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Here is a definition of a function:

fmap :: (a -> b) -> f a -> f b

Can you guys explain what it means exactly? The thing I don't understand are f a and f b: why is it possible to write this way? I mean, why is it syntaсtic correct and compiles well?

I think there should be only one variable (a -> b) -> a -> b or (a -> b) -> f -> f or whatever (a -> b) -> c -> d

Once again, the question is not about the meaning of the function, but about being syntactic correct.

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The buzzword is higher kinded types resp. higher kinded type variables – Ingo Jul 28 '13 at 17:53
    
You are looking at type classes here. In particular, fmap is defined for the Functor type class. The book Learn You a Haskell For Great Good has very good explanations of type classes and Functors. There is even a free online version of the book. – Code-Apprentice Jul 28 '13 at 18:47
up vote 2 down vote accepted

The syntax Type1 Type2 in Haskell means application of types. For example, you might have seen the type Maybe Integer. It works because Maybe is defined like this:

data Maybe a = ...

Note the type variable a. It means that we have to apply Maybe to some type before we can use it as a type itself. In Maybe Integer, this a is set to Integer.

Now in the question, we have f a, that is, a type variable is applied to another type variable. This means that f can be something like Maybe that expects to be applied to one more type, and a can be something like Integer that is a type in itself.

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can f be a function which takes a as an argument? – Alan Coromano Jul 28 '13 at 13:57
    
@Marius: f is a type variable, so you have to instantiate it to a type. You cannot instantiate f to a function, because that would mix up the value-level with the type-level. If you want, you can think of Maybe as a type function, though. – Toxaris Jul 28 '13 at 14:17
    
@Toxaris That being said, you can instantiate f to be a function (e.g. see Functor ((->) r)) – Julien Langlois Jul 28 '13 at 16:57
    
@Julien I would say: "You can instantiate f to construct function types". There's a difference between "function" and "function type", and there's a another difference between (->) r s and (->) r. – Toxaris Jul 28 '13 at 18:45
    
@Toxaris Agreed. :) – Julien Langlois Jul 28 '13 at 19:15

Do you accept the signature of the "normal" map function, map :: (a -> b) -> [a] -> [b]?

Now pretend that instead of [a] we had written List a (compare with Maybe a) so that the signature had read map :: (a -> b) -> List a -> List b. This signature is on the form (a -> b) -> f a -> f b with f = List.

The function fmap :: (a -> b) -> f a -> f b is a generalisation of map to other type constructors like Maybe.

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Do be careful with your type signatures: fmap :: a -> b-> f a -> f b is not the same as fmap :: (a -> b) -> f a -> f b. – Julien Langlois Jul 28 '13 at 7:11
    
Thanks Julien! I obviously wasn't really awake. – md2perpe Jul 28 '13 at 7:39

Well Haskell[1] type signatures are composed of 3 elements

  • Type Variables.
    • They are implicitly universally quantified. Syntactically they start with lower case letters.
  • Concrete Types.
    • They are the actual "stuff" that fills type variables. They start with upper case letters.
  • The function arrow.
    • This represents, well, functions. It's curried and blah blah blah. Syntactically it's an arrow.

Now as for your example we have 2 elements. a, b, and f are type variables, and then we have the function arrow.

a and b have the kind *, meaning that they can be instantiated by concrete types as is. f on the other hand, has the kind * -> *[2]. That means that f can't be instantiated in the same way as a and b. It needs to be given instantiated with a type that takes a type of kind * and then yields a concrete type.

For example, Maybe has to be given another type, say Int, before you can construct a value of that type. Eg Just 1 :: Maybe Int but wat :: Maybe doesn't make sense. So the application f a is the same as applying a value-function f to a value a, except with types. You even have partial application!

So read f a -> f b as "a function which will take some type f, apply it to some type a, and return a value of type f applied to some type b".

[1] By Haskell I mean vanilla haskell. Type operators, rank N types, etc complicate things.

[2] This is not the normal function ->. It's talking about types rather than values.

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It might be helpful to squeeze in the definition of 'type constructor' along with the definition of kinds. haskell.org/haskellwiki/Constructor#Type_constructor – cheecheeo Jul 28 '13 at 4:41

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