16

I'm looking for a function in haskell to zip two lists that may vary in length.
All zip functions I could find just drop all values of a lists that is longer than the other.

For example: In my exercise I have two example lists.
If the first one is shorter than the second one I have to fill up using 0's. Otherwise I have to use 1's.
I'm not allowed to use any recursion. I just have to use higher order functions.

Is there any function I can use?
I really could not find any solution so far.

4

10 Answers 10

43

There is some structure to this problem, and here it comes. I'll be using this stuff:

import Control.Applicative
import Data.Traversable
import Data.List

First up, lists-with-padding are a useful concept, so let's have a type for them.

data Padme m = (:-) {padded :: [m], padder :: m} deriving (Show, Eq)

Next, I remember that the truncating-zip operation gives rise to an Applicative instance, in the library as newtype ZipList (a popular example of a non-Monad). The Applicative ZipList amounts to a decoration of the monoid given by infinity and minimum. Padme has a similar structure, except that its underlying monoid is positive numbers (with infinity), using one and maximum.

instance Applicative Padme where
  pure = ([] :-)
  (fs :- f) <*> (ss :- s) = zapp fs ss :- f s where
    zapp  []        ss        = map f ss
    zapp  fs        []        = map ($ s) fs
    zapp  (f : fs)  (s : ss)  = f s : zapp fs ss

I am obliged to utter the usual incantation to generate a default Functor instance.

instance Functor Padme where fmap = (<*>) . pure

Thus equipped, we can pad away! For example, the function which takes a ragged list of strings and pads them with spaces becomes a one liner.

deggar :: [String] -> [String]
deggar = transpose . padded . traverse (:- ' ')

See?

*Padme> deggar ["om", "mane", "padme", "hum"]
["om   ","mane ","padme","hum  "]
2
  • This data structure feels wrong to me. The padding value should be at the end of the list, where it's used, not side-by-side with the head. Something like data Listttt a = Repeat a | Cons a (Listttt a).
    – benrg
    Feb 7, 2022 at 1:56
  • @benrg Arranging it like that would impose a linear cost in accessing the padder, in case you ever need to use it for something else.
    – duplode
    Jun 11, 2023 at 15:08
11

This can be expressed using These ("represents values with two non-exclusive possibilities") and Align ("functors supporting a zip operation that takes the union of non-uniform shapes") from the these library:

import Data.Align
import Data.These

zipWithDefault :: Align f => a -> b -> f a -> f b -> f (a, b)
zipWithDefault da db = alignWith (fromThese da db)

salign and the other specialised aligns in Data.Align are also worth having a look at.

Thanks to u/WarDaft, u/gallais and u/sjakobi over at r/haskell for pointing out this answer should exist here.

7

You can append an inifinte list of 0 or 1 to each list and then take the number you need from the result zipped list:

zipWithDefault :: a -> b -> [a] -> [b] -> [(a,b)]
zipWithDefault da db la lb = let len = max (length la) (length lb)
                                 la' = la ++ (repeat da)
                                 lb' = lb ++ (repeat db)
                             in take len $ zip la' lb'  
1
  • @Lee: Sorry, my bad, it does. It breaks on infinite lists though (even if one is infinite), but that's already been mentioned. My answer below works with infinite and finite lists.
    – Clinton
    Jan 25, 2014 at 12:29
7

This should do the trick:

import Data.Maybe (fromMaybe)

myZip dx dy xl yl = 
  map (\(x,y) -> (fromMaybe dx x, fromMaybe dy y)) $ 
    takeWhile (/= (Nothing, Nothing)) $ 
    zip ((map Just xl) ++ (repeat Nothing)) ((map Just yl) ++ (repeat Nothing))

main = print $ myZip 0 1 [1..10] [42,43,44]

Basically, append an infinite list of Nothing to the end of both lists, then zip them, and drop the results when both are Nothing. Then replace the Nothings with the appropriate default value, dropping the no longer needed Justs while you're at it.

4

No length, no counting, no hand-crafted recursions, no cooperating folds. transpose does the trick:

zipLongest :: a -> b -> [a] -> [b] -> [(a,b)]
zipLongest x y xs ys = map head . transpose $   -- longest length;
                [                                 --   view from above:
                  zip  xs 
                      (ys ++ repeat y)            -- with length of xs
                , zip (xs ++ repeat x) 
                       ys                         -- with length of ys
                ]

The result of transpose is as long a list as the longest one in its input list of lists. map head takes the first element in each "column", which is the pair we need, whichever the longest list was.


