In Wikibooks' Haskell, there is the following claim:

Data.List offers a sort function for sorting lists. It does not use quicksort; rather, it uses an efficient implementation of an algorithm called mergesort.

What is the underlying reason in Haskell to use mergesort over quicksort? Quicksort usually has better practical performance, but maybe not in this case. I gather that the in-place benefits of quicksort are hard (impossible?) to do with Haskell lists.

There was a related question on softwareengineering.SE, but it wasn't really about why mergesort is used.

I implemented the two sorts myself for profiling. Mergesort was superior (around twice as fast for a list of 2^20 elements), but I'm not sure that my implementation of quicksort was optimal.

Edit: Here are my implementations of mergesort and quicksort:

mergesort :: Ord a => [a] -> [a]
mergesort [] = []
mergesort [x] = [x]
mergesort l = merge (mergesort left) (mergesort right)
    where size = div (length l) 2
          (left, right) = splitAt size l

merge :: Ord a => [a] -> [a] -> [a]
merge ls [] = ls
merge [] vs = vs
merge first@(l:ls) second@(v:vs)
    | l < v = l : merge ls second
    | otherwise = v : merge first vs

quicksort :: Ord a => [a] -> [a]
quicksort [] = []
quicksort [x] = [x]
quicksort l = quicksort less ++ pivot:(quicksort greater)
    where pivotIndex = div (length l) 2
          pivot = l !! pivotIndex
          [less, greater] = foldl addElem [[], []] $ enumerate l
          addElem [less, greater] (index, elem)
            | index == pivotIndex = [less, greater]
            | elem < pivot = [elem:less, greater]
            | otherwise = [less, elem:greater]

enumerate :: [a] -> [(Int, a)]
enumerate = zip [0..]

Edit 2 3: I was asked to provide timings for my implementations versus the sort in Data.List. Following @Will Ness' suggestions, I compiled this gist with the -O2 flag, changing the supplied sort in main each time, and executed it with +RTS -s. The sorted list was a cheaply-created, pseudorandom [Int] list with 2^20 elements. The results were as follows:

  • Data.List.sort: 0.171s
  • mergesort: 1.092s (~6x slower than Data.List.sort)
  • quicksort: 1.152s (~7x slower than Data.List.sort)
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    How did you implement quicksort on singly-linked lists? – melpomene Sep 8 '18 at 17:29
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    merge sort can be optimized by splitting the list at even/odd index, which can be done in a single pass with direct recursion, avoiding the two-pass approach above (length, splitAt). Anyway, I guess performance here drove the choice of algorithm. Quicksort is fast because it can be made in-place (with arrays). On lists, it's slower. Some people argue that it should not be called "quicksort" unless it's in-place. Perhaps you can run a few benchmarks yourself. – chi Sep 8 '18 at 17:51
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    I suggest you benchmark your quicksort against Data.List.sort. – melpomene Sep 8 '18 at 18:15
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    The sort important implementation was not switched from quicksort to mergesort without benchmarking. :) Also, a nice property of the current implementation is that it has O(n) complexity for (nearly) sorted inputs. – augustss Sep 9 '18 at 1:20
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    The Ghc's implementation of mergesort also uses an algorithm to detect sequences. Making it very efficient sorting almost sorted lists. – JohEker Sep 9 '18 at 14:41

In imperative languages, Quicksort is performed in-place by mutating an array. As you demonstrate in your code sample, you can adapt Quicksort to a pure functional language like Haskell by building singly-linked lists instead, but this is not as fast.

On the other hand, Mergesort is not an in-place algorithm: a straightforward imperative implementation copies the merged data to a different allocation. This is a better fit for Haskell, which by its nature must copy the data anyway.

Let's step back a bit: Quicksort's performance edge is "lore" -- a reputation built up decades ago on machines much different from the ones we use today. Even if you use the same language, this kind of lore needs rechecking from time to time, as the facts on the ground can change. The last benchmarking paper I read on this topic had Quicksort still on top, but its lead over Mergesort was slim, even in C/C++.

