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# Applying multiple functions to the same value point-free style in Haskell

I was bored one day and wanted to exercise my brain, so I decided to do the 99 Haskell Problems but restricted myself to doing them in point-free style. A problem that seems to crop up a lot when I'm doing things in point-free style is this: How do you apply multiple functions to the same value while keeping each result as an independent entity? Using pointed notation:

``````foobar x = [id x, reverse x]
``````

And what I've come up with so far in point-free notation:

``````foobar' = `map` [id, reverse] (\$ x)
``````

I can't seem to get that `x` off the end of there.

-

Others have already posted how you can do this using the `Reader` monad, but that's not the only way. It turns out that your second function is pretty close. I think you meant to post

``````foobar' x = (`map` [id, reverse]) (\$ x)
``````

Since the `x` is already near a rightmost position, you're almost there. First, transform the section `(\$ x)` into a function, because it's a bit easier to work with:

``````-- by the definition of a right operator section
foobar'2 x = (`map` [id, reverse]) (\y -> (\$) y x)
``````

Next remove the `x` from the lambda body by bringing a new variable into scope, and applying the function to `x`

``````-- lambda abstraction I think...
foobar'2 x = (`map` [id, reverse]) \$ (\z y -> (\$) y z) x
``````

Rewrite this application as a function composition, and then you can eta reduce:

``````-- by definition of '.'
foobar'3 x = (`map` [id, reverse]) . (\z y -> (\$) y z) \$ x

-- eta reduction
foobar'4 = (`map` [id, reverse]) . (\z y -> (\$) y z)
``````

Finally, notice that we can replace the lambda with a function

``````-- by definition of `flip`
foobar'5 = (`map` [id,reverse]) . flip (\$)
``````

and you have a point-free form.

-

Use sequence:

``````> let foobar' = sequence [id, reverse]
> foobar' "abcde"
["abcde","edcba"]
``````
-
Only if you're ok with the constraints. This won't work for all uses. – Thomas M. DuBuisson Jul 29 '12 at 14:43
@ThomasM.DuBuisson: what constraints? – Ben Millwood Aug 9 '12 at 14:30
@BenMillwood I'm referring to the typeclass constraints. JohnL's answer is of type `a -> [a]`. This answer, while nice and clean, is of type `Monad ((-> a) => a -> [a]`. – Thomas M. DuBuisson Aug 9 '12 at 15:57
@ThomasM.DuBuisson: That context indicates a missing instance that really ought to be in the Prelude - if you import `Control.Monad.Instances` then that constraint goes away forever. It will work for all uses. – Ben Millwood Aug 9 '12 at 18:25

You will be interested in the `Applicative` instance of the reader monad:

``````instance Applicative (e ->)
``````

Using it you can easily distribute an argument:

``````liftA2 (+) sin cos 3
``````

Here `sin` and `cos` are functions, which both receive the value 3. The individual results are then combined using `(+)`. You can further combine this with the `Category` instance of `(->)`, but of cource specialized versions of `(.)` and `id` are already defined in the `Prelude`.

Background: The `Applicative` instance for `(e ->)` really represents the SKI calculus, where `(<*>)` is the S combinator and `pure` is the K combinator. S is precisely used to distribute an argument to two functions:

``````S f g x = f x (g x)
``````

It takes a function application (f g) and makes both dependent on the value x ((f x) (g x)).

-

There are a few basic idiomatic combinators which pop up repeatedly, and are reimplemented with various higher concepts and libraries, but which are essentially very simple. Names may vary, and some are implementable in terms of others:

``````fork (f,g) x = (f x, g x)              -- == (f &&& g)
prod (f,g) x = (f \$ fst x, g \$ snd x)  -- == (f *** g)
pmap f (x,y) = (f x, f y)              -- == (f *** f)
dup     x    = (x,x)
``````

etc. Of course `uncurry f (x,y) == f x y` gets used a lot with these, too.

`&&&` and `***` are defined in `Control.Arrow`, as well as `first` and `second`. Then `prod (f,id) == first f`, `prod(id,g) == second g` etc. etc.

So your `foobar` becomes

``````foobar = (\(a,b)->[a,b]) . fork (id,reverse)
= (\(a,b)->[a,b]) . (id &&& reverse)
= (\(a,b)->[a,b]) . (id *** reverse) . dup
= join \$ curry ( (\(a,b)->[a,b]) . second reverse)
``````

For the last one you need to also import `Control.Monad` and `Control.Monad.Instances`. See also this question.

late edit: also, using `Control.Applicative` as hinted in answer by ertes,

``````       = (:) <*> ((:[]) . reverse)
``````
-
also, `(:) <*> (pure . reverse)` ( the `((->) r), []` Applicatives), `([id, reverse] <*>) . pure` ( the `[]` Applicative), `sequence [id, reverse]` ( the `((->) r)` Monad). – Will Ness Apr 23 at 20:08