I tried to understand this elegant solution myself, so I tried to derive the types and evaluation myself. So, we need to write a function:

```
zip xs ys = foldr step done xs ys
```

Here we need to derive `step`

and `done`

, whatever they are. Recall `foldr`

's type, instantiated to lists:

```
foldr :: (a -> state -> state) -> state -> [a] -> state
```

However our `foldr`

invocation must be instantiated to something like below, because we must accept not one, but two list arguments:

```
foldr :: (a -> ? -> ?) -> ? -> [a] -> [b] -> [(a,b)]
```

Because `->`

is right-associative, this is equivalent to:

```
foldr :: (a -> ? -> ?) -> ? -> [a] -> ([b] -> [(a,b)])
```

Our `([b] -> [(a,b)])`

corresponds to `state`

type variable in the original `foldr`

type signature, therefore we must replace every occurrence of `state`

with it:

```
foldr :: (a -> ([b] -> [(a,b)]) -> ([b] -> [(a,b)]))
-> ([b] -> [(a,b)])
-> [a]
-> ([b] -> [(a,b)])
```

This means that arguments that we pass to `foldr`

must have the following types:

```
step :: a -> ([b] -> [(a,b)]) -> [b] -> [(a,b)]
done :: [b] -> [(a,b)]
xs :: [a]
ys :: [b]
```

Recall that `foldr (+) 0 [1,2,3]`

expands to:

```
1 + (2 + (3 + 0))
```

Therefore if `xs = [1,2,3]`

and `ys = [4,5,6,7]`

, our `foldr`

invocation would expand to:

```
1 `step` (2 `step` (3 `step` done)) $ [4,5,6,7]
```

This means that our `1 `step` (2 `step` (3 `step` done))`

construct must create a recursive function that would go through `[4,5,6,7]`

and zip up the elements. (Keep in mind, that if one of the original lists is longer, the excess values are thrown away). IOW, our construct must have the type `[b] -> [(a,b)]`

.

`3 `step` done`

is our base case, where `done`

is an initial value, like `0`

in `foldr (+) 0 [1..3]`

. We don't want to zip anything after 3, because 3 is the final value of `xs`

, so we must terminate the recursion. How do you terminate the recursion over list in the base case? You return empty list `[]`

. But recall `done`

type signature:

```
done :: [b] -> [(a,b)]
```

Therefore we can't return just `[]`

, we must return a function that would ignore whatever it receives. Therefore use `const`

:

```
done = const [] -- this is equivalent to done = \_ -> []
```

Now let's start figuring out what `step`

should be. It combines a value of type `a`

with a function of type `[b] -> [(a,b)]`

and returns a function of type `[b] -> [(a,b)]`

.

In `3 `step` done`

, we know that the result value that would later go to our zipped list must be `(3,6)`

(knowing from original `xs`

and `ys`

). Therefore `3 `step` done`

must evaluate into:

```
\(y:ys) -> (3,y) : done ys
```

Remember, we must return a function, inside which we somehow zip up the elements, the above code is what makes sense and typechecks.

Now that we assumed how exactly `step`

should evaluate, let's continue the evaluation. Here's how all reduction steps in our `foldr`

evaluation look like:

```
3 `step` done -- becomes
(\(y:ys) -> (3,y) : done ys)
2 `step` (\(y:ys) -> (3,y) : done ys) -- becomes
(\(y:ys) -> (2,y) : (\(y:ys) -> (3,y) : done ys) ys)
1 `step` (\(y:ys) -> (2,y) : (\(y:ys) -> (3,y) : done ys) ys) -- becomes
(\(y:ys) -> (1,y) : (\(y:ys) -> (2,y) : (\(y:ys) -> (3,y) : done ys) ys) ys)
```

The evaluation gives rise to this implementation of step (note that we account for `ys`

running out of elements early by returning an empty list):

```
step x f = \[] -> []
step x f = \(y:ys) -> (x,y) : f ys
```

Thus, the full function `zip`

is implemented as follows:

```
zip :: [a] -> [b] -> [(a,b)]
zip xs ys = foldr step done xs ys
where done = const []
step x f [] = []
step x f (y:ys) = (x,y) : f ys
```

P.S.: If you are inspired by elegance of folds, read *Writing foldl using foldr* and then Graham Hutton's *A tutorial on the universality and expressiveness of fold*.