Chapter 11 of Learn You a Haskell introduces the following definition:

instance Applicative ((->) r) where
    pure x = (\_ -> x)
    f <*> g = \x -> f x (g x)

Here, the author engages in some uncharacteristic hand-waving ("The instance implementation for <*> is a bit cryptic, so it's best if we just [show it in action without explaining it]"). I'm hoping someone here might help me figure it out.

According to the applicative class definition, (<*>) :: f (a -> b) -> f a -> f b

In the instance, substituting ((->)r) for f: r->(a->b)->(r->a)->(r->b)

So the first question, is how do I get from that type to f <*> g = \x -> f x (g x)?

But even if I take that last formula for granted, I have trouble making it agree with examples I give to GHCi. For example:

Prelude Control.Applicative> (pure (+5)) <*> (*3) $ 4

This expression instead appears consistent with f <*> g = \x -> f (g x) (note that in this version x doesn't appear after f.

I realize this is messy, so thanks for bearing with me.

  • 1
    In the example, remeber that pure (+5) discards its first argument, so it's const (+5) 4 $ (4 * 3) or 4 * 3 + 5 which is consistent with (+5) . (*3) $ 4. Additionally, f <*> g = \x -> f (g x) is of type (b -> c) -> (a -> b) -> (a -> c) which neither typechecks with pure (+ 5) <*> (* 3) $ 4 nor the class declaration of Applicative. Jun 24, 2018 at 8:49

4 Answers 4


First of all, remember how fmap is defined for applicatives:

fmap f x = pure f <*> x

This means that your example is the same as (fmap (+ 5) (* 3)) 4. The fmap function for functions is just composition, so your exact expression is the same as ((+ 5) . (* 3)) 4.

Now, let's think about why the instance is written the way it is. What <*> does is essentially apply a function in the functor to a value in the functor. Specializing to (->) r, this means it applies a function returned by a function from r to a value returned by a function from r. A function that returns a function is just a function of two arguments. So the real question is this: how would you apply a function of two arguments (r and a, returning b) to a value a returned by a function from r?

The first thing to note is that you have to return a value of type (->) r which means the result also has to be a function from r. For reference, here is the <*> function:

f <*> g = \x -> f x (g x)

Since we want to return a function taking a value of type r, x :: r. The function we return has to have a type r -> b. How can we get a value of type b? Well, we have a function f :: r -> a -> b. Since r is going to be the argument of the result function, we get that for free. So now we have a function from a -> b. So, as long as we have some value of type a, we can get a value of type b. But how do we get a value of type a? Well, we have another function g :: r -> a. So we can take our value of type r (the parameter x) and use it to get a value of type a.

So the final idea is simple: we use the parameter to first get a value of type a by plugging it into g. The parameter has type r, g has type r -> a, so we have an a. Then, we plug both the parameter and the new value into f. We need both because f has a type r -> a -> b. Once we plug both an r and an a in, we have a b1. Since the parameter is in a lambda, the result has a type r -> b, which is what we want.

  • 1
    Wow, flashback to the abstract algebra class that cleaned my clock ten years ago! I really do appreciate the patient detail of this response. You're a gifted teacher, and I hope you'll at least consider academia among your post-graduate options.
    – planarian
    Aug 4, 2012 at 22:55
  • 3
    Fun fact: The definition of <*> for ((->) r) can be derived for free. Try plugging the type ((r -> a -> b) -> (r -> a) -> (r -> b)) into Djinn! Apr 13, 2014 at 23:18
  • 3
    I found the above explanation really useful but a bit difficult to follow. If anyone wants more to work with, here's an explanation of how I applied the above to a real example so that I could better understand it: wjdhamilton.blogspot.co.uk/2016/08/f-f-x-g-x.html Aug 5, 2016 at 15:33

Going through your original question, I think there's one subtle but very key point that you might have missed. Using the original example from LYAH:

(+) <$> (+3) <*> (*100) $ 5

This is the same as:

pure (+) <*> (+3) <*> (*100) $ 5

The key here is the pure before (+), which has the effect of boxing (+) as an Applicative. If you look at how pure is defined, you can see that to unbox it, you need to provide an additional argument, which can be anything. Applying <*> to (+) <$> (+3), we get

\x -> (pure (+)) x ((+3) x)

Notice in (pure (+)) x, we are applying x to pure to unbox (+). So we now have

\x -> (+) ((+3) x)

Adding (*100) to get (+) <$> (+3) <*> (*100) and apply <*> again, we get

\y -> (\x -> (+) ((+3) x)) y ((*100) y) {Since f <*> g = f x (g x)}

5  -> (\x -> (+) ((+3) x)) 5 ((*100) 5)

(\x -> (+) ((+3) x)) 5 (500)

5 -> (+) ((+3) 5) (500)

(+) 8 500


So in conclusion, the x after f is NOT the first argument to our binary operator, it is used to UNBOX the operator inside pure.