Mergesort has other advantages: it doesn't need to be tweaked to avoid Quicksort's O(n^2) worst case, and it is naturally stable. So, if you lose the narrow performance difference due to other factors, Mergesort is an obvious choice.

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    Another note: You can implement mergesort in such a way that head (sort xs) is O(n) in a lazy language. – melpomene Sep 8 '18 at 18:32
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    what do you mean by "naturally" stable? it is very easy to do the initial split wrong, like e.g. "splitting the list at even/odd index". – Will Ness Sep 8 '18 at 19:00
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    Yes, but if you do the implementation right, you can get your stability "for free". With Quicksort (and other unstable sorts like Heapsort), you must explicitly track the original index to stabilize the sort. This dings the performance enough that, if you need the stability, you might as well use Mergesort. – comingstorm Sep 8 '18 at 19:11
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    Actually, the not-in-place version of Quicksort above is (or can be made) stable, unlike the usual in-place Quicksort! I was alerted to this from following the link from K. A. Buhr's answer to the old Haskell implementation, which notes that its qsort (similar to the question's quicksort) is stable. – comingstorm Sep 8 '18 at 20:25
  • yeah, I wasn't arguing against it. the runs discovery and bottom-up merging is specifically named "natural" in the cs.tufts.edu/~nr/cs257/archive/olin-shivers/msort.ps paper, even quoting the 1982 O'Keefe implementation mentioned in the docs (which is how I found that paper). for the simple list-based quicksort (which is a deforested tree sort really), all we have to do is use < and >= (and not <= and >) in the partitioning. – Will Ness Sep 9 '18 at 1:45

I think @comingstorm's answer is pretty much on the nose, but here's some more info on the history of GHC's sort function.

In the source code for Data.OldList, you can find the implementation of sort and verify for yourself that it's a merge sort. Just below the definition in that file is the following comment:

Quicksort replaced by mergesort, 14/5/2002.

From: Ian Lynagh <igloo@earth.li>

I am curious as to why the List.sort implementation in GHC is a
quicksort algorithm rather than an algorithm that guarantees n log n
time in the worst case? I have attached a mergesort implementation along
with a few scripts to time it's performance...

So, originally a functional quicksort was used (and the function qsort is still there, but commented out). Ian's benchmarks showed that his mergesort was competitive with quicksort in the "random list" case and massively outperformed it in the case of already sorted data. Later, Ian's version was replaced by another implementation that was about twice as fast, according to additional comments in that file.

The main issue with the original qsort was that it didn't use a random pivot. Instead it pivoted on the first value in the list. This is obviously pretty bad because it implies performance will be worst case (or close) for sorted (or nearly sorted) input. Unfortunately, there are a couple of challenges in switching from "pivot on first" to an alternative (either random, or -- as in your implementation -- somewhere in "the middle"). In a functional language without side effects, managing a pseudorandom input is a bit of a problem, but let's say you solve that (maybe by building a random number generator into your sort function). You still have the problem that, when sorting an immutable linked list, locating an arbitrary pivot and then partitioning based on it will involve multiple list traversals and sublist copies.

I think the only way to realize the supposed benefits of quicksort would be to write the list out to a vector, sort it in place (and sacrifice sort stability), and write it back out to a list. I don't see that that could ever be an overall win. On the other hand, if you already have data in a vector, then an in-place quicksort would definitely be a reasonable option.


On a singly-linked list, mergesort can be done in place. What's more, naive implementations scan over half the list in order to get the start of the second sublist, but the start of the second sublist falls out as a side effect of sorting the first sublist and does not need extra scanning. The one thing quicksort has going over mergesort is cache coherency. Quicksort works with elements close to each other in memory. As soon as an element of indirection enters into it, like when you are sorting pointer arrays instead of the data itself, that advantage becomes less.

Mergesort has hard guarantees for worst-case behavior, and it's easy to do stable sorting with it.


Short answer:

Quicksort is advantageous for arrays (in-place, fast, but not worst-case optimal). Mergesort for linked lists (fast, worst-case optimal, stable, simple).

