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How does one combine using $ and point-free style?

A clear example is the following utility function:

times :: Int -> [a] -> [a]
times n xs = concat $ replicate n xs  

Just writing concat $ replicate produces an error, similarly you can't write concat . replicate either because concat expects a value and not a function.

So how would you turn the above function into point-free style?

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5 Answers 5

up vote 19 down vote accepted

You can use this combinator: (The colon hint that there follow two arguments)

(.:) :: (c -> d) -> (a -> b -> c) -> a -> b -> d
(.:) = (.) . (.)

It allows you to get rid of the n:

time = concat .: replicate
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3  
+1 It's a shame we can't call it (..). –  dave4420 Nov 16 '11 at 17:47
    
@dave4420 Well, IMHO .: is much more mnemnoric –  FUZxxl Nov 16 '11 at 18:02
2  
I personally prefer .*, so that the next ones can be .**, .***, etc. Either way, we should try to get .: into Haskell Prime's Prelude, or at least into base libraries. –  Dan Burton Nov 16 '11 at 21:25
    
Is fmap fmap fmap a generalization of .:? –  nponeccop Nov 17 '11 at 14:57
    
@nponeccop Yes, but one is like (.), so it's rather fmap . fmap. –  FUZxxl Nov 17 '11 at 17:11

You can easily write an almost point-free version with

times n  =  concat . replicate n

A fully point-free version can be achieved with explicit curry and uncurry:

times  =  curry $ concat . uncurry replicate
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IMHO the last one is unneccessarily complicated since it involves needless curry and uncurry, see the answer of Josh and me. –  FUZxxl Nov 16 '11 at 16:59
5  
+1 for the almost point-free version. –  dave4420 Nov 16 '11 at 17:46
3  
Another +1 for the almost point-free version. While I recommend wider adoption of .:, I also recommend sticking with "almost" point-free for more convoluted cases. –  Dan Burton Nov 16 '11 at 21:36
3  
@Dan Well, completely pointfree is often considered too pointless, at least by me. –  FUZxxl Nov 17 '11 at 17:13
1  
and by me :) Adapt the degree of point-free to your skills and taste. There are some fundamental flaws with point free style which can be observed by studying combinatory logic - the ultimate pointfree calculus. Also take a look at Tony Hoare's work on function-based programming. –  nponeccop Nov 17 '11 at 19:10

Get on freenode and ask lambdabot ;)

<jleedev> @pl \n xs -> concat $ replicate n xs
<lambdabot> (join .) . replicate
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1  
That's always a good idea. –  FUZxxl Nov 16 '11 at 17:00
    
Note that (foo . ) . bar is lambdabot's typical pattern for foo .: bar, since .: is apparently not considered in the poitless-ing process. –  Dan Burton Nov 16 '11 at 21:34

By extending FUZxxl's answer, we got

(.:) :: (c -> d) -> (a -> b -> c) -> a -> b -> d
(.:) = (.).(.)

(.::) :: (d -> e) -> (a -> b -> c -> d) -> a -> b -> c -> e
(.::) = (.).(.:)

(.:::) :: (e -> f) -> (a -> b -> c -> d -> e) -> a -> b -> c -> d -> f
(.:::) = (.).(.::)

...

Very nice.

Bonus

(.:::) :: (e -> f) -> (a -> b -> c -> d -> e) -> a -> b -> c -> d -> f
(.:::) = (.:).(.:)

Emm... so maybe we should say

(.1) = .

(.2) :: (c -> d) -> (a -> b -> c) -> a -> b -> d
(.2) = (.1).(.1)

(.3) :: (d -> e) -> (a -> b -> c -> d) -> a -> b -> c -> e
(.3) = (.1).(.2)
-- alternatively, (.3) = (.2).(.1)

(.4) :: (e -> f) -> (a -> b -> c -> d -> e) -> a -> b -> c -> d -> f
(.4) = (.1).(.3)
-- alternative 1 -- (.4) = (.2).(.2)
-- alternative 2 -- (.4) = (.3).(.1)

Even better.

We can also extend this to

fmap2 :: (Functor f, Functor g) => (a -> b) -> f (g a) -> f (g b)
fmap2 f = fmap (fmap f)

fmap4 :: (Functor f, Functor g, Functor h, functro i) 
   => (a -> b) -> f (g (h (i a))) -> f (g (h (i b)))
fmap4 f = fmap2 (fmap2 f)

which follows the same pattern.

It would be even better to have the times of applying fmap or (.) parameterized. However, those fmap or (.)s are actually different on type. So the only way to do this would be using compile time calculation, for example TemplateHaskell.

For everyday uses, I would simply suggest

Prelude> ((.).(.)) concat replicate 5 [1,2]
[1,2,1,2,1,2,1,2,1,2]
Prelude> ((.).(.).(.)) (*10) foldr (+) 3 [2,1]
60
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In Haskell, function composition is associative¹:

f . g . h == (f . g) . h == f . (g . h)

Any infix operator is just a good ol' function:

2 + 3 == (+) 2 3
f 2 3 = 2 `f` 3

A composition operator is just a binary function too, a higher-order one, it accepts 2 functions and returns a function:

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

Therefore any composition operator can be rewritten as such:

f . g == (.) f g
f . g . h == (f . g) . h == ((.) f g) . h == (.) ((.) f g) h
f . g . h == f . (g . h) == f . ((.) g h) == (.) f ((.) g h)

Every function in Haskell can be partially applied due to currying by default. Infix operators can be partially applied in a very concise way, using sections:

(-) == (\x y -> x - y)
(2-) == (-) 2 == (\y -> 2 - y)
(-2) == flip (-) 2 == (\x -> (-) x 2) == (\x -> x - 2)
(2-) 3 == -1
(-2) 3 == 1

As composition operator is just an ordinary binary function, you can use it in sections too:

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

Another interesting binary operator is $, which is just function application:

f x == f $ x
f x y z == (((f x) y) z) == f x y z
f(g(h x)) == f $ g $ h $ x == f . g . h $ x == (f . g . h) x

With this knowledge, how do I transform concat $ replicate n xs into point-free style?

times n xs = concat $ replicate n xs
times n xs = concat $ (replicate n) xs
times n xs = concat $ replicate n $ xs
times n xs = concat . replicate n $ xs
times n    = concat . replicate n
times n    = (.) concat (replicate n)
times n    = (concat.) (replicate n) -- concat is 1st arg to (.)
times n    = (concat.) $ replicate n
times n    = (concat.) . replicate $ n
times      = (concat.) . replicate

¹Haskell is based on category theory. A category in category theory consists of 3 things: some objects, some morphisms, and a notion of composition of morphisms. Every morphism connects a source object with a target object, one-way. Category theory requires composition of morphisms to be associative. A category that is used in Haskell is called Hask, whose objects are types and whose morphisms are functions. A function f :: Int -> String is a morphism that connects object Int to object String. Therefore category theory requires Haskell's function compositions to be associative.

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