I'm reading Conor McBride and Ross Paterson's "Functional Pearl / Idioms: applicative programming with effects:" (The
new version, with "idioms" in the title). I'm having a little difficulty with Exercise 4, which is explained below. Any hints would be much appreciated (especially: should I start writing
You want to create an
instance Monad  where
return x = repeat x
ap = zapp.
Standard library functions
As on p. 2 of the paper,
ap applies a monadic function-value to a monadic value.
ap :: Monad m => m (s -> t) -> m s -> m t ap mf ms = do f <- mf s <- ms return (f s)
I expanded this in canonical notation to,
ap mf ms = mf >>= (\f -> (ms >>= \s -> return (f s)))
The list-specific function
zapp ("zippy application") applies a function from one list to a corresponding value in another, namely,
zapp (f:fs) (s:ss) = f s : zapp fs ss
Note that in the expanded form,
mf :: m (a -> b) is a list of functions
[(a -> b)] in our case. So, in the first application of
>>=, we have
(f:fs) >>= mu
mu = (\f -> (ms >>= \s -> return (f s))). Now, we can call
fs >>= mu as a subroutine, but this doesn't know to remove the first element of
ms. (recall that we want the resulting list to be [f1 s1, f2 s2, ...]. I tried to hack something but... as predicted, it didn't work... any help would be much appreciated.
Thanks in advance!
I think I got it to work; first I rewrote
join as user "comonad" suggested .
My leap of faith was assuming that
fmap = map. If anyone can explain how to get there, I'd appreciate it very much. After this, it's clear that
join works on the list of lists user "comonad" suggested, and should be the diagonal,
\x -> zipWith ((!!) . unL) x [0..]. My complete code is this:
newtype L a = L [a] deriving (Eq, Show, Ord) unL (L lst) = lst liftL :: ([a] -> [b]) -> L a -> L b liftL f = L . f . unL joinL :: L (L a) -> L a joinL = liftL $ \x -> zipWith ((!!) . unL) x [0..] instance Functor L where fmap f = liftL (map f) instance Monad L where return x = L $ repeat x m >>= g = joinL (fmap g m)
hopefully that's right (seems to be the "solution" on p. 18 of the paper) ... thanks for the help, everyone!