After looking up the Control.Monad
documentation, I'm confused about
this passage:
The above laws imply:
fmap f xs = xs >>= return . f
How do they imply that?
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After looking up the Control.Monad
documentation, I'm confused about
this passage:
The above laws imply:
fmap f xs = xs >>= return . f
How do they imply that?
Control.Applicative
says
As a consequence of these laws, the
Functor
instance for f will satisfyfmap f x = pure f <*> x
The relationship between Applicative
and Monad
says
pure = return
(<*>) = ap
ap
says
return f `ap` x1 `ap` ... `ap` xn
is equivalent to
liftMn f x1 x2 ... xn
Therefore
fmap f x = pure f <*> x
= return f `ap` x
= liftM f x
= do { v <- x; return (f v) }
= x >>= return . f
Applicative
level. That is: why is fmap f x = pure f <*> x
a consequence of the Applicative
laws? After all, they don't even mention fmap
! And then to answer that, you need @duplode's observation about parametricity...
– Daniel Wagner
May 22 '17 at 23:19
Functor
instances are unique, in the sense that if F
is a Functor
and you have a function foobar :: (a -> b) -> F a -> F b
such that foobar id = id
(that is, it follows the first functor law) then foobar = fmap
. Now, consider this function:
liftM :: Monad f => (a -> b) -> f a -> f b
liftM f xs = xs >>= return . f
What is liftM id xs
, then?
liftM id xs
xs >>= return . id
-- id does nothing, so...
xs >>= return
-- By the second monad law...
xs
liftM id xs = xs
; that is, liftM id = id
. Therefore, liftM = fmap
; or, in other words...
fmap f xs = xs >>= return . f
epheriment's answer, which routes through the Applicative
laws, is also a valid way of reaching this conclusion.