In this question, the author brings up an interesting programming question: given two string, find possible 'interleaved' permutations of those that preserves order of original strings.

I generalized the problem to n strings instead of 2 in OP's case, and came up with:

-- charCandidate is a function that finds possible character from given strings.
-- input : list of strings
-- output : a list of tuple, whose first value holds a character 
-- and second value holds the rest of strings with that character removed
-- i.e ["ab", "cd"] -> [('a', ["b", "cd"])] ..

charCandidate xs = charCandidate' xs []
charCandidate' :: [String] -> [String] -> [(Char, [String])]
charCandidate' [] _ = []     
charCandidate' ([]:xs) prev = 
    charCandidate' xs prev
charCandidate' (x@(c:rest):xs) prev =
    (c, prev ++ [rest] ++ xs) : charCandidate' xs (x:prev)

interleavings :: [String] -> [String]
interleavings xs = interleavings' xs []    

-- interleavings is a function that repeatedly applies 'charCandidate' function, to consume
-- the tuple and build permutations.
-- stops looping if there is no more tuple from charCandidate.

interleavings' :: [String] -> String -> [String]
interleavings' xs prev = 
    let candidates = charCandidate xs
        in case candidates of
            [] -> [prev]
            _  -> concat . map (\(char, ys) -> interleavings' ys (prev ++ [char])) $ candidates

-- test case
input :: [String]
input = ["ab", "cd"]    
-- interleavings input == ["abcd","acbd","acdb","cabd","cadb","cdab"]

it works, however I'm quite concerned with the code:

  1. it is ugly. no point-free!
  2. explicit recursion and additional function argument prev to preserve states
  3. using tuples as intermediate form

How can I rewrite the above program to be more "haskellic", concise, readable and more conforming to "functional programming"?

  • 4
    I wouldn't recommend pursuing point-free style too far. It may be educational and even fun, but if taken beyond a certain point, point-free programming can make things less readable, not more... – comingstorm Mar 31 '16 at 20:29
  • 2
    Also, please avoid the likes of (:) (...) $ ... in favor of (...):(...). In the above case, you don't even need the second set of parens... – comingstorm Mar 31 '16 at 20:48
  • I haven't tested, but I suspect you meant to write charCandidate' everywhere you currently have getCandidate, and meant to write charCandidate' everywhere you currently have charCandidate in the five lines following the type declaration for charCandidate'. – Daniel Wagner Mar 31 '16 at 20:59
  • @DanielWagner sorry, I've changed some names while copypasting from my editor and it seems I forgot to make my edit match with name-changes. – thkang Mar 31 '16 at 21:06

I think I would write it this way. The main idea is to treat creating an interleaving as a nondeterministic process which chooses one of the input strings to start the interleaving and recurses.

Before we start, it will help to have a utility function that I have used countless times. It gives a convenient way to choose an element from a list and know which element it was. This is a bit like your charCandidate', except that it operates on a single list at a time (and is consequently more widely applicable).

zippers :: [a] -> [([a], a, [a])]
zippers = go [] where
    go xs [] = []
    go xs (y:ys) = (xs, y, ys) : go (y:xs) ys

With that in hand, it is easy to make some non-deterministic choices using the list monad. Notionally, our interleavings function should probably have a type like [NonEmpty a] -> [[a]] which promises that each incoming string has at least one character in it, but the syntactic overhead of NonEmpty is too annoying for a simple exercise like this, so we'll just give wrong answers when this precondition is violated. You could also consider making this a helper function and filtering out empty lists from your top-level function before running this.

interleavings :: [[a]] -> [[a]]
interleavings [] = [[]]
interleavings xss = do
    (xssL, h:xs, xssR) <- zippers xss
    t <- interleavings ([xs | not (null xs)] ++ xssL ++ xssR)
    return (h:t)

You can see it go in ghci:

> interleavings ["abc", "123"]
> interleavings ["a", "b", "c"]
> permutations "abc" -- just for fun, to compare
  • what is [xs | hay xs] ? – thkang Mar 31 '16 at 20:40
  • @thkang Ah, right, so: [e1 | e2] is a list that contains element e1 if e2 evaluates to True and an empty list if e2 evaluates to False. So it's shorthand for if hay xs then [xs] else []. Cute, no? Anyway the purpose is to maintain the invariant that we pass only non-empty lists to interleavings. – Daniel Wagner Mar 31 '16 at 20:44
  • thanks, that was the only part I couldn't understand - I've read about zippers but it's nice to see a real application here (I'm quite new to haskell). – thkang Mar 31 '16 at 20:50
  • For posterity: thkang's earlier question mentions [xs | hay xs]. This is because originally I had defined hay = not . null; but I decided it wasn't worth splitting out into its own function and inlined it, so the new spelling is [xs | not (null xs)]. – Daniel Wagner Mar 31 '16 at 20:54
  • I've come up with an implementation that seems to be much faster when dealing with long lists. Could you possibly take a look and see if you have any suggestions (especially for making it prettier)? – dfeuer Apr 3 '16 at 1:49

This is fastest implementation I've come up with so far. It interleaves a list of lists pairwise.

interleavings :: [[a]] -> [[a]]
interleavings = foldr (concatMap . interleave2) [[]]

This horribly ugly mess is the best way I could find to interleave two lists. It's intended to be asymptotically optimal (which I believe it is); it's not very pretty. The constant factors could be improved by using a special-purpose queue (such as the one used in Data.List to implement inits) rather than sequences, but I don't feel like including that much boilerplate.

