# Point-free style and using \$

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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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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+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
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
+1 for the almost point-free version. –  dave4420 Nov 16 '11 at 17:46
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
@Dan Well, completely pointfree is often considered too pointless, at least by me. –  FUZxxl Nov 17 '11 at 17:13
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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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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