I have a list, I want to break the list into two, one with elements in the even indexes, and the other from the odd indexes.

breakByIndexes :: [a] -> ([a], [a])

For example:

> breakByIndexes ["A", "B", "C", "D"]
(["A", "C"], ["B", "D"]

> breakByIndexes ["A", "B", "C", "D", "E"]
(["A", "C", "E"], ["B", "D"]

I got a solution like this

breakByIndexes [] = ([], [])
breakByIndexes [e] = ([e], [])
breakByIndexes (e:o:xs) =
  let (es, os) = breakByIndexes xs
   in (e : es, o : os)

But I'm curious is it possible to implement without using recursion? And is it possible to implement by composing existing functions from Data.List?


Yes you are right, using the partition function from Data.List.

Prelude Data.List> (s, u) = partition (even . fst) (zip [0 .. ] "ABCD")
Prelude Data.List> (_, s2) = unzip s
Prelude Data.List> (_, u2) = unzip u
Prelude Data.List> (s2, u2)

How I found this? Go to Hoogle and fill in [a] -> ([a], [a]).


My favourite version of this function uses foldr

pairs = foldr (\x ~(ys,zs) -> (x:zs,ys)) ([],[])

It works by swapping the tuple around on each item in the list. Inside the closure:

\x ~(odds,evens) -> (x:evens, odds)

You add on the x, which means that all of the rest of the elements in the evens list now become the odd-numbered elements.

What's the ~ for? It makes the pattern-match lazy. Without it, you'll force the tuple. So, for instance, if I wrote:

(head . fst . pairs) [1..]

It would not work without the ~. You could achieve the same effect by writing:

pairs = foldr (\x yszs -> (x:snd yszs,fst yszs)) ([],[])


pairs = foldr (\x -> uncurry (\ys zs -> (x:zs,ys))) ([],[])
  • 1
    wow, cool. can you explain how it works? looks very magically. what does ~ do?
    – Leo Zhang
    Apr 10 '18 at 4:49
  • @zhangchiqing You could try running it by hand on a small example to see what happens. The key thing here is that in the pattern (ys, zs) and the return value (x:zs, ys) the lists ys and zs have switched places. Which means that if ys gets the current value then zs will get the next, then ys again, etc., etc.
    – gallais
    Apr 10 '18 at 9:24
  • Thinking a bit. I actually like your solution better now. Because this solution can be extended to break a list into 3-tuples, or more. like this take 10 $ fst3 $ foldr (\x xs -> (x:trd3 xs, fst3 xs, snd3 xs)) ([], [], []) [1..] whereas, the partition solution is easier to understand, it can only work for breaking into a pair of two lists
    – Leo Zhang
    Apr 11 '18 at 0:16

Here is another way. Unlike the others answers at the time of posting, it naturally generalizes to other moduli than 2.

Data.List Data.List.Split> transpose . chunksOf 2 $ "ABCDE"
  • Thanks Daniel! Your solution is very elegant, just that it requires additional module other than Data.List
    – Leo Zhang
    Apr 10 '18 at 0:31
  • 2
    @zhangchiqing Yep. Of course chunksOf can be implemented with just Data.List functions, but I think code reuse is nice, so I recommend getting familiar with the libraries available. Apr 10 '18 at 0:32
  • "it naturally generalizes to other moduli than 2" because you don't produce a tuple: [[x | (x,i)<-zip xs [0..], i `mod` n == j] | j<-[0..n-1]].
    – jferard
    Apr 10 '18 at 18:44
  • 1
    @jferard Yup, not producing a tuple is a key trick for using this technique. But the technique brings other benefits over your proposal; e.g. it makes O(1) passes over the input list, not O(n) (where n is the modulus) like yours, and is friendlier to the GC than yours. Apr 10 '18 at 19:44
  • @DanielWagner you are right: I'm not trying to save my solution, which is probably the worst proposed here (though not so bad), but I had some difficulties to ouput a tuple instead of a list...
    – jferard
    Apr 10 '18 at 21:10

EDIT: Since @DanielWagner opened the door, if it's possible to return a list instead of a tuple, an obvious solution is:

[[x | (x,i)<-zip xs [0..], i `mod` 2 == j] | j<-[0..1]]

It may be generalized to:

[[x | (x,i)<-zip xs [0..], i `mod` k == j] | j<-[0..k-1]]

For k lists of elements [[e_0, e_k, e_2k, ...], [e_1, e_k+1, e_2k+1, ...], ..., [e_k-1, e_2k-1, e_3k-1,...]].

For tuples, I leave for the record the previous code, though it's clearly worse than the other answers.

It's easy to pick even elements with a list comprehension:

Prelude> evens xs = [x | (x,i) <- zip xs [0..], even i]
Prelude> evens ["A", "B", "C", "D", "E"]

You can do the same with odd elements. But you can also define a function that takes a filter (even or odd) and returns a function that will select elements:

Prelude> toFilter xs = \f -> [x | (x,i) <- zip xs [0..], f i]
Prelude> :t toFilter ["A", "B", "C", "D", "E"]
toFilter ["A", "B", "C", "D", "E"]
  :: (Num t, Enum t) => (t -> Bool) -> [[Char]]

toFilter xs takes a filter and returns a list:

Prelude> l = toFilter ["A", "B", "C", "D", "E"]
Prelude> l even
Prelude> l odd

It's also possible two define a function that takes a function like toFilter ((t -> Bool) -> [[Char]]) and create a tuple for even and odd filter:

Prelude> :t \tf -> (tf even, tf odd)
\tf -> (tf even, tf odd) :: Integral a => ((a -> Bool) -> t) -> (t, t)

Now, it becomes easy to put things together:

Prelude> breakByIndexes xs = (\tf -> (tf even, tf odd)) (\f -> [x | (x,i)<-zip xs [0..], f i])
Prelude> breakByIndexes ["A", "B", "C", "D"]
Prelude> breakByIndexes ["A", "B", "C", "D", "E"]

Less elegant than @elemx80s, but does the job...


Just remember that ASCII characters have a built in index offset by 65.

import Data.Char (ord)

ord 'A' - 65 = 0`

Without the offset, the numeric values are even and odd anyway. 'A' is 65, odd.

p l = [ [x|x<-l,odd (ord(head x))], [x|x<-l,even (ord(head x))] ]

I do love pairs. Once a data set is in pairs it becomes much easier to work with. I came across a function that creates the perfect pairs for this set, it leaves unpaired elements at the end but in the list. It does not create tuples but list pairs are okay, too. The function is chunksOf.

Here it is used as

i3 = chunksOf 2 $ words "A B C D E F G H I"

To produce the pairs we want. [["A","B"],["C","D"],["E","F"],["G","H"],["I"]]

Pairs are even-odd pairs. The odd one at the end is really lacking an odd member. All odd elements of the list are missing the odd member. The odd member extractor has to compensate with filter of pairs with less than two members.

[ map (head) l3,   map (last) (filter ((>1).length) l3) ]

Produces [["A","C","E","G","I"],["B","D","F","H"]] Pairs carry information, such as even or odd.

And to my shock and awe @DanielWagner points out that transpose produces the desired results with the pair list. His is transpose i3 for an incredibly even more concise solution. Wow!

Edit 4/15/2018

I do hope this is final or near final.

let ls = words "A B C D E F G"
[[a|(a,b)<-zip ls [0..],bl b]|bl<-[even,odd]]


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