Reading this Wikibook about Haskell and Category Theory basics, I learn about Functors:

A functor is essentially a transformation between categories, so given categories C and D, a functor F : C -> D

maps any object A in C to F(A), in D.

maps morphisms f : A -> B in C to F(f) : F(A) -> F(B) in D.

... which sounds all nice. Later an example is provided:

Let's have a sample instance, too:

```
instance Functor Maybe where
fmap f (Just x) = Just (f x)
fmap _ Nothing = Nothing
```

Here's the key part: the type constructor Maybe takes any type T to a new type, Maybe T. Also, fmap restricted to Maybe types takes a function a -> b to a function Maybe a -> Maybe b. But that's it! We've defined two parts, something that takes objects in Hask to objects in another category (that of Maybe types and functions defined on Maybe types), and something that takes morphisms in Hask to morphisms in this category. So Maybe is a functor.

I understand how the definition of `fmap`

is key. I am confused about how the "type constructor Maybe" provides the first part. I would have rather expected something like `pure`

.

If I get it right, `Maybe`

rather maps `C`

to `D`

. (Thus being a morphism on category level, which might be a requirement for a Functor)

I guess you could rephrase my question like this: Is there a Functor that does not have an obvious implementation of `pure`

?

`Functor`

that does not admit`pure`

is`data Void a`

. The instance looks like`instance Functor Void where { fmap f x = case x of {} }`

. (I'm not making this an answer because I don't think this example is particularly enlightening, even though it answers the only question you actually ask in the body.)only`Functor`

that doesn't admit`pure`

: if you haveanyvalue`v`

in the`Functor`

you can define`pure x = x <$ v`

. And I think every choice for`pure`

is of this form, too. Of course this is not usually very unique.takes objects in Hask to objects in another category (that of Maybe types and functions defined on Maybe types)" I think you are confusing the codomain and the image. The codomain here is the same as the domain, it's Hask, so we are talking about an endofunctor. Theimageof Hask under Maybe is asubsetof the codomain -- all the Maybe types. You can easily convince yourself that Maybe doesn't take you out of Hask because you can apply Maybe multiple times -- Maybe (Mabe a), etc. -- the inner Maybe is still in the domain of Maybe.4more comments