It's been claimed that `newtype T a = T (a -> Int)`

is a type constructor that is not a functor (but is a contravariant functor). How so? Or what is the contravariant functor (whence I assume it will be obvious why this can't be made a normal functor)?

Given

```
newtype T a = T (a -> Int)
```

let's try to build the `Contravariant`

instance for this datatype.

Here's the typeclass in question:

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

Basically, `contramap`

is akin to `fmap`

, but instead of lifting a function `a -> b`

to `f a -> f b`

, it lifts it to `f b -> f a`

.

Let's begin writing the instance...

```
instance Contravariant T where
contramap g (T f) = ?
```

Before we fill in the `?`

, let's think about what the types of `g`

and `f`

are:

```
g :: a -> b
f :: b -> Int
```

And for clarity, we might as well mention that

```
f a ~ T (a -> Int)
f b ~ T (b -> Int)
```

So we can fill in the `?`

as follows:

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

To be super pedantic, you might rename `g`

as `aToB`

, and `f`

as `bToInt`

.

```
instance Contravariant T where
contramap aToB (T bToInt) = T (bToInt . aToB)
```

The reason you can write a `Contravariant`

instance for `T a`

boils down to the fact that `a`

is in contravariant position in `T (a -> Int)`

. The best way to convince yourself that `T a`

isn't a `Functor`

is to try (and fail) to write the `Functor`

instance yourself.

Suppose that T is a functor. Then we have

```
fmap :: (a -> b) -> T a -> T b
```

Now, let's try implementing it.

```
instance Functor T where
fmap f (T g) = T $ \x -> _y
```

Clearly we start with something like this, and combine the values `f`

, `g`

, and `x`

somehow to compute a value for `y`

that's of the right type. How can we do that? Well, notice I've called it `_y`

, which tells GHC I need some help figuring out what to put there. What does GHC have to say?

```
<interactive>:7:28: error:
• Found hole: _y :: Int
Or perhaps ‘_y’ is mis-spelled, or not in scope
• In the expression: _y
In the second argument of ‘($)’, namely ‘\ x -> _y’
In the expression: T $ \ x -> _y
• Relevant bindings include
x :: b (bound at <interactive>:7:23)
g :: a -> Int (bound at <interactive>:7:13)
f :: a -> b (bound at <interactive>:7:8)
fmap :: (a -> b) -> T a -> T b (bound at <interactive>:7:3)
```

So now we're clear about the types of everything relevant, right? We need to return an `Int`

somehow, and what we have to build it out of are:

```
x :: b
g :: a -> Int
f :: a -> b
```

Well, okay, the only thing we have that can possibly create an `Int`

is `g`

, so let's fill that in, leaving `g`

's argument blank to ask GHC for more help:

```
instance Functor T where
fmap f (T g) = T $ \x -> g _y
<interactive>:7:31: error:
• Found hole: _y :: a
Where: ‘a’ is a rigid type variable bound by
the type signature for:
fmap :: forall a b. (a -> b) -> T a -> T b
at <interactive>:7:3
Or perhaps ‘_y’ is mis-spelled, or not in scope
• In the first argument of ‘g’, namely ‘(_y)’
In the expression: g (_y)
In the second argument of ‘($)’, namely ‘\ x -> g (_y)’
• Relevant bindings include
x :: b (bound at <interactive>:7:23)
g :: a -> Int (bound at <interactive>:7:13)
f :: a -> b (bound at <interactive>:7:8)
fmap :: (a -> b) -> T a -> T b (bound at <interactive>:7:3)
```

Okay, we could have predicted this ourselves: to call `g`

, we need a value of type `a`

from somewhere. But we don't have any values of type `a`

in scope, and we don't have any functions that return a value of type `a`

either! We're stuck: it's impossible to produce a value of the type we want now, even though at every step we did the only possible thing: there's nothing we could back up and try differently.

Why did this happen? Because if I give you a function of type `a -> Int`

and say "but by the way, here's a function from `a -> b`

, please give me back a function from `b -> Int`

instead", you can't actually *use* the function from `a -> b`

, because nobody ever gives you any `a`

s to call it on! If I had given you a function from `b -> a`

instead, that would be quite helpful, right? You could produce a function from `b -> Int`

then, by first calling the `b -> a`

function to get an `a`

, and then calling the original `a -> Int`

function to get out the desired `Int`

.

And that's what a contravariant functor is about: we reverse the arrow in the function passed to `fmap`

, so it can fmap over things you "need" (function arguments) instead of things you "have" (concrete values, return values of functions, etc).

Aside: I claimed earlier that we had done "the only possible thing" at each step, which was a bit of a fib. We can't build an `Int`

out of `f`

, `g`

, and `x`

, but of course we can make up all sorts of numbers out of the air. We don't know anything about the type `b`

, so we can't get an `Int`

that's derived from it in some way, but we could just say "let's always return zero", and this technically satisfies the type checker:

```
instance Functor T where
fmap f (T g) = T $ const 0
```

Obviously this looks quite wrong, since it seems like `f`

and `g`

ought to be pretty important and we're ignoring them! But it type-checks, so we're okay, right?

No, this violates one of the Functor laws:

```
fmap id = id
```

We can prove this easily enough:

```
fmap id (T $ const 5) = (T $ const 0) /= (T $ const 5)
```

And now we really *have* tried everything: the only way we have to build an `Int`

without using our `b`

type at all is to make it up out of nothing, and all such uses will be isomorphic to using `const`

, which will violate the Functor laws.

Here's another bit of perspective. As liminalisht showed, `T`

is `Contravariant`

. What can we tell about types that are both covariant and contravariant?

```
import Data.Void
change1, change1', change2 :: (Functor f, Contravariant f) => f a -> f b
change1 = contramap (const ()) . fmap (const ())
change1' = (() >$) . (() <$)
change2 = fmap absurd . contramap absurd
```

The first two implementations are basically the same (`change1'`

being an optimization of `change1`

); each of them uses the fact that `()`

is a "terminal object" of **Hask**. `change2`

instead uses the fact that `Void`

is an "initial object".

Each of these functions replaces all the `a`

s in `f a`

with `b`

s without knowing anything whatsoever about `a`

, `b`

, or the relationship between them, leaving everything else the same. It should probably be clear that this means `f a`

doesn't really depend on `a`

. That is, `f`

's parameter must be phantom. That is *not* the case for `T`

, so it can't also be covariant.