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I know that fmap has type (a -> b) -> f a -> f b where f is a functor (and does different things depending on what the functor is). My basic question is this: given some invocation fmap r x, how does ghc figure out what the functor f is, just given the types of x and r?

Let me make this more precise. Suppose f and f' are functors such that f a = f' a for some type a, but f b and f' b are different. If r has type a -> b and x has type f a, it seems there are two different possible results for fmap r x: something of type f b and something of type f' b. How is this ambiguity resolved?

A secondary question: I wanted to test this out by making a weird functor -- maybe something that takes a to [Int] for any type a and does something stupid to functions... but I apparently haven't found the right bit of syntax that allows me to specify functors this way. (Is there something like data Newtype a = [Int] that works? It seems I'd need to make a typeclass name before I can make it an instance of functor.)

EDIT: I get it now, but for the record, the real issue (which is only implicit in my question) was that I didn't realize you can't have a functor Foo such that Foo a is a type like Int that already exists.

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Aren't typeclasses the thing you're looking for? – EarlGray Aug 13 '13 at 16:56
Concrete implementations of fmap for some Foo a are described in instance Functor <Foo> for typeclass Functor. – EarlGray Aug 13 '13 at 16:58
up vote 1 down vote accepted

Haskell type classes are based on first-order logic resolution. A type class constraint on a type variable is a predicate (you may have seen error messages indicating this if you ever tried to use a type class name where a type name was required) in that logic system.

Haskell requires a unique solution for each (Predicate, Type) pair throughout the program, so you will not be able to create two different Functor instances over Int, for example. The standard way around this, such as in the Monoid class for numeric types that could provide either a summation or product depending on how you define the monoidal operator you want to use, is to provide newtype wrappers over the concrete type that you want the class to have different instances for.

So, for Monoid, we have newtype Sum a = Sum { getSum :: a } and instance Num a => Monoid (Sum a) for the sum monoid and newtype Product a = Product { getProduct :: a } and instance Num a => Monoid (Product a) for the product monoid.

Note that since type only creates an alias for a type, it's not sufficient to provide multiple class instances for a type. The newtype declaration is like type in the sense that it does not produce any additional run-time structure for the new type, but it is unlike type in that it creates a new type rather than a type alias.

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I think the general answer you're looking for is that Haskell types are organized using "kinds", which are like types of types.

Here's the Functor class

class Functor f where
    fmap :: (a -> b) -> f a -> f b

It's not explicit, but this means that f is a type constructor with kind * -> *. Only types with that kind can be made Functors.

This is actually a rather strong statement. It means that any Functor must be parametric in a type argument. Now consider your statement:

Suppose f and f' are functors such that f a = f' a for some type a, but f b and f' b are different.

Given the kind system, this isn't possible. Since a Functor is parametric in its type argument, f a = f' a implies f = f', therefore f b = f' b.

I'm not entirely sure what you're asking for with the "weird functor", but it sounds like something that couldn't be expressed with the Functor type class. IIRC Functor can only express endofunctors on Hask; you may need a different abstraction that allows for functors between categories.

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As I see it (math notation, not haskell), a functor f is a set map ob(Hask) -> ob(Hask) (where ob(Hask) is the objects of the category Hask, i.e. the set of all haskell types), along with an implementation of fmap. You claim that if f a = f' a for any type a, then f = f'. But, ignoring the fmap thing for a second, it's perfectly reasonable to have two maps of sets f,f': ob(Hask) -> ob(Hask) that have the same value on some types but not others (e.g. if there were only 5 types a,b,c,d,e then you could have maps f,f':{a,b,c,d,e} -> {a,b,c,d,e} such that f(a) = f'(a) but f(b) != f'(b). – qqw Aug 13 '13 at 17:43
In category theory, at least, the thing I'm asking for -- a functor sending any type to the type [Int], that sends every function a->b to the identity [Int] -> [Int] -- is definitely a valid endofunctor Hask -> Hask. Maybe you're trying to tell me that not every endofunctor Hask -> Hask is something you can actually construct in haskell? – qqw Aug 13 '13 at 18:07
@jm109: The key thing to realize is that f and f' must be type constructors. Type constructors have the property that f a is different from any other type that doesn't mention f, this gives you f /= f' => f a /= f' a. – Vitus Aug 13 '13 at 20:04
@Vitus: OK, is this roughly correct -- the only way to make functors is by using type constructors e.g. data Foo a = ... and by nature of type constructors, Foo a can't be a type that already exists. – qqw Aug 13 '13 at 20:20
@jm109: Pretty much. – Vitus Aug 13 '13 at 20:22

It depends on what argument you pass it. For example a list is a functor and so is Maybe

main = do
   putStrLn $ show (double [1..5])
   putStrLn $ show (double (Just 3))
   putStrLn $ show (double Nothing)

double :: (Functor f, Num a) => f a -> f a
double = fmap (*2)

*Main> main
Just 6

This double function will work for any functor that is holding an Num.

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"Suppose f and f' are functors such that f a = f' a for some type a, but f b and f' b are different."

This doesn't really make sense. Either f and f' are the same, or they aren't. You seem to be suggesting some kind of in-between state where it varies depending on the argument type; that can't happen.

"If r has type a -> b and x has type f a, it seems there are two different possible results for fmap r x: something of type f b and something of type f' b. How is this ambiguity resolved?"

Where did f' come from? Nothing in the above signatures mentions it. Since x has type f a, it follows that the result of fmap must have some type beginning with f - in this case f b, since r :: a -> b. This is perfectly unambiguous. The result of fmap is always in the same functor as you started with.

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f' in your second quote from my question was supposed to be the same as the f' in the first quote. f and f' are basically functions that take some type and return some other type (plus having fmap defined); so just like (in math) I can have two set functions f,f': {a,b,c} -> {a,b,c} such that f(a) = f'(a) but f(b) != f'(b), why can't I have a pair of functors f,f' such that f a = f' a but f b != f' b? – qqw Aug 13 '13 at 17:55
@jm109 f and f' are not arbitrary type level functions. They are type constructors. As such, each is a functor from Hask to a distinct subcategory of Hask. – Ben Aug 13 '13 at 20:53
@jm109 In fact, type constructors are faithful/injective, and as Ben points out, have disjoint images. If f a = f' b then f = f' and a = b. For example, [Int] cannot equal Maybe Char, because if it did, then Int=Char and []=Maybe. – AndrewC Aug 13 '13 at 21:42

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