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
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''
foldr isn't so difficult:
mapMaybe :: (a -> Maybe b) -> [a] -> [b]
mapMaybe f = foldr (\x xs -> maybe xs (: xs) (f x)) 
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
bs, the result is an empty list. If there is at least one, we construct a pair and call
f on the rest of
zip :: [a] -> [b] -> [(a,b)]
zip = foldr step (const )
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.