Lifts, and the dual notion of extensions, are absolutely used in Haskell, perhaps most prominently in the guise of comonadic extend
and monadic bind
. (Confusingly, extend
is a lift, not an extension.) A comonad w
's extend
lets us take a function w a > b
and lift it along extract :: w b > b
to get a map w a > w b
. In ASCII art, given the diagram
w b

V
w a > b
where the vertical arrow is extract, extend
gives us a diagonal arrow (making the diagram commute):
> w b
/ 
/ V
w a > b
More familiar to most Haskellers is the dual notion of bind
(>>=
) for a monad m
. Given a function a > m b
and return :: a > m a
, we can "extend" our function along return
to get a function m a > m b
. In ASCII art:
a > m b

V
m a
gives us
a > m b
 __A
V /
m a
(That A
is an arrowhead!)
So yes, extend
could have been called lift
, and bind
could have been called extend
. As for Haskell's lift
s, I have no idea why they're called that!
EDIT: Actually, I think that again, Haskell's lift
s are actually extensions. If f
is applicative, and we have a function a > b > c
, we can compose this function with pure :: c > f c
to get a function a > b > f c
. Uncurrying, this is the same as a function (a, b) > f c
. Now we can also hit (a, b)
with pure
to get a function (a, b) > f (a, b)
. Now, by fmap
ing fst
and snd
, we get a functions f (a, b) > f a
and f (a, b) > f b
, which we can combine to get a function f (a, b) > (f a, f b)
. Composing with our pure
from before gives (a, b) > (f a, f b)
. Phew! So to recap, we have the ASCII art diagram
(a, b) > f c

V
(f a, f b)
Now liftA2
gives us a function (f a, f b) > f c
, which I won't draw because I'm sick of making terrible diagrams. But the point is, the diagram commutes, so liftA2
actually gives us an extension of the horizontal arrow along the vertical one.