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I know that a standard way would be

(Eq z) => matchLists :: [x] -> [x] -> Bool
matchLists xs ys = xs == ys

But I have a special matching function for element which is passed from the outside and I have no control over it.

So what I am looking for is

matchLists :: (x -> x -> Bool) -> [x] -> [x] -> Bool

(Hoogle says no)

Would you end up with a custom function with a signature like this or what would you do instead?

EDIT:

zip functions don't do what I need since the resulting list has the minimal length out of 2 input lists

EDIT:

What do you think of this?

--matchListsWith :: (a -> a -> Bool) -> [a] -> [a] -> Bool
matchListsWith :: (a -> b -> Bool) -> [a] -> [b] -> Bool
matchListsWith _ [] [] = True
matchListsWith _ (_:_) [] = False
matchListsWith _ [] (_:_) = False
matchListsWith matcher (x:xs) (y:ys) = matcher x y && matchListsWith matcher xs ys
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1  
There's no reason for matchListsWith not to have the more general type (a -> b -> Bool) -> [a] -> [b] -> Bool. –  Cirdec Nov 5 '13 at 18:28
    
@Cirdec, that's a good point –  Aleksey Bykov Nov 5 '13 at 18:29

3 Answers 3

Using Data.Align we can handle both the zipping and the length issues at once

matchWith :: (a -> b -> Bool) -> [a] -> [b] -> Bool
matchWith f as bs = and $ alignWith combiner as bs where
  combiner = these (const False) (const False) f

This unfolds to the same code as your explicitly recursive function, but using tags from Data.These to mark the various list alignments. It also generalizes to many other structures like Trees or Sequences if you generalize the and.

matchWith :: (Foldable f, Align f) => (a -> b -> Bool) -> f a -> f b -> Bool
matchWith f as bs = Foldable.and $ alignWith combiner as bs where
  combiner = these (const False) (const False) f

data Tree a = Tip | Branch a (Tree a) (Tree a) deriving ( Functor, Foldable )

instance Align Tree where
  nil = Tip
  align Tip Tip = Tip
  align (Branch a la ra) Tip = Branch (This a) (fmap This la) (fmap This ra)
  align Tip (Branch b lb rb) = Branch (That b) (fmap That lb) (fmap That rb)
  align (Branch a la ra) (Branch b lb rb) =
    Branch (These a b) (align la lb) (align ra rb)

So that we have

λ> matchWith (==) Tip Tip
True
λ> matchWith (==) (Branch 3 Tip Tip) (Branch 3 Tip Tip)
True
λ> matchWith (==) (Branch 3 Tip Tip) (Branch 3 Tip (Branch 3 Tip Tip))
False

(Might as well...)

instance Eq a => Eq (Tree a) where (==) = matchWith (==)
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The hand-written approach is perfectly fine here, I think. If you're not already using some library that happens to have a suitable function for this problem, then I believe it isn't worth adding another dependency just for the sake of shaving off three lines of code.

You can still shave off a single line though:

matchListWith :: (a -> b -> Bool) -> [a] -> [b] -> Bool
matchListWith f (x:xs) (y:ys) = f x y && matchListWith f xs ys
matchListWith _ []     []     = True
matchListWith _ _      _      = False
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One possibility:

matchList f xs ys = and $ zipWith f xs ys
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2  
This might cause surprising behaviour if the lists have different lengths. and $ zipWith (==) [1] [1,2] evaluates to True. –  duplode Nov 5 '13 at 17:18
    
That's what I thought too. I don't want it to be True. So I guess I need to keep looking. –  Aleksey Bykov Nov 5 '13 at 17:21

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