# Why is the minimalist, example Haskell quicksort not a "true" quicksort?

Haskell's website introduces a very attractive 5-line quicksort function, as seen below.

``````quicksort [] = []
quicksort (p:xs) = (quicksort lesser) ++ [p] ++ (quicksort greater)
where
lesser = filter (< p) xs
greater = filter (>= p) xs
``````

They also include a "True quicksort in C".

``````// To sort array a[] of size n: qsort(a,0,n-1)

void qsort(int a[], int lo, int hi)
{
int h, l, p, t;

if (lo < hi) {
l = lo;
h = hi;
p = a[hi];

do {
while ((l < h) && (a[l] <= p))
l = l+1;
while ((h > l) && (a[h] >= p))
h = h-1;
if (l < h) {
t = a[l];
a[l] = a[h];
a[h] = t;
}
} while (l < h);

a[hi] = a[l];
a[l] = p;

qsort( a, lo, l-1 );
qsort( a, l+1, hi );
}
}
``````

A link below the C version directs to a page that states 'The quicksort quoted in Introduction isn't the "real" quicksort and doesn't scale for longer lists like the c code does.'

Why is the above Haskell function not a true quicksort? How does it fail to scale for longer lists?

• You should add a link to the exact page you're talking about. Oct 10, 2011 at 19:35
• It's not in-place, thus quite slow? Good question actually!
– fuz
Oct 10, 2011 at 19:36
• @FUZxxl: Haskell lists are immutable so no operation will be in-place whilst using the default datatypes. As to it's speed - it will not necessarily be slower; GHC is an impressive piece of compiler technology and very often haskell solutions using immutable data structures are up to speed with other mutable ones in other languages. Oct 10, 2011 at 19:48
• Is it actually not qsort? Remember that qsort has `O(N^2)` runtime. Oct 10, 2011 at 19:59
• It should be noted that the above example is a introductory example of Haskell, and that quicksort is a very bad choice for sorting lists. The sort in Data.List was changed to mergesort back in 2002: hackage.haskell.org/packages/archive/base/3.0.3.1/doc/html/src/…, there you can also see the previous quick sort implementation. The current implementation is a mergesort that was made in 2009: hackage.haskell.org/packages/archive/base/4.4.0.0/doc/html/src/… . Oct 11, 2011 at 8:32

The true quicksort has two beautiful aspects:

1. Divide and conquer: break the problem into two smaller problems.
2. Partition the elements in-place.

The short Haskell example demonstrates (1), but not (2). How (2) is done may not be obvious if you don't already know the technique!

``````import qualified Data.Vector.Generic as V
import qualified Data.Vector.Generic.Mutable as M

qsort :: (V.Vector v a, Ord a) => v a -> v a
qsort = V.modify go where
go xs | M.length xs < 2 = return ()
| otherwise = do
p <- M.read xs (M.length xs `div` 2)
j <- M.unstablePartition (< p) xs
let (l, pr) = M.splitAt j xs
k <- M.unstablePartition (== p) pr
go l; go \$ M.drop k pr
``````
• The source for unstablePartition reveals that it is indeed the same in-place swapping technique (as far as I can tell). Oct 20, 2011 at 17:38
• This solution is incorrect. `unstablePartition` is very similar to `partition` for `quicksort`, but it doesn't guarantee the element at `m`th position is just `p`.
– nymk
Mar 27, 2013 at 12:34

Here is a transliteration of the "true" quicksort C code into Haskell. Brace yourself.

``````import Control.Monad
import Data.Array.IO
import Data.IORef

qsort :: IOUArray Int Int -> Int -> Int -> IO ()
qsort a lo hi = do
(h,l,p,t) <- liftM4 (,,,) z z z z

when (lo < hi) \$ do
l .= lo
h .= hi
p .=. (a!hi)

doWhile (get l .< get h) \$ do
while ((get l .< get h) .&& ((a.!l) .<= get p)) \$ do
modifyIORef l succ
while ((get h .> get l) .&& ((a.!h) .>= get p)) \$ do
modifyIORef h pred
b <- get l .< get h
when b \$ do
t .=. (a.!l)
lVal <- get l
hVal <- get h
writeArray a lVal =<< a!hVal
writeArray a hVal =<< get t

lVal <- get l
writeArray a hi =<< a!lVal
writeArray a lVal =<< get p

hi' <- fmap pred (get l)
qsort a lo hi'
lo' <- fmap succ (get l)
qsort a lo' hi
``````