{-# LANGUAGE BangPatterns #-}
import Data.Monoid
import Data.Foldable (toList)
import Data.Sequence (Seq, (|>))

interleave2 :: [a] -> [a] -> [[a]]
interleave2 xs ys = interleave2' mempty xs ys []

interleave2' :: Seq a -> [a] -> [a] -> [[a]] -> [[a]]
interleave2' !prefix xs ys rest =
  (toList prefix ++ xs ++ ys)
     : interleave2'' prefix xs ys rest

interleave2'' :: Seq a -> [a] -> [a] -> [[a]] -> [[a]]
interleave2'' !prefix [] _ = id
interleave2'' !prefix _ [] = id
interleave2'' !prefix xs@(x : xs') ys@(y : ys') =
  interleave2' (prefix |> y) xs ys' .
      interleave2'' (prefix |> x) xs' ys

Using foldr over interleave2

interleave :: [[a]] -> [[a]]
interleave = foldr ((concat .) . map . iL2) [[]]  where 
   iL2 [] ys = [ys]
   iL2 xs [] = [xs]
   iL2 (x:xs) (y:ys) = map (x:) (iL2 xs (y:ys)) ++ map (y:) (iL2 (x:xs) ys)

Another approach would be to use the list monad:

interleavings xs ys = interl xs ys ++ interl ys xs where
  interl [] ys = [ys]
  interl xs [] = [xs]
  interl xs ys = do
    i <- [1..(length xs)]
    let (h, t)  = splitAt i xs
    map (h ++) (interl ys t)

So the recursive part will alternate between the two lists, taking all from 1 to N elements from each list in turns and then produce all possible combinations of that. Fun use of the list monad.

Edit: Fixed bug causing duplicates

Edit: Answer to dfeuer. It turned out tricky to do code in the comment field. An example of solutions that do not use length could look something like:

interleavings xs ys = interl xs ys ++ interl ys xs where 
  interl [] ys = [ys]
  interl xs [] = [xs]
  interl xs ys = splits xs >>= \(h, t) -> map (h ++) (interl ys t)

splits [] = []
splits (x:xs) = ([x], xs) : map ((h, t) -> (x:h, t)) (splits xs)

The splits function feels a bit awkward. It could be replaced by use of takeWhile or break in combination with splitAt, but that solution ended up a bit awkward as well. Do you have any suggestions?

(I got rid of the do notation just to make it slightly shorter)

  • Can you see a way to avoid length? It's not really needed here. – dfeuer Apr 1 '16 at 12:12
  • You could lazily produce all possible ways to split the list and then draw elements from that. I tried one version but it did not make it more readable, and I am not sure it would be faster either. – dvaergiller Apr 1 '16 at 12:57
  • Just realised that this solution is very similar to that of Daniel Wagner – dvaergiller Apr 1 '16 at 13:21
  • Another option (better, I think) is to recognize that interleaving can be done pairwise. – dfeuer Apr 1 '16 at 19:27
  • Hm. Please elaborate – dvaergiller Apr 2 '16 at 20:23

Combining the best ideas from the existing answers and adding some of my own:

import Control.Monad

interleave [] ys = return ys
interleave xs [] = return xs
interleave (x : xs) (y : ys) =
  fmap (x :) (interleave xs (y : ys)) `mplus` fmap (y :) (interleave (x : xs) ys)

interleavings :: MonadPlus m => [[a]] -> m [a]
interleavings = foldM interleave []

This is not the fastest possible you can get, but it should be good in terms of general and simple.

  • It's pretty, and it was my original answer, but it has some performance problems. Left-nested ++ and lots of repeated map applications will make this slow. – dfeuer Apr 3 '16 at 5:48
  • Indeed. Such inefficiencies are dwarfed by the output size though so they are unlikely to matter much. – Rotsor Apr 3 '16 at 6:01
  • Edited the answer slightly so that interleavings works for any MonadPlus now. This means you can make it faster just by using a different monad! – Rotsor Apr 3 '16 at 6:21
  • Better, but the nested maps are still an issue, and you have to get to the end of the first list before you produce anything at all. I like your mplus idea, but I don't think it's sufficient. – dfeuer Apr 3 '16 at 11:46

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