# An example of a type with kind * -> * which cannot be an instance of Functor

I'm very much a Haskell novice, so apologies if the answer is obvious, but I'm working through the Typeclassopedia in an effort to better understand categories. When doing the exercises for the section on Functors, I came across this problem:

Give an example of a type of kind * -> * which cannot be made an instance of Functor (without using undefined).

My first thought was to define some kind of infinitely recursing definition of fmap, but wouldn't that essentially be the same as if `undefined` was used in the definition?

If someone could explain the answer it would be greatly appreciated.

Thanks!

Source of original exercise here, section 3: http://www.haskell.org/haskellwiki/Typeclassopedia#Introduction

• What about `(-> int)`? – Ramon Snir Apr 20 '13 at 8:57
• @RamonSnir `((->) Int)` is actually fine, you need something like `data K a = K (a -> Int)`. – Mikhail Glushenkov Apr 20 '13 at 8:59
• @MikhailGlushenkov, that's almost certainly what Ramon means, just like `(+ 1) = \a -> a + 1`. – huon Apr 20 '13 at 9:02
• @MikhailGlushenkov as @dbaupp noted, `(-> int)` <> `((->) int)`. – Ramon Snir Apr 20 '13 at 9:10
• – Petr Pudlák Apr 20 '13 at 15:14

A simple example is

``````data K a = K (a -> Int)
``````

Here's what ghci tells us is we try to automatically derive a `Functor` instance for `K`:

``````Prelude> :set -XDeriveFunctor
Prelude> data K a = K (a -> Int)
Prelude> :k K
K :: * -> *
Prelude> data K a = K (a -> Int) deriving Functor

<interactive>:14:34:
Can't make a derived instance of `Functor K':
Constructor `K' must not use the type variable in a function argument
In the data type declaration for `K'
``````

The problem is that the standard `Functor` class actually represents covariant functors (`fmap` lifts its argument to `f a -> f b`), but there is no way you can compose `a -> b` and `a -> Int` to get a function of type `b -> Int` (see Ramon's answer). However, it's possible to define a type class for contravariant functors:

``````class Contravariant f where
contramap :: (a -> b) -> f b -> f a
``````

and make `K` an instance of it:

``````instance Contravariant K where
contramap f (K g) = K (g . f)
``````

For more on covariance/contravariance in Haskell, see here.

Edit: Here's also a nice comment on this topic from Chris Smith on Reddit.

• +1 for `CoFunctor`s. – Ramon Snir Apr 20 '13 at 9:18
• Thanks, so if I understand correctly, the issue is that for the fmap definition for K, we have `(a -> b) -> K (a -> Int) -> K (a -> b)` which would be defined by attempting to compose a function of type `a -> Int` and a function of type `a -> b`, which doesn't work because type `a` would have to be fixed to `Int`? – JS. Apr 20 '13 at 9:20
• @JS You have a function of type `a -> b` and a function of type `a -> Int`, and you must produce a function of type `b -> Int`. But there is no way you can compose the inputs to get the desired output. – Mikhail Glushenkov Apr 20 '13 at 9:31
• No need to define the `Contravariant` class, use the one from Hackage! – leftaroundabout Apr 20 '13 at 9:50
• @mikhail-glushenkov ah yes I see it now, thanks again. – JS. Apr 20 '13 at 12:53

To expand on my (short) comment and on Mikhail's answer:

Given `(-> Int)`, you'd expect `fmap` to look as such:

``````(a -> Int) -> (a -> b) -> (b -> Int)
``````

or:

``````(a -> Int) -> (a -> b) -> b -> Int
``````

It is easy to prove that from the three arguments `(a -> Int)`, `(a -> b)`, `b` there is no possible way to reach `Int` (without `undefined`), thus from `(a -> Int)`, `(a -> b)` there is no way to reach `(b -> Int)`. Conclusion: no `Functor` instance exists for `(-> Int)`.

• The proof is simply: We have two theorems, both require proof for `a`. We only have a proof for `b`. No new proofs can be derived (as none of the theorems is applicable) => no proof can be derived for `Int`. – Ramon Snir Apr 20 '13 at 9:09

I also had trouble with this one, and I found Ramon and Mikhail's answers informative -- thanks! I'm putting this in an answer rather than a comment because 500 chars is too short, and for code formatting.

I was having trouble understanding what was covariant about `(a -> Int)` and came up with this counterexample showing `data K a = K (a -> Int)` can be made an instance of Functor (disproving Ramon's proof)

``````data K a = K (a -> Int)
instance Functor K where
fmap g (K f) = K (const 0)
``````

If it compiles, it must be correct, right? ;-) I spent some time trying other permutations. Flopping the function around just made it easier:

``````-- "o" for "output"
-- The fmapped (1st) type is a function output so we're OK.
data K0 o = K0 (Int -> o)
instance Functor K0 where
fmap :: (oa -> ob) -> (K0 oa) -> (K0 ob)
fmap g (K0 f) = K0 (g . f)
``````

Turning the Int into a type variable reduced it to Section 3.2 exercise 1 part 2:

``````-- The fmapped (2nd) type argument is an output
data K1 a b = K1 (a -> b)
instance Functor (K1 a) where
fmap :: (b1 -> b2) -> K1 a b1 -> K1 a b2
fmap g (K1 f) = K1 (g . f)
``````

Forcing the fmapped type to be an argument of the function was the key... just like Mikhail's answer said, but now I understand it ;-)

``````-- The fmapped (2nd) type argument is an input
data K2 a b = K2 (b -> a)
instance Functor (K2 o) where
fmap :: (ia -> ib) -> (K2 o ia) -> (K2 o ib)
-- Can't get our hands on a value of type o
fmap g (K2 f) = K2 (const (undefined :: o))
-- Nor one of type ia
fmap g (K2 f) = K2 (const (f (undefined :: ia)))
``````