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Can a pointfree function return a tuple? For instance, can the following be written in pointfree style (where f1, f2, and f3 have been defined):

(\t -> (f1 t, f2 t, f3 t))

In this case, my f1, f2, and f3 are compositions of quot, mod, *, and some integers.

(\f1,f2,f3 -> (\t -> (f1 t, f2 t, f3 t)))

is a more general case, and is equivalent to

(\f1,f2,f3,t -> (f1 t, f2 t, f3 t))

Named functions are OK, but my examples are anonymous. (Named examples would be as follows)

f x = (f1 x, f2 x, f3 x)
f f1 f2 f3 x = (f1 x, f2 x, f3 x)

EDIT: I'm just curious for fun, I'm not going to do this.

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By the way, don't use quot and mod together. Either use quot and rem (or just quotRem) or use div and mod (or just use divMod). These pairings have guarantees, namely, that quotRem m n = (q, r) implies n * q + r = m (and similarly for divMod). –  Daniel Wagner Sep 12 '12 at 23:09
okay, thank you! –  Andrew Sep 13 '12 at 21:19
why have two pairs, by the way? –  Andrew Sep 16 '12 at 0:59
quotRem and divMod have different behaviors on negative numbers. divMod always returns a positive mod part, but quotRem is typically a tiny bit faster. –  Daniel Wagner Sep 16 '12 at 2:29
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5 Answers

up vote 11 down vote accepted

You can write

(\t -> (f1 t, f2 t, f3 t))

pointfree, it's

liftM (,,) f1 `ap` f2 `ap` f3

with ap from Control.Monad and the Monad instance of (->) a from Control.Monad.Instances. A somewhat more readable form may be the Control.Applicative variant

(,,) <$> f1 <*> f2 <*> f3

You can then further point-free

(\f1 f2 f3 -> (\t -> (f1 t, f2 t, f3 t)))


  \f1 f2 f3 -> (,,) <$> f1 <*> f2 <*> f3
= \f1 f2 -> ((,,) <$> f1 <*> f2 <*>)
= \f1 f2 -> (<*>) ((,,) <$> f1 <*> f2)
= \f1 f2 -> ((<*>) . ((,,) <$> f1 <*>)) f2
= \f1 -> (<*>) . ((,,) <$> f1 <*>)
= \f1 -> (<*>) . (<*>) ((,,) <$> f1)
= \f1 -> (((<*>) .) . (<*>) . (<$>) (,,)) f1
= ((<*>) .) . (<*>) . (<$>) (,,)

but seriously, you shouldn't. Keep it readable, that means a bit of pointfreeing is good, but don't overdo it.

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I think this answer is much better than mine, I was mostly forwarding what lambdabot gave. In particular, I like the Control.Applicative variant! –  Frerich Raabe Sep 12 '12 at 19:53
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Although the applicative or monadic version is simpler and shorter, one way that perhaps exposes the "meaning" (and what property of the category of Haskell types you are using) is using Control.Arrow

uncurry (uncurry (,,)) . ((f &&& g) &&& h)

The pointfull version is superior though.

This also exposes that you need the "Cartesianess" of Hask, but not all the "Closedness" of Hask

 arrowized :: Arrow cat => cat a a1 -> cat a b1 -> cat a b -> cat a (a1, b1, b)
 arrowized f g h => arr (uncurry (uncurry (,,))) . ((f &&& g) &&& h)
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Yes. The "lambdabot" IRC bot on the #haskell IRC channel actually has a feature which gives you the point-free version of a given function. In your case, it says that

\x -> (f x, g x, h x)

is equivalent to

ap (liftM2 (,,) f g) h
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I love how lambdabot uses the function monad. –  Philip JF Sep 12 '12 at 19:51
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You can write your example like this:

\f1 f2 f3 t -> (,,) (f1 t) (f2 t) (f3 t)

(,,) is a usual function with 3 arguments, so there's nothing special in making its application pointfree. However, it uses its argument 3 times so it's going to be cumbersome and it's probably not worth it.

Lambdabot at #haskell says it's (ap .) . liftM2 (,,). Enjoy :)

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Here's some elaboration on the other's answers here.

Inside the source code for Control.Applicative we find

instance Applicative ((->) a) where  -- (a ->) is meant here
    pure = const
    (<*>) f g x = f x (g x)

liftA3 f a b c = f <$> a <*> b <*> c

In GHCi, we get

Prelude Control.Applicative> :t liftA3 (,,)
liftA3 (,,) :: (Applicative f) => f a -> f b -> f c -> f (a, b, c)

So, with (t->) as f, liftA3 (,,) just works:

liftA3 (,,) ~ (t->a) -> (t->b) -> (t->c) -> (t->(a,b,c))

I.e., calling liftA3 (,,) f1 f2 f3 t produces a triple (f1 t, f2 t, f3 t), given three functions on same-type input:

Prelude Control.Applicative> liftA3 (,,) (:[]) (quot 12) (`rem`3) 4

So, how does it work? By the definiton of liftA3, and then of <*>,

liftA3 (,,) f g h t = ((((,,) <$> f) <*> g) <*> h) t
    = (((,,) <$> f) <*> g) t (h t)
    = (((,,) <$> f) t (g t) (h t)

Now, (<$>) = fmap and instance Functor ((->) t) defines fmap = (.), so we continue

    = (((,,) . f) t (g t) (h t)
    = (,,) (f t) (g t) (h t)
    = (f t, g t, h t)
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