  • 3
    This is an absolutely critical point! It explains both the role of x and also why the number of parameters that the first function accepts must equal the number of applied functions. Aug 5, 2016 at 13:39
  • 2
    @JamesHamilton This is the answer that hits the nail on the head. It ought to be the answer.
    – Olumide
    May 14, 2018 at 12:28
  • 1
    You're right, but given that it's been several years since I asked the question I am unsure that I can change my preferred answer May 14, 2018 at 14:10
  • LYAH makes it sound in their description like (+3) <*> (*100) is a well-formed Haskell expression, and the confusion with the associativity between $ and <$> makes the matter worse. Writing without infix makes it far easier to understand: (<*>) ((+) <$> (+3)) (*100) or (<*>) ((<*>) (pure (+)) (+3)) (*100) $ 5. Jul 29, 2020 at 18:33

“In the instance, substituting ((->)r) for f: r->(a->b)->(r->a)->(r->b)

Why, that's not right. It's actually (r->(a->b)) -> (r->a) -> (r->b), and that is the same as (r->a->b) -> (r->a) -> r -> b. I.e., we map an infix and a function which returns the infix' right-hand argument, to a function which takes just the infix' LHS and returns its result. For example,

Prelude Control.Applicative> (:) <*> (\x -> [x]) $ 2

How to understand Function as Functor and Function as Applicative?

First, how to understand function as functor?

We can regard functor as an empty box such as:

instance Functor Maybe where 
    fmap :: (a -> b) -> f a -> f b
    fmap f (Just x) = Just (f x) 
    fmap f Nothing = Nothing

there, Maybe type can be seen as an empty box with one slot which take a type to generate a concrete type Maybe a. In the fmap function:

  • The first parameter is a function, which maps from a to b;
  • The second parameter is a value of the type with the slot filled(concrete type), this concrete type is generated by type constructor and has the type f a (f is Maybe, so f a is Maybe a ).

When we implement function functors, for function functors must have two parameters to make a type a -> b, if we want our function functor has exactly one slot, we should first fill a slot, so the type constructor of function functor is ((->) r):

instance Functor ((->) r) where 
    fmap f g = (\x -> f (g x))

As the same as the fmap function in Maybe Functor, we should regard the second parameter g as a value of a concrete type which is generate by f (f equals (->) r), so f a is (->) r a which can be seen as r -> a. Finally, it is not difficult to understand that the g x in the fmap function cannot be seen as r -> x, it is just a function application which can be seen as (r -> a) x, also (x -> a).

Finally, it is not hard to understand that the <*> function in Applicative function (->) r can be implemented as following:

<*> :: f (a -> b) -> f a -> f b
<*> :: (r -> a -> b) -> (r -> a) -> (r -> b)
<&> :: (a -> b) -> (r -> a) -> (r -> b)
f <*> g = \r -> f r (g r)

for g r will map r to a, f r a will map r, a to b, so the whole lambda function can be seen as r -> b, also f b. For an instance:

((+) <*> (+3)) 5

the result is 5 + (5 + 3) = 13.

How to understand in functions as applicatives, (+) <$> (+3) <*> (*100) $ 5 = 508?

We know (+) has type: Num a, a -> a -> a;

We also know (+3) and (*100) has type: Num r, a, r -> a;

(+) <$> (+3) equals pure (+) <*> (+3), where :t pure (+) equals Num _, a, _ -> a -> a -> a

In another words, the pure (+) simply takes a _ parameter whatever and return the + operator, the parameter _ has no effect on the final return value. pure (+) also maps the return value of function (+3) to a function. Now for

f <*> g = \r -> f r (g r)

we can apply the operators and get:

pure (+) <*> (+3) = 
    \r -> f r (gr) =
    \r -> + (gr) =
    \r -> + (r + 3) =
    \r x -> x + (r + 3)

it has the type r -> x -> a. We then calculate pure (+) <*> (+3) <*> (*100) using the definition of <*>, and get:

pure (+) <*> (+3) <*> (*100) = 
    \r -> f r (gr) =
    \r -> (r + 3) + (gr)
    \r -> (r + 3) + (r * 100)

then we apply this function with parameter 5, we get:

(5 + 3) + (5 * 100) = 508 

we can simply think this applicative style as first to calculate the value after <$> and sum them up with the operator before <$>. In last example, this operator is a binary operator equals (+), we can replace it with a triple operator (\x y z -> [x,y,z]), so the following equation holds:

(\x y z -> [x,y,z]) <$> (+3) <*> (*2) <*> (/2) $ 5 = [8.0,10.0,2.5]

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