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 `fmap`

and `join`

or `return`

and `>>=`

?).

### Problem Statement

You want to create an `instance Monad []`

where

```
return x = repeat x
```

and `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
```

### My difficulties

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
```

where `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!

### Edit 1

I think I got it to work; first I rewrote `ap`

with `fmap`

and `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!

`fmap`

: The`Applicative`

laws include the identity`pure f <*> x`

=`f <$> x`

. You should be able to show`fmap`

as being`map`

using this. And yes,`join`

takes the diagonal of the nested lists--as a follow-up exercise, you could try to show how the diagonal being ill-defined on lists of different lengths breaks the monad laws. – C. A. McCann Jul 5 '11 at 4:24