Well, `fmap`

is just `(a -> b) -> f a -> f b`

, i.e. we want to transform the monadic action's result with a pure function. That's easy to write with do notation:

```
fmap f m = do
a <- m
return (f a)
```

or, written "raw":

```
fmap f m = m >>= \a -> return (f a)
```

This is available as `Control.Monad.liftM`

.

`pure :: a -> f a`

is of course `return`

. `(<*>) :: f (a -> b) -> f a -> f b`

is a little trickier. We have an action returning a function, and an action returning its argument, and we want an action returning its result. In do notation again:

```
mf <*> mx = do
f <- mf
x <- mx
return (f x)
```

Or, desugared:

```
mf <*> mx =
mf >>= \f ->
mx >>= \x ->
return (f x)
```

Tada! This is available as `Control.Monad.ap`

, so we can give a complete instance of `Functor`

and `Applicative`

for any monad `M`

as follows:

```
instance Functor M where
fmap = liftM
instance Applicative M where
pure = return
(<*>) = ap
```

Ideally, we'd be able to specify these implementations directly in `Monad`

, to relieve the burden of defining separate instances for every monad, such as with this proposal. If that happens, there'll be no real obstacle to making `Applicative`

a superclass of `Monad`

, as it'll ensure it doesn't break any existing code. On the other hand, this means that the boilerplate involved in defining `Functor`

and `Applicative`

instances for a given `Monad`

is minimal, so it's easy to be a "good citizen" (and such instances should be defined for any monad).