`head`

is a function of one argument^{1}. If you use `f $ x`

to apply a function to something, it's the same as simply writing `f x`

(or if you like `f(x)`

, or `(f)x`

, all the same thing... just uglier): the argument is "filled in" by the specified variable. So the result of `head $ reverse`

will simply be whatever result `head`

gives you when fed with an argument of `reverse`

's type... ...which however doesn't work, because `head`

needs a list but `reverse`

is a function. `$`

itself doesn't care about this but just hands on the parameter, for instance you could write

Prelude> :t map $ reverse

map $ reverse :: [[a]] -> [[a]]

because the first argument of `map`

is in fact a function.

With `(.)`

it's different. That cares about what type the argument to its right has (must also be a function), and it doesn't simply feed it to the left function right away. Rather, `f . g`

yields *another* function, which does the following: it waits for some argument `x`

, which it feeds to `g`

, and then feeds *the result of that* to `f`

.

Now, if you write

```
myLast' = head . reverse
```

it means just, you define `myLast`

as this function that `(.)`

gives you as the composition of `head`

and `reverse`

. That there are no arguments mentioned for `myLast`

here doesn't matter: `[a] -> a`

is just some type so you can define variables with this type (like myLast), by assigning them to values that happen to have such a function type (like `head . reverse`

). You *could*, if you wanted, make the parameter explicit:

```
myLast'' x = (head . reverse) x
```

Note that the parens are needed because otherwise it's parsed as `head . (reverse x)`

– which wouldn't work, because `reverse x`

is not a function anymore, just a result list. And therefore you couldn't *compose* it with `head`

; what you could however do is *apply* `head`

to it:

```
myLast''' x = head $ reverse x
```

^{1}In fact, *every* function in Haskell has just one argument... but we say "two-argument function" for things like `(+) :: Int -> Int -> Int`

, though really this is a one-argument function returning a one-argument function returning an `Int`

: `(+) :: Int -> (Int -> Int)`

.