Obligatory cryptic answer:

```
import Control.Arrow
import Data.Composition
both :: (a -> Bool) -> (a -> Bool) -> a -> Bool
both = uncurry (&&) .** (&&&)
```

Someday I'll get around to documenting my Data.Composition library properly (it's on hackage!), but basically `(.**) f g x y z = f (g x y z)`

Here's how it works (simplified how &&& works on functions)

```
(&&&) f g x = (f x, g x)
uncurry f (x,y) = f x y
(.**) f g x y z = f (g x y z)
both = uncurry (&&) .** (&&&)
-- undo infix notation
both = (.**) (uncurry (&&)) (&&&)
-- definition of .**, with f = (uncurry (&&)), g = (&&&), x = p1, y = p2, z = v
both = \p1 p2 v -> (uncurry (&&)) ((&&&) p1 p2 v)
-- definition of &&&, with f = p1, g = p2, x = v
both = \p1 p2 v -> (uncurry (&&)) (p1 v, p2 v)
-- definition of uncurry, with f = (&&)
both = \p1 p2 v -> (\(x, y) -> (&&) x y) (p1 v, p2 v)
-- function application, bind x = p1 v, y = pw v
both = \p1 p2 v -> (&&) (p1 v) (p2 v)
-- rewrite without lambda, move && to infix position
both p1 p2 v = p1 v && p2 v
```

We have now arrived at hammar's definition. :)

`(&&)`

function. Else I don't understand your question. – missingfaktor Oct 10 '11 at 19:52`:: a -> Bool`

? – Tarrasch Oct 10 '11 at 19:57