Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I wonder:

1) are the following functions exactly the same:

inc = (+1)
double = (*2)

func1 = double . inc
func2 x = double $ inc x
func3 x = double (inc x)
func4 = \x -> double (inc x)

2) why doesn't func5 compile?

func5 = double $ inc        -- doesn't work
share|improve this question
The dot operator (.) is used to "pipe" functions together, so that the expression f . g is a function, 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 a value, where x is given as an argument to f. –  kqr Oct 27 '13 at 17:49

4 Answers 4

up vote 15 down vote accepted

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.

share|improve this answer
fantastic answer! (with meticulous precision in reduction sequences, great introduction of the type system, etc.) –  Will Ness Oct 27 '13 at 22:45

1) Yes. Those functions are all absolutely identical

2) To see why func5 doesn't work, just expand out its definition:


-- Definition of `func5`
= double $ inc

-- Definition of `($)`
= double inc

-- Definition of `double`
= 2 * inc

-- Definition of `inc`
= 2 * (1 +)

The compiler is complaining because (1 +) is a function, and you can't double a function.

share|improve this answer
To the OP: there is a perfectly natural notion of doubling a function into a commutative ring (which numbers are supposed to be). It's just not possible using Haskell's broken numeric typeclasses. You can hack around this by defining instance Num b => Num (a -> b) where f + g = \a -> f a + g a; f * g = \a -> f a * g a; fromInteger = const . fromInteger; -- ... and then double $ inc will do what you expect. –  Fixnum Oct 27 '13 at 18:46
@Fixnum Actually, you can double any function into an abelian group: (2 * f)(x) = f(x) + f(x). –  Joker_vD Oct 28 '13 at 9:49
@Joker_vD - Actually, you can double any magma-valued function (with some loss of good properties). I'm sorry for not generalizing my answer fully :) With a module structure you can multiply by ring elements (if you hack up more instances), not just integers, which is probably what the OP expects. You're perfectly right, of course. –  Fixnum Oct 28 '13 at 17:33

The first four functions are identical.

You are trying to apply double to inc. This won’t work, as inc cannot be multiplied.

double $ inc
-- is the same as
double inc

If you add type specs you’ll see it:

inc :: Integer -> Integer
double :: Integer -> Integer

double takes an Integer but you are trying to pass it an Integer -> Integer.

Note that it is good practice to explicitly state the types of top-level functions in Haskell, as these often tell a lot about the functions and the program.

share|improve this answer

$ (called the apply operator) is not a different way of writing . (function composition operator). You can see that they are not the same by using ghci:

>:t ($)
($) :: (a -> b) -> a -> b

:t (.)
(.) :: (b -> c) -> (a -> b) -> a -> c

You can always substitute $ with parentheses. So func2 and func5 can be rewritten as:

func2 x = double (inc x)
func5 = double (inc)

But double expects a value of type Num a => a and you are passing it a value of type Num a => a -> a that's why it doesn't work.

You can read more about $ here, and about . here.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.