the type of fmap in Functor is:

``````fmap :: Functor f => (a -> b) -> f a -> f b
``````

it looks like ,first apply function (a -> b) to the parameter of f a to create a result of type b, then apply f to it, and result is f b

using Maybe a for example :

`````` fmap show (Just 1)
result is : Just "1"
``````

same as saying:

``````Just (show 1)
``````

but when (->) is used as a Functor (in Control.Monad.Instances)

``````import Control.Monad.Instances
(fmap show Just) 1
result is : "Just 1"
``````

that is, Just is apply first, then show is applied. in another example ,result is same:

`````` fmap (*3) (+100) 1
result is 303
``````

why not *3 first, then +100?

-

the type of fmap in Functor is:

``````fmap :: Functor f => (a -> b) -> f a -> f b
``````

it looks like ,first apply function (a -> b) to the parameter of f a to create a result of type b, then apply f to it, and result is f b

That is the type of `fmap`, but your interpretation of what that type means is wrong.

You seem to assume that `f a` has one parameter, and that that parameter has type `a`.

Consider `xs :: [a]`:

• Perhaps `xs = []`.
• Perhaps `xs = [x1]`.
• Perhaps `xs = [x1, x2]`.
• ...

The type `f a` is a functor `f` with a single type parameter `a`. But values of type `f a` do not necessarily take the form `F x`, as you can see from the first and third cases above.

Now consider `fmap f xs`:

• Perhaps `fmap f xs = []`.
• Perhaps `fmap f xs = [f x1]`.
• Perhaps `fmap f xs = [f x1, f x2]`.
• ...

We don't necessarily apply `f` at all (first case)! Or we might apply it more than once (third case).

What we do is replace the things of type `a`, with things of type `b`. But we leave the larger structure intact --- no new elements added, no elements removed, their order is left unchanged.

Now let's think about the functor `(c ->)`. (Remember, a functor takes one type parameter only, so the input to `(->)` is fixed.)

Does a `c -> a` even contain an `a`? It might not contain any `a`s at all, but it can somehow magic one out of thin air when we give it a `c`. But the result from `fmap` has type `c -> b`: we only have to provide a `b` out of that when we're presented with a `c`.

So we can say `fmap f x = \y -> f (x y)`.

In this case, we're applying `f` on demand --- every time the function we return gets applied, `f` gets applied as well.

-
yes, your answer is great! I made a big mistake. thank you very much. –  诺 铁 Apr 24 '12 at 13:54
I confuse "type parameter" with a concrete parameter –  诺 铁 Apr 24 '12 at 14:19

The `fmap` instance for `(->) r` (i.e. functions) is literally just composition. From the source itself:

``````instance Functor ((->) r) where
fmap = (.)
``````

So, in your example, we can just replace `fmap` with `(.)`, and do some transformations

``````fmap (*3) (+100) 1 =>
(.) (*3) (+100) 1  =>
(*3) . (+100) \$ 1  => -- put (.) infix
(*3) (1 + 100)     => -- apply (+100)
(1 + 100) * 3         -- apply (*3)
``````

That is, `fmap` for functions composes them right to left (exactly the same as `(.)`, which is sensible because it is `(.)`).

To look at it another way (for (double) confirmation!), we can use the type signature:

``````-- general fmap
fmap :: Functor f => (a -> b) -> f a -> f b

-- specialised to the function functor (I've removed the last pair of brackets)
fmap :: (a -> b) -> (r -> a) -> r -> b
``````

So first the value of type `r` (the third argument) needs to be transformed into a value of type `a` (by the `r -> a` function), so that the `a -> b` function can transform it into a value of type `b` (the result).

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Thank you, this is a nice clear definition! –  Jeff Foster Apr 24 '12 at 9:03
yes, fmap :: (a -> b) -> (r -> a) -> r -> b ,this explains much,thank you –  诺 铁 Apr 24 '12 at 13:33

It needs to be defined that way to make the types work out. As you pointed out, the type of `fmap` is:

``````fmap :: Functor f => (a -> b) -> f a -> f b
``````

Let's consider the case when the functor `f` is `((->) c)`

(Note: we'd actually like to write this as `(c ->)`, i.e. functions from `c`, but Haskell doesn't allow us to do this.)

Then `f a` is actually `((->) c a)`, which is equivalent to `(c -> a)`, and similarly for `f b`, so we have:

``````fmap :: (a -> b) -> (c -> a) -> (c -> b)
``````

i.e. we need to take two functions:

• `f :: a -> b`
• `g :: c -> a`

and construct a new function

• `h :: c -> b`

But there's only one way to do that: you have to apply `g` first to get something of type `a`, and then apply `f` to get something of type `b`, which means that you have to define

``````instance Functor ((->) c) where
fmap f g = \x -> f (g x)
``````

or, more succinctly,

``````instance Functor ((->) c) where
fmap = (.)
``````
-

`fmap` for `(->)` is defined like `fmap = (.)`. So, `(fmap f g) x` is `(f . g) x` is `f (g x)`. In your case `(*3) ((+100) 1)`, which equals `3 * (100 + 1)` which results in `303`.

-
``````fmap :: Functor f => (a -> b) -> f a -> f b
``````

Remember that `f` can also be a type constructor. I take this to mean (for the simplest cases) that function takes something of type `a` wrapped in an `f` and converts it to something of type `b` wrapped in an `f` using the function `a -> b`.

In the second example, you are doing `(fmap show Just) 1`. This is of type

``````Prelude> :t fmap show Just
fmap show Just :: (Show a, Functor ((->) a)) => a -> String
``````

This is in contrast to the previous one

``````Prelude> :t fmap show (Just 1)
fmap show (Just 1) :: Maybe String
``````

The difference is that in the first one `Just` is a type constructor, whereas `Just 1` is an instance of a type. `fmap` is suitably generic such that it has meanings for both.

-
In "Remember that f can also be a type constructor" you probably mean "must" instead "can also". –  Omar Antolín-Camarena Apr 24 '12 at 12:35
`Just` isn't a type constructor, it is a value or data constructor. `Maybe` is a type constructor. –  Ben Millwood Apr 24 '12 at 21:15