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Is there any way to find out local maxima of a list using foldr or foldl or maybe I have to use unfoldr because of first and last elements of list aren't local maximums?

I understand how to find it using recursion with guards, e.g.

localMax :: [Int] -> [Int]
localMax []       = []
localMax (x:[])   = []
localMax (x:y:[]) = []
localMax (x:y:z:zs)
    | y > z && y > x = y:localMax (y:z:zs)
    | otherwise = localMax (y:z:zs)
share|improve this question
You could use drop and take to get the interior of the list, and then use a foldl. – Eric Feb 26 '14 at 16:07
@Eric You can't just use the interior because in [3,6,5] you have to compare with 3 and 5 to find that 6 is a local maximum. – AndrewC Feb 26 '14 at 16:44
FYI, this is a homework from Brent Yorgey's course on Haskell: – Mirzhan Irkegulov Jul 10 '14 at 12:59
up vote 2 down vote accepted

I'll try to only use the fold, as you asked. What about something like this?

lmax (x:y:xs) = third $ foldl f (x,y,[]) xs
    third (_, _, x) = x
    f (x, y, ls) z = (y, z, if y > x && y > z then y:ls else ls)

The idea is that you pass a tuple in the fold instead of a list of results. The tuple (a triple) will contain the last two elements and the list of results. The function evaluates whether the second element of the triple is a local minimum w.r.t. the first element (its predecessor) and the current element passed by the fold (its successor).

ghci> lmax [1,3,2]
ghci> lmax [3,4,2,5,1,7,6,1,9]
ghci> lmax [1..10]
ghci> lmax []
*** Exception: test.hs:(4,1)-(5,66): Non-exhaustive patterns in function lmax

Anyway, from this it should be easy to use whatever method you prefer in order to return an empty result list when the input list is too short.

Please note that, by using foldl, every new result is appended at the top. Because of this, the list of results is reversed. You might want to reverse again lmax's results if you want to have them in the same order as in the original list: lmax' = reverse . lmax.

share|improve this answer
Coding style is a little terse for something intended to teach but this solves the problem the OP was running into of how to get fold to handle the triple required. – Sean Perry Feb 26 '14 at 17:00
Also note the answer is backwards due to the use of foldl vs. foldr. – Sean Perry Feb 26 '14 at 17:06
True :) I removed the let by adding a more clear third function in order to simplify a bit, and I remarked the fact about reversed results. – Riccardo Feb 27 '14 at 8:56

You could, but itd be very ugly. Mostly because to find the local maximum, you'll need to know the previous and next elements.

The previous element is no problem, but a fold isn't supposed to know anything about the elements after it.

As a possible approach

 import Data.List (zip3)

 localMax xs = map proj2
               . filter isLocalMax
               $ zip3 xs (tail xs) (drop 2 xs)
   where isLocalMax (x, y, z) = x < y && z < y
         proj2 (_,x,_) = x

So we shift the list by one and two and zip it all together so [a, b, c, d, e] becomes [(a, b, c), (b, c, d), (c, d, e)] then we just use map and filter to select the appropriate elements.

Do note though that map and filter could be smashed into one foldr if you really wanted to.

share|improve this answer
Thanks a lot. So, using «clear» folds to solve this problem are impossible? Your solution works perfectly. I'll try to smash foldr instead of map and filter – zerospiel Feb 26 '14 at 16:43
@zerospiel You can use something like foldr (\x accum -> if isLocalMax x then x:accum else accum) instead of map and filter but ti's harder to read – jozefg Feb 26 '14 at 16:47
Also it'd be possible to combine map and filter into mapMaybe. – Petr Pudlák Feb 26 '14 at 18:59
it is quite easy to emulate the insightful paramorphism with the shortsighted foldr, after first taking init . tails. :) – Will Ness Feb 26 '14 at 19:55
@WillNess I should have been more specific, when the user said "I have to use a fold" I assumed he meant something to the effect of isSorted Pattern = foldr a b c for some trivial value of a b and c. Which you can totally do, but involves dragging state through tuples and I personally don't like. Of course my answer can trivially be a fold and yours is quite nice as well, but both require some jiggery pokery on the list before the actual fold – jozefg Feb 26 '14 at 20:00
localMaxAsUnfold :: [Int] -> [Int]
localMaxAsUnfold = unfoldr work
    work (x:y:z:rest)
      | y > x && y > z = Just (y, y:z:rest)
      | otherwise      = work (y:z:rest) -- cheat and recurse internally
    work _             = Nothing

localMaxAsFold :: [Int] -> [Int]
localMaxAsFold = foldr work [] . makeTriples
    makeTriples :: [Int] -> [(Int, Int, Int)]
    makeTriples vals = zip3 vals (tail vals) (drop 2 vals)

    work (x,y,z) vals
      | y > x && y > z = y : vals
      | otherwise      = vals
share|improve this answer
Thanks @jozefg, my makeTriples was hand coded previously. – Sean Perry Feb 26 '14 at 16:52

