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.

higher kinded typesresp.higher kinded type variables– Ingo Jul 28 '13 at 17:53`fmap`

is defined for the`Functor`

type class. The bookLearn You a Haskell For Great Goodhas 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