# Breaking lists at index

I have a performance question today.

I am making a (Haskell) program and, when profiling, I saw that most of the time is spent in the function you can find below. Its purpose is to take the nth element of a list and return the list without it besides the element itself. My current (slow) definition is as follows:

breakOn :: Int -> [a] -> (a,[a])
breakOn 1 (x:xs) = (x,xs)
breakOn n (x:xs) = (y,x:ys)
where
(y,ys) = breakOn (n-1) xs

The Int argument is known to be in the range 1..n where n is the length of the (never null) list (x:xs), so the function never arises an error.

However, I got a poor performance here. My first guess is that I should change lists for another structure. But, before start picking different structures and testing code (which will take me lot of time) I wanted to ask here for a third person opinion. Also, I'm pretty sure that I'm not doing it in the best way. Any pointers are welcome!

Please, note that the type a may not be an instance of Eq.

## Solution

I adapted my code tu use Sequences from the Data.Sequence module. The result is here:

import qualified Data.Sequence as S

breakOn :: Int -> Seq a -> (a,Seq a)
breakOn n xs = (S.index zs 0, ys <> (S.drop 1 zs))
where
(ys,zs) = S.splitAt (n-1) xs

However, I still accept further suggestions of improvement!

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why not use the standart funktions? breakOn n l = (take n l,drop n l) –  nist Jan 3 '13 at 15:31
@nist That doesn't have the right type. mhwombat's answer below does. –  dave4420 Jan 3 '13 at 15:40
Because I need to retain the nth element and end up with all elements before and after the extracted element in a single list. –  Daniel Díaz Jan 3 '13 at 15:46
OK, thanks! I didn't know it! Done! –  Daniel Díaz Jan 3 '13 at 17:23

Yes, this is inefficient. You can do a bit better by using splitAt (which unboxes the number during the recursive bit), a lot better by using a data structure with efficient splitting, e.g. a fingertree, and best by massaging the context to avoid needing this operation. If you post a bit more context, it may be possible to give more targeted advice.

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OK, this was a huge performance improvement! I adapted my program to use Sequences everywhere. Now it performs much better. Interestingly, now it takes more time generating random numbers than splitting lists. Hurray! My remaining question is why lists are the default method?. –  Daniel Díaz Jan 3 '13 at 16:37
@DanielDíaz Because they're very simple (both, to use and to implement). And they're fast enough for many many uses. Just, indexing isn't one of those. –  Daniel Fischer Jan 3 '13 at 16:39
I really must object, there are entirely too many people named Daniel here for me to keep track of. >:[ –  C. A. McCann Jan 4 '13 at 3:53
@C.A.McCann I disagree. Daniel and Daniel are well known to you being top notch Haskell answerers, and Daniel, as OP is highlighted blue, and stands out as a cheerful, open-minded, fast learning OP. I see no cause for confusion. By the way, Daniel, if you keep learning fast you'll end up as insightful as Daniel and Daniel are. –  AndrewC Jan 4 '13 at 9:30

Prelude functions are generally pretty efficient. You could rewrite your function using splitAt, as so:

breakOn :: Int -> [a] -> (a,[a])
breakOn n xs = (z,ys++zs)
where
(ys,z:zs) = splitAt (n-1) xs
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Thanks, this version is a bit more efficient, but still slow. I'm using big lists here. I'm going to try with the Data.Sequence module as suggested by Daniel Wagner. –  Daniel Díaz Jan 3 '13 at 15:56
The problem with this version is the right appending (I think). –  Daniel Díaz Jan 3 '13 at 15:57
@DanielDíaz No, that is fine. The only problem with this version is that getting at the n-th element of a list is an O(n) operation. If that's not fast enough, you need a different data structure. Data.Sequence is a good first candidate. –  Daniel Fischer Jan 3 '13 at 16:19
@DanielFischer Yes, I'm trying to adapt the whole code to Data.Sequence to try it. Right now I'm trying to implement mapM for the Seq type. –  Daniel Díaz Jan 3 '13 at 16:25