Let's try to understand this code from an elementary point of view. What does it even do, one wonders?

```
zipRev xs ys = foldr f id xs snd (ys,[])
where
-- f x k c = k (\(y:ys, r) -> c (ys, (x,y):r))
f x k c = k (g x c)
-- = (k . g x) c -- so,
-- f x k = k . g x
g x c (y:ys, r) = c (ys, (x,y):r)
```

Here we used lambda lifting to recover the `g`

combinator.

So then because `f x k = k . g x`

were `k`

goes *to the left* of `x`

, the input list is translated into a reversed chain of compositions,

```
foldr f id [x1, x2, x3, ..., xn] where f x k = k . g x
===>>
(((...(id . g xn) . ... . g x3) . g x2) . g x1)
```

and thus, it just does what a left fold would do,

```
zipRev [] ys = []
zipRev [x1, x2, x3, ..., xn] ys
= (id . g xn . ... . g x3 . g x2 . g x1) snd (ys, [])
= g xn (g xn1 ( ... ( g x3 ( g x2 ( g x1 snd)))...)) (ys, [])
where ----c--------------------------------------------
g x c (y:ys, r) = c (ys, (x,y):r)
```

So we went to the deep end of the `xs`

list, and then we come back consuming the `ys`

list left-to-right (i.e. top-down) on our way back right-to-left on the `xs`

list (i.e. bottom-up). This is straightforwardly coded as a right fold with strict reducer, so the flow is indeed right-to-left on the `xs`

. The bottom-most action (`snd`

) in the chain is done last, so in the new code it becomes the topmost (still done last):

```
zipRev xs ys = snd (foldr h (ys,[]) xs)
where
h x (y:ys, r) = (ys, (x,y):r)
```

`g x c`

was used as a continuation in the original code, with `c`

as a second-tier continuation; but it's actually all just been a regular fold from the right, all along.

So indeed it zips the reversed first list with the second. It's also unsafe; it misses a clause:

```
g x c ([], r) = c ([], r) -- or just `r`
g x c (y:ys, r) = c (ys, (x,y):r)
```

*(update:)* The answers by duplode (and Joseph Sible) do the lambda lifting a bit differently, in a way which is better suited to the task. It goes like this:

```
zipRev xs ys = foldr f id xs snd (ys,[])
where
f x k c = k (\((y:ys), r) -> c (ys, (x,y):r))
= k (c . (\((y:ys), r) -> (ys, (x,y):r)) )
= k (c . g x)
g x = (\((y:ys), r) -> (ys, (x,y):r))
{- f x k c = k ((. g x) c) = (k . (. g x)) c = (. (. g x)) k c
f x = (. (. g x)) -}
```

so then

```
foldr f id [ x1, x2, ... , xn ] snd (ys,[]) =
= ( (. (. g x1)) $ (. (. g x2)) $ ... $ (. (. g xn)) id ) snd (ys,[]) -- 1,2...n
= ( id . (. g xn) . ... . (. g x2) . (. g x1) ) snd (ys,[]) -- n...2,1
= ( snd . g x1 . g x2 . ... . g xn ) (ys,[]) -- 1,2...n!
= snd $ g x1 $ g x2 $ ... $ g xn (ys,[])
= snd $ foldr g (ys,[]) [x1, x2, ..., xn ]
```

Simple. :) Flipping twice is no flipping at all.

`zipRev`

fail if the second list is shorter than the first. I believe the laziest possible version that works regardless of relative lengths is this one I just put together. – dfeuer May 14 at 5:09