``````data Free f a = Return a | Roll (f (Free f a))
``````

``````instance (Functor f) => Monad (Free f) where
return = Return
Return x    >>= f = f x
Roll action >>= f = Roll \$ fmap (>>= f) action
``````

and its functor instance

``````instance (Functor f) => Functor (Free f) where
fmap f (Return x) = Return (f x)
fmap f (Roll   x) = Roll \$ fmap (fmap f) x
``````

I know that every monad is an applicative functor with `pure = return` and `(<*>) = ap`. For me, applicative functors are conceptually harder than monads. For a better understanding of applicative functors, I like to have the applicative instance without resorting to `ap`.

The first line for `<*>`is easy:

``````instance (Applicative f) => Applicative (Free f) where
pure = Return
Return f <*> x = fmap f x -- follows immediately from pure f <*> x = f <\$> x
--Roll   f <*> x = Roll \$ (fmap ((fmap f) <*>)) x -- wrong, does not type-check
``````

How to define `Roll f <*> x` in basic terms with `fmap` and `<*>`?

``````instance (Functor f) => Applicative (Free f) where
The plan is to act only at the leaves of the tree which produces the function, so for `Return`, we act by applying the function to all the argument values produced by the argument action. For `Roll`, we just do to all the sub-actions what we intend to do to the overall action.
Crucially, what we do when we reach `Return` is already set before we start. We don't change our plans depending on where we are in the tree. That's the hallmark of being `Applicative`: the structure of the computation is fixed, so that values depend on values but actions don't.