# Haskell dot (.) operator in de Morgan's law implementation

In this question, the author has written an implementation of de Morgan's laws in Haskell. I understand the implementations of `notAandnotB`, and `notAornotB`, but I'm struggling to understand the implementation of `notAorB` which is:

``````notAorB :: (Either a b -> c) -> (a -> c, b -> c)
notAorB f = (f . Left, f . Right)
``````

Could someone explain how the `(f . Left, f . Right)` part works? I've seen the `.` operator used before, but with three arguments, not two.

Recall that the definition of the `.` operator is `(f . g) x = f (g x)`, i.e. `f . g = \x -> f (g x)` (syntactically, it is a binary operator, it is just that Haskell’s syntax sugar permits the latter definition to be restated as the former). So, the definition you have can be rephrased as

``````notAorB f = ((\x -> f (Left x)), (\y -> f (Right y)))
``````

(this can be done mechanically by Lambdabot on #haskell, tell him to `@unpl ‹expr›`), or more verbosely

``````notAorB f = (lt, rt)
where lt x = f (Left x)
rt y = f (Right y)
``````

As always, try writing down the types. If `(.) :: ∀ s t u. (t -> u) -> (s -> t) -> s -> u`, `f :: Either a b -> c`, `Left :: ∀ p q. p -> Either p q`, then `f . Left` or `(.) f Left :: a -> c`, etc.