Are these functions exactly the same?

Actually, no! There are some very subtle differences. First of all, read about the dreaded monomorphism restriction. In short, class-polymorphic functions are given different types by default if they're "obviously" functions or not. In your code, this difference won't manifest, because `inc`

and `double`

aren't "obviously" functions and so are given monomorphic types. But if we make a slight change:

```
inc, double :: Num a => a -> a
inc = (+1)
double = (*2)
func1 = double . inc
func2 x = double $ inc x
func3 x = double (inc x)
func4 = \x -> double (inc x)
```

then in ghci we can observe that `func1`

and `func4`

-- which are not "obviously" functions -- are given a monomorphic type:

```
*Main> :t func1
func1 :: Integer -> Integer
*Main> :t func4
func4 :: Integer -> Integer
```

whereas `func2`

and `func3`

are given a polymorphic type:

```
*Main> :t func2
func2 :: Num a => a -> a
*Main> :t func3
func3 :: Num a => a -> a
```

The second slight difference is that these implementations may have (very slightly) different evaluation behavior. Since `(.)`

and `($)`

are functions, you may find that invoking `func1`

and `func2`

requires a little bit of evaluation before they can run. For example, perhaps the first invocation of `func1 3`

proceeds like this:

```
func1 3
= {- definition of func1 -}
(double . inc) 3
= {- definition of (.) -}
(\f g x -> f (g x)) double inc 3
= {- beta reduction -}
(\g x -> double (g x)) inc 3
= {- beta reduction -}
(\x -> double (inc x)) 3
```

whereas the first invocation of, e.g, `func4 3`

gets to this point in a much more straightforward manner:

```
func3 3
= {- definition of func3 -}
(\x -> double (inc x)) 3
```

However, I wouldn't worry about this too much. I expect that in GHC with optimizations turned on, saturated calls to both `(.)`

and `($)`

get inlined, eliminating this possible difference; and even if not, it's going to be a very small cost indeed, since this will likely happen only once per definition (not once per invocation).

Why doesn't `func5`

compile?

Because you don't want it to compile! Imagine it did. Let's see how we would evaluate `func5 3`

. We'll see that we "get stuck".

```
func5 3
= {- definition of func5 -}
(double $ inc) 3
= {- definition of ($) -}
(\f x -> f x) double inc 3
= {- beta reduction -}
(\x -> double x) inc 3
= {- beta reduction -}
double inc 3
= {- definition of double -}
(\x -> x*2) inc 3
= {- beta reduction -}
(inc * 2) 3
= {- definition of inc -}
((\x -> x+1) * 2) 3
```

Now we are trying to multiply a function by two. At the moment, we haven't said what multiplication of functions should be (or even, in this case, what "two" should be!), and so we "get stuck" -- there's nothing further that we can evaluate. That's not good! We don't want to "get stuck" in such a complicated term -- we want to only get stuck on simple terms like actual numbers, functions, that kind of thing.

We could have prevented this whole mess by observing right at the beginning that `double`

only knows how to operate on things that can be multiplied, and `inc`

isn't a thing that can be multiplied. So that's what the type system does: it makes such observations, and refuses to compile when it's clear that something wacky is going to happen down the line.

`(.)`

is used to "pipe" functions together, so that the expression`f . g`

is afunction, where the result of`g`

is used as an argument to`f`

. The dollar operator`($)`

is used to give arguments to a function, so that the expression`f $ x`

is avalue, where`x`

is given as an argument to`f`

. – kqr Oct 27 '13 at 17:49