Because of currying. Think about the type of this:

```
add 3 :: Integer -> Integer
```

If you give `add`

one number it returns a function that maps an `Integer`

to another integer. So you could do this:

```
map (add 3) [1..10]
```

It doesn't make sense to treat arguments differently from return types with partial application.

**EDIT to clarify**

I think bheklilr makes a good point that the type signature can be read like this

```
add :: Integer -> (Integer -> Integer)
```

We can take a function with more arguments, `zipWith3`

because it is the only one I can really think of.

```
zipWith3 :: (a -> b -> c -> d) -> [a] -> [b] -> [c] -> [d]
```

If we just read what this does it takes a function that takes 3 values and returns a fourth and then 3 lists of those values respectively and it returns a list of the fourth value. Trying it out.

```
add3 :: Int -> Int -> Int -> Int
add3 a b c = a + b + c
Prelude>zipWith3 add3 [1] [2] [3]
[6]
```

Although, in this case all the values are of type `Int`

it still demonstrates the point.

Now what if we don't give it all the lists? What if we give it no lists just `add3`

.

```
zipWith3 add3 :: [Int] -> [Int] -> [Int] -> [Int]
zipWith3 add3 :: [Int] -> ([Int] -> [Int] -> [Int])
zipWith3 add3 :: [Int] -> [Int] -> ([Int] -> [Int])
```

So, now we have a function that takes 3 lists and returns a list. But this is also a function that takes a list are returns a function that takes 2 lists and returns a list. There is no way to distinguish between them really.

```
(zipWith3 add3) [1,2] [3,4] [5,6] :: [Int]
(zipWith3 add3) [1,2] :: [Int] -> [Int] -> [Int]
```

See where I'm going with this? There is no distinction between arguments are return types.

`(->)`

is just a regular type taking two parameters (albeit with a special case syntax, and hidden implementation). Fire up ghci and run`:info (->)`

; you'll see there are even a few typeclass instances defined for`((->) a)`

already in the Prelude – jberryman Dec 9 '13 at 3:54`Int Int -> Int`

for`Int -> Int -> Int`

, or even (the to me unreadable)`(a b -> c) [a] [b] -> [c])`

for`((a -> b -> c) -> [a] -> [b] -> [c])`

. The interpretation seems to subtly different from the one found in Haskell. If I understand it is able to express some distinctions we cannot make in Haskell. – Arthur Dec 20 '13 at 15:37