I want something like J's fork feature, I guess. Is there any way to do this?
This is, using so-called applicative style,
h <$> f <*> g
An alternative is to lift
h into the
(->) r applicative functor with
liftA2 h f g
The intuition behind that is that if
h :: a -> b -> c -- then -- liftA2 h :: (r -> a) -> (r -> b) -> r -> c
so the lifted version takes two functions
r -> something instead of the actual
somethings, and then feeds an
r to get the
somethings out of the functions.
liftA* and the corresponding combination of
<*> are equivalent.
While @kqr has the more practical solution based on the
Applicative instance for
((->) a), we can also talk about it in the "pipey" method
+----- f ------+ / \ <---- h +------< x \ / +----- g ------+
which provides a very compositional kind of pointfree program. We'll create this program with tools from
First we get the rightmost part of our diagram using a common missing function in Haskell called
--+ \ +----- x dup :: x -> (x, x) / dup x = (x, x) --+
then the middle is created using the
(***) combinator from
----- f ----- (***) :: (a -> b) -> (c -> d) -> (a, c) -> (b, d) f :: (a -> b) g :: (c -> d) ----- g ----- f *** g :: (a, c) -> (b, d)
then the left side is exactly what
uncurry does for us
+-- uncurry :: (a -> b -> c) -> (a, b) -> c / h :: (a -> b -> c) h uncurry h :: (a, b) -> c \ +--
Then wiring them all together we can erase the
x points with a very compositional style.
m :: (a -> b -> c) -> (x -> a) -> (x -> b) -> x -> c m h f g = uncurry h . (f *** g) . dup +------ f ----+ / \ <----- h +-----------< x (eta reduced) \ / +------ g ----+