# Merging two lists in Haskell

Can't figure out how to merge two lists in the following way in Haskell:

``````INPUT:  [1,2,3,4,5] [11,12,13,14]

OUTPUT: [1,11,2,12,3,13,4,14,5]
``````
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Usually you learn more if you explain what you tried and why it didn't work, that way people can do some filling-in-the-gaps instead of just giving you a chunk of code. –  Thomas M. DuBuisson Oct 14 '10 at 23:56

``````merge :: [a] -> [a] -> [a]
merge xs     []     = xs
merge []     ys     = ys
merge (x:xs) (y:ys) = x : y : merge xs ys
``````
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I am new to functional programming, and the code gets me wonder this: Does the tail call optimization apply in that form of recursion too? –  Le Curious Jul 21 '13 at 11:01
No, it doesn't. The tail call is (:), and it needs no optimization. –  Ingo Jul 21 '13 at 12:09

Another possibility:

``````merge xs ys = concatMap (\(x,y) -> [x,y]) (zip xs ys)
``````

Or, if you like Applicative:

``````merge xs ys = concat \$ getZipList \$ (\x y -> [x,y]) <\$> ZipList xs <*> ZipList ys
``````
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Yea, to bad, that only works on equal-length lists. –  Jevgeni Bogatyrjov Oct 15 '10 at 16:55

So why do you think that simple (concat . transpose) "is not pretty enough"? I assume you've tried something like:

``````merge :: [[a]] -> [a]
merge = concat . transpose

merge2 :: [a] -> [a] -> [a]
merge2 l r = merge [l,r]
``````

Thus you can avoid explicit recursion (vs the first answer) and still it's simpler than the second answer. So what are the drawbacks?

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Ah, I forgot about transpose, and missed the comment. Very nice, +1 (But I wouldn't necessarily say that it's much easier than my first solution.) –  danlei Oct 15 '10 at 13:53
Agree. Your solution is probably even more straightforward.. The real problem with it though is that it isn't 100% correct: for the lists of different lengths (like in the sample input from the question) it doesn't work as expected (tailing '5' is missing). –  Ed'ka Oct 15 '10 at 14:03
Good catch! I overlooked the 5 in the sample output. I'll update my answer with a pointer to your answer and comments. Thanks! –  danlei Oct 15 '10 at 15:50
Looks like both are O(n) although explicit recursion is more than 2 times faster and space efficient against Data.List implementation (which is expected - the latter generates lots of intermediate lists) with "ghc -O2". However I suspect the difference would be less obvious should, say, 'stream-fusion' implementation of "transpose" and "concat" be used. –  Ed'ka Oct 15 '10 at 18:16
The main drawback is that the average person looking at it will have to stare at it and think for a while to understand why it works, whereas the other solutions are immediately obvious. Your solution is very elegant though. –  Yitz Oct 21 '10 at 17:48

I want to propose a lazier version of merge:

``````merge [] ys = ys
merge (x:xs) ys = x:merge ys xs
``````

For one example use case you can check a recent SO question about lazy generation of combinations.
The version in the accepted answer is unnecessarily strict in the second argument and that's what is improved here.

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Well, that puts all of the elements of ys at the end, so it doesn't work. But I think what you meant was to reverse the order of the first two equations in andri's solution. –  Yitz Oct 21 '10 at 17:44
No, it does the same thing - alternates between each list. Notice that `xs` and `ys` are swapped in the recursive call. –  Daniel Velkov Oct 21 '10 at 18:25
It's a great solution! I wish I could think of something like that myself –  Jevgeni Bogatyrjov Oct 21 '10 at 23:01
+1 very nice! this is exactly what `mplus/i`, the "interleaving mplus" is doing, from the book The Reasoned Schemer btw. –  Will Ness Jul 14 '12 at 8:39
@Shitikanth did you look at the link from my answer? That's an example where you need the extra laziness of this version of merge. Your merge is lazy too but it forces the second argument unnecessarily through pattern matching. –  Daniel Velkov Jul 30 '13 at 21:43
``````-- ++
pp [] [] = []
pp [] (h:t) = h:pp [] t
pp (h:t) [] = h:pp t []
pp (h:t) (a:b) = h : pp t (a:b)
``````
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This solution is incorrect. The final line should be `pp (h:t) (a:b) = h : a : pp t b`. –  bisserlis Oct 20 '12 at 0:41

Surely a case for an unfold:

``````interleave :: [a] -> [a] -> [a]
interleave = curry \$ unfoldr g
where
g ([],  _)   = Nothing
g (x:xs, ys) = Just (x, (ys, xs))
``````
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