Exercise 5 of the Haskell Typeclassopedia Section 3.2 asks for a proof or counterexample on the statement

The composition of two Functors is also a Functor.

I thought at first that this was talking about composing the fmap methods defined by two separate instances of a Functor, but that doesn't really make sense, since the types wouldn't match up as far as I can tell. For two types f and f', the types of fmap would be fmap :: (a -> b) -> f a -> f b and fmap :: (a -> b) -> f' a -> f' b, and that doesn't really seem composable. So what does it mean to compose two Functors?

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    Have you tried actually composing fmap with itself in ghci? i.e. :t fmap . fmap – Squidly Nov 5 '13 at 9:57
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    @MrBones Thanks for the tip! For those who don't have ghci access, the output is :: (Functor f1, Functor f) => (a -> b) -> f (f1 a) -> f (f1 b) – akbiggs Nov 5 '13 at 21:38

A Functor gives two mappings: one on the type level mapping types to types (this is the x in instance Functor x where), and one on the computation level mapping functions to functions (this is the x in fmap = x). You are thinking about composing the computation-level mapping, but should be thinking about composing the type-level mapping; e.g., given

newtype Compose f g x = Compose (f (g x))

can you write

instance (Functor f, Functor g) => Functor (Compose f g)

? If not, why not?

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    This is an excellent answer that explains the Typeclassopedia exercise without giving away the solution. – Will Nov 30 '15 at 16:09

What this is talking about is the composition of type constructors like [] and Maybe, not the composition of functions like fmap. So for example, there are two ways of composing [] and Maybe:

newtype ListOfMabye a = ListOfMaybe [Maybe a]
newtype MaybeOfList a = MaybeOfList (Maybe [a])

The statement that the composition of two Functors is a Functor means that there is a formulaic way of writing a Functor instance for these types:

instance Functor ListOfMaybe where
    fmap f (ListOfMaybe x) = ListOfMaybe (fmap (fmap f) x) 

instance Functor MaybeOfList where
    fmap f (MaybeOfList x) = MaybeOfList (fmap (fmap f) x)

In fact, the Haskell Platform comes with the module Data.Functor.Compose that gives you a Compose type that does this "for free":

import Data.Functor.Compose

newtype Compose f g a = Compose { getCompose :: f (g a) }

instance (Functor f, Functor g) => Functor (Compose f g) where
    fmap f (Compose x) = Compose (fmap (fmap f) x)

Compose is particularly useful with the GeneralizedNewtypeDeriving extension:

{-# LANGUAGE GeneralizedNewtypeDeriving #-}

newtype ListOfMaybe a = ListOfMaybe (Compose [] Maybe a)
   -- Now we can derive Functor and Applicative instances based on those of Compose
   deriving (Functor, Applicative)

Note that the composition of two Applicatives is also an Applicative. Therefore, since [] and Maybe are Applicatives, so is Compose [] Maybe and ListOfMaybe. Composing Applicatives is a really neat technique that's slowly becoming more common these days, as an alternative to monad transformers for cases when you don't need the full power of monads.

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    Surely the most useable of all answers here. Let me ask you further: when you write fmap f (Compose x) what is the type of x? I'd say it is f g a, but still I struggle to visualize the computation (fmap (fmap f) x). Gotta think harder about getCompose. NB: I understand that the letter "f" is used here in two different roles. – Marco Faustinelli Mar 15 '15 at 19:32
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    @MarcoFaustinelli You can tell what type it is by looking at the constructor for Compose that you are matching against. Since newtype Compose f g a = Compose (f (g a)), it must be the case that when you pattern-match against it you get a value of type f (g a). – amalloy Apr 23 '19 at 0:33

It really helps to think about the categorical interpretation here, a functor F: C -> D takes objects (values) and morphisms (functions) to objects and morphisms from a category C to objects and morphisms in a category D.

For a second functor G : D -> E the composition of functors G . F : C -> E is just taking the codomain of F fmap transformation to be the domain of the G fmap transformation. In Haskell this is accomplished with a little newtype unwrapping.

import Data.Functor

newtype Comp f g a = Comp { unComp :: f (g a) }

compose :: f (g a) -> Comp f g a
compose = Comp

decompose :: Comp f g a -> f (g a)
decompose = unComp

instance (Functor f, Functor g) => Functor (Comp f g) where
  fmap f = compose . fmap (fmap f) . decompose
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    Does f refer to functor and function at the same time? If the answer were yes, then why does the type constraint of Functor f not apply to f in fmap f? – Kamel Aug 30 '15 at 4:00

The composition of two functions is when you put one function inside another function, such as

round (sqrt 23)

This is the composition of the two functions round and sqrt. Similarly, the composition of two functors is when you put one functor inside another functor, such as

Just [3, 5, 6, 2]

List is a functor, and so is Maybe. You can get some intuition for why their composition also is a functor if you try to figure out what fmap should do to the above value. Of course it should map over the contents of the inner functor!


I am sure those answers are great but they did not mean anything to me beyond hints (perhaps I need coffee). My contribution to those who may be similarly situated is the following:

Functor composition is, per Luis Casillas and others, putting one Functor inside another. Consequently, given Functors, Array of List composed with Array of Maybe, it is required that fmap be implemented such that:

(Array of List)  o  (Array of Option)  ==  Array of (List of Option)

Specifically, that fmap for Array of List and fmap for Array of Option is equivalent to fmap for Array of (List of Option). That means, the outer fmap uses the inner Functor's fmap and does not use other means to apply its function to the given inner Functor's elements.

Per the question, the key thing here is that fmap never touches values of the inner Functor but rather merely applies the function given to fmap to each of them in turn. Consequently, fmap does not impose any type constraints on the composition. That is becomes the responsibility of whatever function being mapped.

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