(update:) For an arbitrary number of lists, efficient padding to the maximal length -- aiming to avoid the potentially quadratic behaviour of other sequentially-combining approaches -- can follow the same idea:

padAll :: a -> [[a]] -> [[a]]
padAll x xss = transpose $ 
   zipWith const
      (transpose [xs ++ repeat x | xs <- xss])         -- pad all, and cut
      (takeWhile id . map or . transpose $             --   to the longest list
         [ (True <$ xs) ++ repeat False | xs <- xss])

> mapM_ print $ padAll '-' ["ommmmmmm", "ommmmmm", "ommmmm", "ommmm", "ommm",
   "omm", "om", "o"]
"ommmmmmm"
"ommmmmm-"
"ommmmm--"
"ommmm---"
"ommm----"
"omm-----"
"om------"
"o-------"
3

You don't have to compare list lengths. Try to think about your zip function as a function taking only one argument xs and returning a function which will take ys and perform the required zip. Then, try to write a recursive function which recurses on xs only, as follows.

type Result = [Int] -> [(Int,Int)]
myZip :: [Int] -> Result
myZip []     = map (\y -> (0,y)) -- :: Result
myZip (x:xs) = f x (myZip xs)    -- :: Result
   where f x k = ???             -- :: Result

Once you have found f, notice that you can turn the recursion above into a fold!

2

As you said yourself, the standard zip :: [a] -> [b] -> [(a, b)] drops elements from the longer list. To amend for this fact you can modify your input before giving it to zip. First you will have to find out which list is the shorter one (most likely, using length). E.g.,

zip' x xs y ys | length xs <= length ys  =  ...
               | otherwise               =  ...

where x is the default value for shorter xs and y the default value for shorter ys.

Then you extend the shorter list with the desired default elements (enough to account for the additional elements of the other list). A neat trick for doing so without having to know the length of the longer list is to use the function repeat :: a -> [a] that repeats its argument infinitely often.

zip' x xs y ys | length xs <= length ys = zip {-do something with xs-} ys
               | otherwise              = zip xs {-do something with ys-}
3
  • @augustss: Right. I should have mentioned it in my post.
    – chris
    Jan 25, 2014 at 13:01
  • Also quite inefficient.
    – dfeuer
    Mar 3, 2019 at 17:34
  • if memory serves, the augustss's deleted comment was "doesn't work with infinite lists". length is the culprit.
    – Will Ness
    Dec 7, 2019 at 20:51
2

Here is another solution, that does work on infinite lists and is a straightforward upgrade of Prelude's zip functions:

zipDefault :: a ->  b -> [a] -> [b] -> [(a,b)]
zipDefault _da _db []     []     = []
zipDefault  da  db (a:as) []     = (a,db) : zipDefault da db as []
zipDefault  da  db []     (b:bs) = (da,b) : zipDefault da db [] bs
zipDefault  da  db (a:as) (b:bs) = (a,b)  : zipDefault da db as bs

and

zipDefaultWith :: a -> b -> (a->b->c) -> [a] -> [b] -> [c]
zipDefaultWith _da _db _f []     []     = []
zipDefaultWith  da  db  f (a:as) []     = f  a db : zipDefaultWith da db f as []
zipDefaultWith  da  db  f []     (b:bs) = f da  b : zipDefaultWith da db f [] bs
zipDefaultWith  da  db  f (a:as) (b:bs) = f  a  b : zipDefaultWith da db f as bs

@pigworker, thank you for your enlightening solution!

2

Yet another implementation:

zipWithDefault :: a -> b -> (a -> b -> c) -> [a] -> [b] -> [c]
zipWithDefault dx _  f []     ys     = zipWith f (repeat dx) ys
zipWithDefault _  dy f xs     []     = zipWith f xs (repeat dy)
zipWithDefault dx dy f (x:xs) (y:ys) = f x y : zipWithDefault dx dy f xs ys

And also:

zipDefault :: a -> b -> [a] -> [b] -> [c]
zipDefault dx dy = zipWithDefault dx dy (,)
0

I would like to address the second part of Will Ness's solution, with its excellent use of known functions, by providing another to the original question.

zipPadWith :: a -> b -> (a -> b -> c) -> [a] -> [b] -> [c]
zipPadWith n _ f [] l          = [f n x | x <- l]
zipPadWith _ m f l []          = [f x m | x <- l]
zipPadWith n m f (x:xs) (y:ys) = f x y : zipPadWith n m f xs ys

This function will pad a list with an element of choice. You can use a list of the same element repeated as many times as the number of lists in another like this:

rectangularWith :: a -> [[a]] -> [[a]]
rectangularWith _ []       = []
rectangularWith _ [ms]     = [[m] | m <- ms]
rectangularWith n (ms:mss) = zipPadWith n [n | _ <- mss] (:) ms (rectangularWith n mss)

The end result will have been a transposed rectangular list of lists padded by the element that we provided so we only need to import transpose from Data.List and recover the order of the elements.

mapM_ print $ transpose $ rectangularWith 0 [[1,2,3,4],[5,6],[7,8],[9]]

[1,2,3,4]
[5,6,0,0]
[7,8,0,0]
[9,0,0,0]

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