Idea is very close to what Will Ness suggested, but without applicative zips and a bit shorter:

lm a = foldr (\(x:y:z:_) a -> if y > z && y > x then y:a else a) [] 
             $ filter ((2<) . length) (tails a)

Readability still questionable though :)

Update As suggested by Will Ness, list comprehension also can be used:

lm a = [y | (x:y:z:_) <- tails a, x < y && y > z]
share|improve this answer
The test length x > 2 is redundant. I've edited this for you. :) this is the cleanest, shortest, nicest solution IMO. (though it's not a fold per se). -- BTW Common Lisp has two "maps" - mapcar (like the usual map) and maplist - like a map on tails. But Haskel has list comprehension with quiet pattern-mismatch! – Will Ness Mar 1 '14 at 16:42
Nice! But why it doesn't fails with "Irrefutable pattern failed" or "Non-exhaustive patterns"? – wonder.mice Mar 1 '14 at 18:20
exactly! that's the point here. That list comprehension is equivalent to do {(x:y:z:_)<- tails a; if (x<y&&y>z)then [y] else []}. The Report gives the translation of that as let { ok (x:y:z:_) = if (x<y&&y>z)then [y] else []; ok _ = fail "error message"} in tails a >>= ok where fail _ = []. The last bit is crucial. List monad's fail does not cause errors. It just skips over the mismatches, like Maybe monad's fail does as well: let { catMaybes :: [Maybe a] -> [a]; catMaybes xs = [x | Just x <- xs]}. – Will Ness Mar 1 '14 at 19:15

we can always call the shortsighted1 foldr over (init . tails) to emulate the insightful paramorphism:

import Data.List
import Control.Applicative

localMaxima :: Ord a => [a] -> [a]
localMaxima = foldr g [] . init . tails . (zip <*> tail) 
     g ((a,b):(_,c):_) r | a<b && b>c = b:r
     g  _              r              =   r

In this particular case init can be omitted. zip <*> tail (which is just a shorthand for \xs -> zip xs (tail xs)) forms a list of pairs of consecutive elements from the input list.

And no, I don't think it is particularly "ugly".2 :)

1 2 cf. this answer here
2 also another answer here

share|improve this answer
Thanks @WillNess, this was interesting. How do the various options presented to this question pan out in terms of performance? – Sean Perry Feb 26 '14 at 23:34

Here is another one that doesn't pattern match on the list at all and uses only fold:

g :: a -> (a -> Bool) -> (a -> Bool) -> [a]
g x p n | p x && n x = [x]
        | otherwise  = []

localMax :: Ord a => [a] -> [a]
localMax l = fr $ const False
  where (_, fr) = foldr worker (const False, \_ -> []) l
        worker x (p,f) = ((> x), \n -> g x p n ++ f (> x))

How does this work?

The basic idea is to use a function in the accumulator, so that we can "pass back" a later element to a previous stage. So we pass back a function of type a -> Bool, that returns True only if the next element is greater than the argument. (this function is called n for nextin the code above). We also have another function of type a -> Bool in the accumulator which returns True if the previous element is less than the passed value (called p for previous). We have a maximum exactly when both of the functions return True. This is what g checks.


*Main> localMax [3,4,2,5,1,7,6,1,9]
*Main> localMax [1..10]
*Main> localMax []
share|improve this answer

Here is another one with zipWith

localMax a = [ x | (x,v) <- zip a localMaxInd, v]
   localMaxInd = zipWith (&&) u v
              u = False : zipWith (>) (tail a) a
              v = zipWith (>) a (tail a) 

test case

> localMax [3,4,2,5,1,7,6,1,9]
share|improve this answer

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 bs, the result is an empty list. If there is at least one, we construct a pair and call f on the rest of bs:

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.

share|improve this answer
also, mapMaybe f = foldr (maybe id (:) . f) [] might be clearer for some people. – Will Ness Feb 26 '14 at 21:11

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