An applicative lets you apply a function in a context to a value in a context. So for instance, you can apply `some((i: Int) => i + 1)`

to `some(3)`

and get `some(4)`

. Let's forget that for now. I'll come back to that later.

List has two representations, it's either `Nil`

or `head :: tail`

. You may be used to fold over it using `foldLeft`

but there is another way to fold over it:

```
def foldr[A, B](l: List[A], acc0: B, f: (A, B) => B): B = l match {
case Nil => acc0
case x :: xs => f(x, foldr(xs, acc0, f))
}
```

Given `List(1, 2)`

we fold over the list applying the function starting from the right side - even though we really deconstruct the list from the left side!

```
f(1, f(2, Nil))
```

This can be used to compute the length of a list. Given `List(1, 2)`

:

```
foldr(List(1, 2), 0, (i: Int, acc: Int) => 1 + acc)
// returns 2
```

This can also be used to *create* another list:

```
foldr[Int, List[Int]](List(1, 2), List[Int](), _ :: _)
//List[Int] = List(1, 2)
```

So given an empty list and the `::`

function we were able to create another list. What if our elements are in some *context*? If our context is an applicative then we can still apply our elements and `::`

in that context. Continuing with `List(1, 2)`

and `Option`

as our applicative. We start with `some(List[Int]()))`

we want to apply the `::`

function in the `Option`

context. This is what the `F.map2`

does. It takes two values in their `Option`

context, put the provided function of two arguments into the `Option`

context and apply them together.

So outside the context we have `(2, Nil) => 2 :: Nil`

In context we have: `(Some(2), Some(Nil)) => Some(2 :: Nil)`

Going back to the original question:

```
// do a foldr
DList.fromList(l).foldr(F.point(List[B]())) {
// starting with an empty list in its applicative context F.point(List[B]())
(a, fbs) => F.map2(f(a), fbs)(_ :: _)
// Apply the `::` function to the two values in the context
}
```

I am not sure why the difference `DList`

is used. What I see is that it uses trampolines so hopefully that makes this implementation work without blowing the stack, but I have not tried so I don't know.

The interesting part about implementing the right fold like this is that I think it gives you an approach to implement traverse for algebric data types using catamorphisms.

For instance given:

```
trait Tree[+A]
object Leaf extends Tree[Nothing]
case class Node[A](a: A, left: Tree[A], right: Tree[A]) extends Tree[A]
```

Fold would be defined like this (which is really following the same approach as for `List`

):

```
def fold[A, B](tree: Tree[A], valueForLeaf: B, functionForNode: (A, B, B) => B): B = {
tree match {
case Leaf => valueForLeaf
case Node(a, left, right) => functionForNode(a,
fold(left, valueForLeaf, functionForNode),
fold(right, valueForLeaf, functionForNode)
)
}
}
```

And traverse would use that `fold`

with `F.point(Leaf)`

and apply it to `Node.apply`

. Though there is no `F.map3`

so it may be a bit cumbersome.