Doesn't tacit programming correspond pretty closely to combinator logic or ~~pointless~~ point-free style in Haskell? For instance, while I don't know J from what I gather a "fork" translates three functions `f`

, `g`

, and `h`

and an argument `x`

into an expression `g (f x) (h x)`

. The operation of "apply multiple functions to a single argument, then apply the results to each other in sequence" is a generalization of ~~Curry's~~ Schönfinkel's **S** combinator and in Haskell corresponds to the `Applicative`

instance of the Reader monad.

A `fork`

combinator in Haskell such that `fork f g h x`

matches the result specified above would have the type `(t -> a) -> (a -> b -> c) -> (t -> b) -> t -> c`

. Interpreting this as using the Reader functor `((->) t)`

and rewriting it for an arbitrary functor, the type becomes `f a -> (a -> b -> c) -> f b -> f c`

. Swapping the first two arguments gives us `(a -> b -> c) -> f a -> f b -> f c`

, which is the type of `liftA2`

/`liftM2`

.

So for the common example of computing the average, the fork `+/ % #`

can be translated directly as `flip liftA2 sum (/) (fromIntegral . length)`

or, if one prefers the infix `Applicative`

combinators, as `(/) <$> sum <*> fromIntegral . length`

.

If not, is there a technical issue that makes this impossible, or is it just not worth doing?

In Haskell at least, I think the main issue is that extremely point-free style is considered obfuscated and unreadable, particularly when using the Reader monad to split arguments.