Applicative functors are well-known and well-loved among Haskellers, for their ability to apply functions in an effectful context.
In category-theoretic terms, it can be shown that the methods of
pure :: a -> f a (<*>) :: f (a -> b) -> f a -> f b
are equivalent to having a
Functor f with the operations:
unit :: f () (**) :: (f a, f b) -> f (a,b)
the idea being that to write
pure you just replace the
unit with the given value, and to write
(<*>) you squish the function and argument into a tuple and then map a suitable application function over it.
Moreover, this correspondence turns the
Applicative laws into natural monoidal-ish laws about
(**), so in fact an applicative functor is precisely what a category theorist would call a lax monoidal functor (lax because
(**) is merely a natural transformation and not an isomorphism).
Okay, fine, great. This much is well-known. But that's only one family of lax monoidal functors – those respecting the monoidal structure of the product. A lax monoidal functor involves two choices of monoidal structure, in the source and destination: here's what you get if you turn product into sum:
class PtS f where unit :: f Void (**) :: f a -> f b -> f (Either a b) -- some example instances instance PtS Maybe where unit = Nothing Nothing ** Nothing = Nothing Just a ** Nothing = Just (Left a) Nothing ** Just b = Just (Right b) Just a ** Just b = Just (Left a) -- ick, but it does satisfy the laws instance PtS  where unit =  xs ** ys = map Left xs ++ map Right ys
It seems like turning sum into other monoidal structures is made less interesting by
unit :: Void -> f Void being uniquely determined, so you really have more of a semigroup going on. But still:
- Are other lax monoidal functors like the above studied or useful?
- Is there a neat alternative presentation for them like the