
• If `M` is `PQ`, that is the term is `λx.PQ`, you want to "push" `x` inside both parts of the function application so that you can recursively process both parts. This is accomplished by using the `S` combinator defined as `λfgx.(fx)(gx)`, that is, it takes two functions and passes `x` to both of them, and applies the results together. You can easily verify that that `λx.PQ` is equivalent to `S(λx.P)(λx.Q)`, and we can recursively process both subterms.

As described in the other answers, the `S` combinator is available in Haskell as `ap` (or `<*>`) specialized to the reader monad.

The appearance of the reader monad isn't accidental: When solving the task of replacing `λx.M` with an equivalent function is basically lifting `M :: a` to the reader monad `r -> a` (actually the reader Applicative part is enough), where `r` is the type of `x`. If we revise the process above:

• The only case that is actually connected with the reader monad is when `M` is `x`. Then we "lift" `x` to `id`, to get rid of the variable. The other cases below are just mechanical applications of lifting an expression to an applicative functor:
• The other case `λx.M` where `M` doesn't contain `x`, it's just lifting `M` to the reader applicative, which is `pure M`. Indeed, for `(->) r`, `pure` is equivalent to `const`.
• In the last case, `<*> :: f (a -> b) -> f a -> f b` is function application lifted to a monad/applicative. And this is exactly what we do: We lift both parts `P` and `Q` to the reader applicative and then use `<*>` to bind them together.

The process can be further improved by adding more combinators, which allows the resulting term to be shorter. Most often, combinators `B` and `C` are used, which in Haskell correspond to functions `(.)` and `flip`. And again, `(.)` is just `fmap`/`<\$>` for the reader applicative. (I'm not aware of such a built-in function for expressing `flip`, but it'd be viewed as a specialization of `f (a -> b) -> a -> f b` for the reader applicative.)

• It's not "built-in", but `lens` has the generalized `flip` as `(??)`. I feel it's a bit of a hole in `Data.Functor`. – Ørjan Johansen Nov 1 '15 at 5:01