Quicksort is slow for lists, Mergesort is not in-place for arrays.


Many arguments on why Quicksort is not used in Haskell seem plausible. However, at least Quicksort is not slower than Mergesort for the random case. Based on the implementation given in Richard Bird's book, Thinking Functionally in Haskell, I made a 3-way Quicksort:

tqsort [] = []
tqsort (x:xs) = sortp xs [] [x] [] 
    sortp [] us ws vs     = tqsort us ++ ws ++ tqsort vs
    sortp (y:ys) us ws vs =
      case compare y x of 
        LT -> sortp ys (y:us) ws vs 
        GT -> sortp ys us ws (y:vs)
        _  -> sortp ys us (y:ws) vs

I benchmarked a few cases, e.g., lists of size 10^4 containing Int between 0 and 10^3 or 10^4, and so on. The result is the 3-way Quicksort or even Bird's version are better than GHC's Mergesort, something like 1.x~3.x faster than ghc's Mergesort, depending on the type of data (many repetitions? very sparse?). The following stats is generated by criterion:

benchmarking Data.List.sort/Diverse/10^5
time                 223.0 ms   (217.0 ms .. 228.8 ms)
                     1.000 R²   (1.000 R² .. 1.000 R²)
mean                 226.4 ms   (224.5 ms .. 228.3 ms)
std dev              2.591 ms   (1.824 ms .. 3.354 ms)
variance introduced by outliers: 14% (moderately inflated)

benchmarking 3-way Quicksort/Diverse/10^5
time                 91.45 ms   (86.13 ms .. 98.14 ms)
                     0.996 R²   (0.993 R² .. 0.999 R²)
mean                 96.65 ms   (94.48 ms .. 98.91 ms)
std dev              3.665 ms   (2.775 ms .. 4.554 ms)

However, there is another requirement of sort stated in Haskell 98/2010: it needs to be stable. The typical Quicksort implementation using Data.List.partition is stable, but the above one isn't.

Later addition: A stable 3-way Quicksort mentioned in the comment seems as fast as tqsort here.

  • FYI here (at the bottom of the answer) you can find a stable three-way quicksort in Haskell. ---- I assume you meant Data.List.partition in your last sentence? Also, in your 2nd sentence, in "it is not true", to what is "it" referring? I think there's a missing sentence there. (?) – Will Ness Jan 7 at 12:34
  • Right... thanks for pointing it out. I have changed my comment. – L.-T. Chen Jan 7 at 12:54
  • Regarding your stable 3-way Quicksort, I quickly benchmark the random case (10^4 Ints between 0 and 10^3). Its performance is almost as the same as tqsort above. – L.-T. Chen Jan 7 at 12:57
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    thanks, will look into it. funny, I once answered with something very similar, if I'm getting it right that is, with data List a = Nil | Append [a]. is that it? (will add a link here shortly...) here it is: Explicit Purely-Functional Data-Structure For Difference Lists. it's a bit different than I remembered: data Dlist a = List [a] | Append (Dlist a) (Dlist a). whatever it is, there's bound to be a package already written for it, huh! :) :) – Will Ness Jan 8 at 17:38
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    Huh, thanks for this! :D – L.-T. Chen Jan 8 at 17:48

I am not sure, but looking at the code i don't think Data.List.sort is Mergesort as we know it. It just makes a single pass starting with the sequences function in a beautiful triangular mutual recursive fashion with ascending and descending functions to result in a list of already ascending or descending ordered chunks in the required order. Only then it starts merging.

It's a manifestation of poetry in coding. Unlike Quicksort, its worst case (total random input) has O(nlogn) time complexity, and best case (already sorted ascending or descending) is O(n).

I don't think any other sorting algorithm can beat it.

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    I'm afraid lots of algorithms do beat it, as far as empirical runtime performance on a real machine is concerned. Not in terms of complexity, but certainly in terms of overhead. – leftaroundabout Nov 13 '18 at 20:18
  • @leftaroundabout You may be right but i wasn't language agnostic. May be I should add in Haskell only. – Redu Nov 13 '18 at 20:21

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