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I'm trying to understand what the dot operator is doing in this Haskell code:

sumEuler = sum . (map euler) . mkList

The entire source code is below.

My understanding

The dot operator is taking the two functions sum and the result of map euler and the result of mkList as the input.

But, sum isn't a function it is the argument of the function, right? So what is going on here?

Also, what is (map euler) doing?

Code

mkList :: Int -> [Int]
mkList n = [1..n-1]

euler :: Int -> Int
euler n = length (filter (relprime n) (mkList n))

sumEuler :: Int -> Int
sumEuler = sum . (map euler) . mkList
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Thre is the best explanation, i think: stackoverflow.com/questions/2486564/… – ses Sep 3 '14 at 15:48
1  
@ses you probably mean this answer: stackoverflow.com/a/2486599 (which, I agree, is definitely concise and to the point). – 7heo.tk Apr 17 '15 at 14:48
up vote 85 down vote accepted

Put simply, . is function composition, just like in math:

f (g x) = (f . g) x

In your case, you are creating a new function, sumEuler that could also be defined like this:

sumEuler x = sum (map euler (mkList x))

The style in your example is called "point-free" style -- the arguments to the function are omitted. This makes for clearer code in many cases. (It can be hard to grok the first time you see it, but you will get used to it after a while. It is a common Haskell idiom.)

If you are still confused, it may help to relate . to something like a UNIX pipe. If f's output becomes g's input, whose output becomes h's input, you'd write that on the command-line like f < x | g | h. In Haskell, . works like the UNIX |, but "backwards" -- h . g . f $ x. I find this notation to be quite helpful when, say, processing a list. Instead of some unwieldy construction like map (\x -> x * 2 + 10) [1..10], you could just write (+10) . (*2) <$> [1..10]. (And, if you want to only apply that function to a single value; it's (+10) . (*2) $ 10. Consistent!)

The Haskell wiki has a good article with some more detail: http://www.haskell.org/haskellwiki/Pointfree

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"just like in math"? I don't think I've ever actually seen a glyph like the canonical representation of ASCII 0x2E used for function composition by any of my professor as an undergrad or in any papers I've read since then. It's not rendered near the baseline. Instead it's more like UNICODE U+00B7 MIDDLE DOT, U+22C5 DOT OPERATOR, or even U+2218 RING OPERATOR, rendered approximately at the mid line. It's certainly closer than using '\' for 'λ', but it's not "just like in math". – Boyd Stephen Smith Jr. Mar 25 '14 at 22:07
7  
@BoydStephenSmithJr. I think he meant that the operator works just like it does it math, not that it looks the same. – Cameron Martin Jul 11 '14 at 19:54
    
thank you! with the unix pipe I got it! – Nicolas Jan 14 '15 at 15:57
    
I really like the pipe analogy! F# actually had an |> operator that functioned like a pipe. – Alex Reinking Mar 27 '15 at 18:57

sum is a function in the Haskell Prelude, not an argument to sumEuler. It has the type

Num a => [a] -> a

The function composition operator . has type

(b -> c) -> (a -> b) -> a -> c

So we have

sum                        :: Num a => [a] -> a
map                        :: (a -> b) -> [a] -> [b]
euler                      :: Int -> Int
mkList                     :: Int -> [Int]
(map euler)                :: [Int] -> [Int]
(map euler) . mkList       :: Int -> [Int]
sum . (map euler) . mkList :: Int -> Int

Note that Int is an instance of Num.

share|improve this answer

The . operator composes functions. For example,

a . b

Where a and b are functions is a new function that runs b on its arguments, then a on those results. Your code

sumEuler = sum . (map euler) . mkList

is exactly the same as:

sumEuler myArgument = sum (map euler (mkList myArgument))

but hopefully easier to read. The reason there are parens around map euler is because it makes it clearer that there are 3 functions being composed: sum, map euler and mkList - map euler is a single function.

Edit: removed erroneous information about precedence.

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2  
Not true, the parentheses around "map euler" are not necessary. They are there for clarification only. Remember: Function application is higher precedence than any operator. – Porges Mar 11 '09 at 8:46
    
Oh! Thanks for the clarification. I'll add it inline. – Jesse Rusak Mar 11 '09 at 10:30
    
that runs b on its arguments, then a on those results. - but what are the arguments of this new function? – Alan Coromano Sep 3 '13 at 14:56
    
@MariusKavansky Sorry, by "runs b on its arguments" I mean "runs b on the arguments passed to the new function". In the example above, it runs mkList on the arguments passed to sumEuler, for example. – Jesse Rusak Sep 3 '13 at 19:45

The . operator is used for function composition. Just like math, if you have to functions f(x) and g(x) f . g becomes f(g(x)).

map is a built-in function which applies a function to a list. By putting the function in parentheses the function is treated as an argument. A term for this is currying. You should look that up.

What is does is that it takes a function with say two arguments, it applies the argument euler. (map euler) right? and the result is a new function, which takes only one argument.

sum . (map euler) . mkList is basically a fancy way of putting all that together. I must say, my Haskell is a bit rusty but maybe you can put that last function together yourself?

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The dot operator applies the function on the left (sum) to the output of the function on the right. In your case, you're chaining several functions together - you're passing the result of mkList to (map euler), and then passing the result of that to sum. This site has a good introduction to several of the concepts.

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