# what does (<*>) :: f (a -> b) -> f a -> f b exactly do in the Functor class

``````class Functor f => Applicative f where
pure :: a -> f a
(<*>) :: f (a -> b) -> f a -> f b
``````

From my understanding, it takes a function f, where another function `(a -> b)` as its argument, returns a function `f`. Applying `f` to `a` then returns a function `f` and apply `f` to `b`.

Here is an example:

``````Prelude> (+) <\$> Just 2 <*> Just 3
Just 5
``````

But I don't quite understand how it works.

I guess `(+)` should be `f`, `Just 2` and `Just 3` should be `a` and `b` respectively. Then what is `(a -> b)`?

• Shouldn't it be "...do in Applicative class"? – radrow Aug 10 at 12:15

From my understanding, it takes a function f...

Unfortunately this is incorrect. In this case, `f` is a type, not a function. Specifically, `f` is a "higher-kinded type" with kind `* -> *`. The type `f` is the functor.

In this case, `f` is `Maybe`. So we can rewrite the function types, specializing them for `Maybe`:

``````pure :: a -> Maybe a
(<*>) :: Maybe (a -> b) -> Maybe a -> Maybe b
``````

It starts to become a bit clearer once you get this far. There are a couple different possible definitions for `pure`, but only one that makes sense:

``````pure = Just
``````

The operator `x <\$> y` is the same as `pure x <*> y`, so if you write out:

``````(+) <\$> Just 2 <*> Just 3
``````

Then we can rewrite it as:

``````pure (+) <*> pure 2 <*> pure 3
``````

Although this technically has a more general type. Working with the functor laws, we know that `pure x <*> pure y` is the same as `pure (x y)`, so we get

``````pure ((+) 2) <*> pure 3
pure ((+) 2 3)
pure (2 + 3)
``````

In this case, we `a` and `b` are the types but since `<*>` appears twice they actually have different types in each case.

In the first `<*>`, `a` is `Int` and `b` is `Int -> Int`. In the second `<*>`, both `a` and `b` are `Int`. (Technically you get generic versions of `Int` but that's not really important to the question.)

• The operator x <\$> y is the same as pure x <*> y. Is it a typo or exactly what you mean? I think it might be x<*>y, isn't it? – user8314628 Aug 10 at 2:03
• No, there's no typo. `x <\$> y` is the same as `pure x <*> y`. – Dietrich Epp Aug 10 at 2:06
• Worth mentioning is this; `fmap :: a->b`, while `<*> :: f (a -> b)`. A nice result of the Applicative typeclass is that you can have a function taking multiple arguments and apply them by using repeated `<*>`, e.g `pure f <*> a <*> b <*> c <*> d .. `. Since fmap accepts a pure function, you can not apply multiple `fmap`s and get it working. – Robert K Aug 10 at 5:40
• “In this case, `f` is a type, not a function” – I'd say it's closer to being a function than a type. An injective type-level function it is, aka type constructor. – leftaroundabout Aug 10 at 10:44
• @leftaroundabout: That is incorrect, in this case `f` is actually a type, and it is not a function. There is no logical way that `f` can be "closer" to being a function. It is not necessary that `f` be a type constructor… in fact, there are many functors which are not type constructors, such as `Either String`. In this case, `f` is a type variable with kind `* -> *`. It is incorrect to equate type constructors with "type-level functions", and recall that while functions in Haskell are values, likewise higher-kinded types are types. – Dietrich Epp Aug 10 at 14:17

Applicative functors were introduced to Haskell as applicative style programming "Idioms". Unpacking this phrase, we have "applicative style programming"; which is just application of functions to arguments. We also have "idioms", or phrases in a language which have a special meaning. For example "raining cats and dogs" is an idiom for raining very heavily. Putting them together, applicative functors are function applications with special meaning.

Take for example, following Dietrich Epp's lead, `anApplication` defined by a function,

``````anApplication = f a
where
f = (+2)
a = 3
``````

and, `anIdiomaticApplication`, defined with idiomatic application,

``````anIdiomaticApplication = f <*> a
where
f = Just (+2)
a = Just 3
``````

The top level structure of these definitions are similar. The difference? The first has a space--normal function application--and the second has `<*>`--idiomatic function application. This illustrates how `<*>` facilitates applicative style: just use `<*>` in place of a space.

The application, `<*>`, is idiomatic because it carries a meaning other than just pure function application. By way of exposition, in `anIdiomaticApplication` we have something like this:

`````` f <*> a :: Maybe (Int -> Int) <*> Maybe Int
``````

Here, the `<*>` in the type is used to represent a type level function* that corresponds to the signature of the real `<*>`. To the type-`<*>` we apply the type arguments for `f` and `a` (respectively `Maybe (Int -> Int)` and `Maybe Int`). After application we have

`````` f <*> a :: Maybe Int
``````

As an intermediate step, we can imagine something like

`````` f <*> a :: Maybe ((Int -> Int) _ Int)
``````

With `_` being the type level stand-in for regular function application.

At this point we can finally see the idiom-ness called out. `f <*> a` is like a normal function application, `(Int -> Int) _ Int`, in the `Maybe` context/idiom. So, `<*>` is just function application that happens within a certain context.

In parting, I'll emphasize that understanding `<*>` is only partially understanding its use. We can understand that `f <*> a` is just function application which some extra idiomatic meaning. Due to the Applicative laws, we can also assume that idiomatic application will be somehow sensible.

Don't be surprised, however, if you look at `<*>` and get confused since there is so little there. We must also be versed in the various Haskell Idioms. For instance, in the `Maybe` idiom either the function or value may not be present, in which case the output will be `Nothing`. There are of course, many others, but getting familiar with just `Either a` and `State s` should model a wide variety of the different kinds.

*Something like this could actually be made with a closed type family (untested)

``````type family IdmApp f a where
IdmApp (f (a->b)) a = f b
``````