It helps to know a little category theory. A category is just a set of objects with arrows between them. They can model many things in mathematics, but for our purposes we are interested in the category of type; Hask is the category of Haskell types, with each type being an object in Hask and each function being an arrow between the argument type and the return type. For example,
Bool are all objects in Hask, and
ord :: Char -> Int,
odd :: Int -> Bool, and
repeat :: Char -> [Char] would be some examples of arrows in Hask.
Each category has several properties:
Every object has an identity arrow.
Arrows compose, so that if
a -> b and
b -> c are arrows, then so is
a -> c.
Identity arrows are both left and right identities for composition.
Composition is associative.
The reason that Hask is a category is that every type has an identity function, and functions compose. That is,
id :: Int -> Int and
id :: Char -> Char are identity arrows for the category, and
odd . ord :: Char -> Bool are composed arrows.
(Ignore for now that we think of
id is polymorphic function with type
a -> a instead of a bunch of separate functions with concrete types. This demonstrates a concept in category theory called a natural transformation that you don't need to think about now.)
In category theory, a functor F is a mapping between two categories; it maps each object of one category to an object of the other, and it also maps each arrow of one category to an arrow of the other. If
a is an object in one category, we say that F a is the object in the other category. We also say that if f is an arrow in the first category, the corresponding arrow in the other if F f.
Not just any mapping is a functor. It has to obey two properties which should look familiar.
- F has to map the identity arrow for an object a to the identity arrow of the object F a.
- F has to preserve composition. That means that the composition of two arrows in the first category has to be mapped to the composition of the corresponding arrows in the other category. That is, if
h = g ∘ f is in the first category, then
h is mapped to
F h = F g ∘ F f in the other.
Finally, an endofunctor is a special name for a functor that maps one category to itself. In Hask, the typeclass
Functor captures the idea of an endofunctor from Hask to Hask. The type constructor itself maps the types, and
fmap is used to map the arrows.
Maybe as an example. The type constructor
Maybe is an endofuntor, because it maps objects in Hask (types) to other objects in Hask (other types). (This point is obscured a little bit since we don't have new names for the target types, so think of
Maybe as mapping
Int to the type
To map an arrow
a -> b to
Maybe a -> Maybe b, we provide a defintion for
fmap in the instance of
Maybe also maps functions, but using the name
fmap instead. The functor laws it must obey are the same as two listed in the definition of a functor.
fmap id = id (Maps
id :: Int -> Int to
id :: Maybe Int -> Maybe Int.
fmap f . fmap g = fmap f . g (That is,
fmap odd . fmap ord $ x has to return the same value as
fmap (odd . ord) $ x for any possible value
x of type
As an unrelated tangent, others have pointed out that some things in Haskell are not functions, namely literal values like
"hello". While true in the programming language (you can't, for instance, compose
4 with another function that takes an
Int as a value), it is true that in category theory that you can replace values with functions from the unit type
() to the type of the value. That is, the literal value 4 can be thought of as an arrow
4 :: () -> Int that, when applied to the (only) value of type
(), it returns a value of type
Int corresponding to the integer 4. This arrow would compose like any other;
odd . 4 :: () -> Bool would map the value from the unit type to a Boolean value indicating whether the integer 4 is odd or not.
Mathematically, this is nice. We don't have to define any structure for types; they just are, and since we already have the idea of a type defined, we don't need a separate definition for what a value of a type is; we just just define them in terms of functions. (You might notice we still need an actual value from the unit type, though. There might be a way of avoiding that in our definition, but I don't know category theory well enough to explain that one way or the other.)
For the actual implementation of our programming language, think of literal values as being an optimization to avoid the conceptual and performance overhead of having to use
4 () in place of
4 every time we just want a constant value.