Yes, your intuition about functions not needing all their arguments is spot on. And when one function takes another function as a parameter to return another function as a result, it is called "currying." See: http://en.wikipedia.org/wiki/Currying.

(As a side note, this was actually discovered (or rediscovered) by **Haskell Curry**, which is how our Haskell got its name.)

If the idea of currying is still taking time to sink in, this may help:
There are actually two functions defined in `Prelude`

called `curry`

and `uncurry`

. They carry the following types:

```
Prelude> :t curry
curry :: ((a, b) -> c) -> a -> b -> c
Prelude> :t uncurry
uncurry :: (a -> b -> c) -> (a, b) -> c
```

`uncurry`

takes a 2 argument *curried* function (or a function that takes a function of one argument that returns a function of one argument,) and produces an *uncurrried* function, or a function that takes all of the arguments *all at once* (as a tuple.)

`curry`

, as you may imply by the name and by its type, goes the other way, so that it takes a *curried* function (a function that takes all the arguments at once) and produces a function that takes one argument and returns a function that takes the other argument.

Most programming languages work by default in a uncurried fashion, you provide all the arguments and get a result, while Haskell is curried by default.

Now for an example of `uncurry`

, we can take a simple function, `(+)`

:

```
Prelude> :t (+)
(+) :: Num a => a -> a -> a
Prelude> (+) 1 2
3
Prelude> :t (+)
(+) :: Num a => a -> a -> a
Prelude> :t uncurry (+)
uncurry (+) :: Num c => (c, c) -> c
Prelude> uncurry (+) (1,2)
3
```

And, we could also do this with `const`

if we want to:

```
Prelude> :t const
const :: a -> b -> a
Prelude> const 1 2
1
Prelude> :t uncurry const
uncurry const :: (c, b) -> c
Prelude> uncurry const (1,2)
1
```

But having an uncurried version of `const`

is just not very useful, because there is no point in having a function that takes two arguments and always returns the first one if you have to specify all the arguments up front.

`const`

is useful precisely because it is curried and can be given in a place where a function is needed that takes two arguments and simply returns the first one.

Like in `foldr1`

, for example:

```
Prelude> :t foldr1
foldr1 :: (a -> a -> a) -> [a] -> a
```

Where the first argument is a curried function of two arguments.
And since the return value of a function can be a function, it can also be so with `const`

:

```
Prelude> :t const id
const id :: b -> a -> a
```

`const id`

simply takes an argument of any type `b`

and returns the `id`

function.

So if we can apply `const id`

step by step:

```
Prelude> :t const id 1
const id 1 :: a -> a
```

`const id 1`

or `const id anyOtherValueHere`

just returns the id function.
Which can be used liked so:

```
Prelude> :t const id "Giraffe" 100
const id "Giraffe" 100 :: Num a => a
Prelude> const id "Giraffe" 100
100
Prelude> :t const id (\a b -> undefined) 100
const id (\a b -> undefined) 100 :: Num a => a
Prelude> const id (\a b -> undefined) 100
100
```

So, `const`

really ignores its second argument. Directly above, is just like applying `id`

to 100.

So, `foldr1 (const id)`

simply takes a list and keeps applying `id`

to each set of two elements and keeping the second one (because `const id`

returns the value of `id`

on the second argument passed in) until we have the last element.

compositionof other functions. For example, instead of`addAndTimes x = 4 * (2 + x)`

, which is a function on x, you can instead say`addAndTimes = (* 4) . (+ 2)`

, which is clearly simply a composition of the`(+ 2)`

and`(* 4)`

functions. – Justin L. Sep 6 '13 at 2:51