Can someone explain in simple terms the difference between the two? I'm not fully understanding the part where monads are endofunctors versus being just functors.
A functor may go from one category to a different one, an endofunctor is a functor for which start and target category are the same.
Same as with endomorphisms versus morphisms.
Now, why must monads be endofunctors?
There is the famous quote that "Monads are just monoids in the category of endofunctors". Fortunately, somebody else has already explained that rather well in this answer.
The key point why a monad has to be an endofunctor, is that join
, as it is called in Haskell, or µ
, as it is usually called in category theory, is part of the definition¹ of a monad. Now
Prelude Control.Monad> :t join
join :: Monad m => m (m a) > m a
so the result of applying the functor m
to an object (in Hask, the category of Haskell types as objects and functions as morphisms, a type) must be an object that m
can again be applied to. That means it must belong to the category that is the domain of the functor m
.
A functor can only be composed with itself if its domain and codomain are the same [strictly, if its codomain is a subcategory of its domain], in other words, if it is an endofunctor. Since composability with itself is part of the definition of a monad, monads are a fortiori endofunctors.
¹ One definition, one can alternatively define a monad using (>>=)
or bind
and have join
as a derived property.

5Are there any functors in Haskell that aren't endofunctors? (Don't they all map Hask to Hask?) – huon Apr 26 '12 at 23:58

5

3Nonendofunctors are available in packages such as hackage.haskell.org/packages/archive/categories/1.0/doc/html/… – sdcvvc Apr 27 '12 at 1:12

1@JonathanDunlap It just occurred to me, did you mistype and actually mean monads, and not monoids? As in, "Monads are monoids in the category of Endofunctors", or what the saying was? – Daniel Fischer Apr 27 '12 at 19:34

2@JonathanDunlap Okay, going to update the answer accordingly (will take a while, though, I'm slow). Monoids are a different kind of beast, it's just that some functors (monads, for instance) are also monoids (in some category). Sort of incidental. – Daniel Fischer Apr 27 '12 at 19:40