I'd like to @jozefg's answer, that it *is* possible to express the whole thing using folds. Any recursive operation on lists can be eventually expressed using `foldr`

, but often it's quite ugly.

First let's implement `locMax`

using `mapMaybe`

and `zip`

, very similarly to what @jozefg did::

```
import Prelude hiding (zip)
isMax :: (Ord a) => ((a, a), a) -> Maybe a
isMax ((x, y), z) | y > z && y > x = Just y
| otherwise = Nothing
locMax :: (Ord a) => [a] -> [a]
locMax xs@(_:xs'@(_:xs'')) = mapMaybe isMax $ zip (zip xs xs') xs''
```

Implementing `mapMaybe`

using `foldr`

isn't so difficult:

```
mapMaybe :: (a -> Maybe b) -> [a] -> [b]
mapMaybe f = foldr (\x xs -> maybe xs (: xs) (f x)) []
```

Implementing `zip`

is a bit more tricky, since we need to consume two lists at once. What we'll do is that we'll accumulate inside `foldr`

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

that'll consume the second list.

The base case is simple. If the first list is empty, the constructed function is `const []`

, so whatever is the second list, the result is also empty.

The folding step takes a value `x : a`

, an accumulated function that converts a sub-list of `[b]`

. And since we're producing a function again, we just take a third argument of type `[b]`

. If there are no `b`

s, the result is an empty list. If there is at least one, we construct a pair and call `f`

on the rest of `b`

s:

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

You can verify that this implementation has the required properties and works properly also if one or both lists are infinite.

`drop`

and`take`

to get the interior of the list, and then use a`foldl`

. – Eric Feb 26 '14 at 16:07