That was fun, wasn't it? I actually cut out this large `let` at the beginning, as well as the `where` at the end of the function, defining all of the helpers to make the preceding code somewhat pretty.

``````  let z :: IO (IORef Int)
z = newIORef 0
(.=) = writeIORef
ref .=. action = do v <- action; ref .= v
(.!) a ref = readArray a =<< get ref
(.<) = liftM2 (<)
(.>) = liftM2 (>)
(.<=) = liftM2 (<=)
(.>=) = liftM2 (>=)
(.&&) = liftM2 (&&)
-- ...
where doWhile cond foo = do
foo
b <- cond
when b \$ doWhile cond foo
while cond foo = do
b <- cond
when b \$ foo >> while cond foo
``````

And here, a dumb test to see if it works.

``````main = do
a <- (newListArray (0,9) [10,9..1]) :: IO (IOUArray Int Int)
printArr a
putStrLn "Sorting..."
qsort a 0 9
putStrLn "Sorted."
printArr a
where printArr a = mapM_ (\x -> print =<< readArray a x) [0..9]
``````

I don't write imperative code very often in Haskell, so I'm sure there are plenty of ways to clean this code up.

So what?

You will notice that the above code is very, very long. The heart of it is about as long as the C code, though each line is often a bit more verbose. This is because C secretly does a lot of nasty things that you might take for granted. For example, `a[l] = a[h];`. This accesses the mutable variables `l` and `h`, and then accesses the mutable array `a`, and then mutates the mutable array `a`. Holy mutation, batman! In Haskell, mutation and accessing mutable variables is explicit. The "fake" qsort is attractive for various reasons, but chief among them is it does not use mutation; this self-imposed restriction makes it much easier to understand at a glance.

• That's awesome, in a kind of queasy-making way. I wonder what sort of code GHC produces from something like that? Oct 20, 2011 at 14:02
• @IanRoss: From the impure quicksort? GHC actually produces pretty decent code.
– J D
May 26, 2016 at 22:11
• "The "fake" qsort is attractive for various reasons..." I afraid its performance without in-place manipulation (as already noted) would be awful. And always taking the 1st element as pivot does not help either. Jul 8, 2019 at 11:52

In my opinion, saying that it's "not a true quicksort" overstates the case. I think it's a valid implementation of the Quicksort algorithm, just not a particularly efficient one.

• I had this argument with someone once: I looked up the actual paper which specified QuickSort, and is indeed in-place. Oct 10, 2011 at 23:30
• @ivanm hyperlinks or it didn't happen :) Oct 11, 2011 at 0:07
• I love how this paper is all imperative and even includes the trick to guarantee logarithmic space use (that many people dont know about) while the (now popular) recursive version in ALGOL is just a footnote. Guess I'll have to look for that other paper now... :) Oct 11, 2011 at 1:15
• A "valid" implementation of any algorithm should have the same asymptotic bounds, don't you think? The bastardised Haskell quicksort doesn't preserve any of the memory complexity of the original algorithm. Not even close. That's why it is over 1,000x slower than Sedgewick's genuine Quicksort in C.
– J D
May 27, 2016 at 17:34
• The canonical qsort has a quadratic complexity in specific cases while this Haskell implementation (immutability included) would be quadratic every time. Clearly very different. Jul 31, 2021 at 17:16

I think the case this argument tries to make is that the reason why quicksort is commonly used is that it's in-place and fairly cache-friendly as a result. Since you don't have those benefits with Haskell lists, its main raison d'être is gone, and you might as well use merge sort, which guarantees O(n log n), whereas with quicksort you either have to use randomization or complicated partitioning schemes to avoid O(n2) run time in the worst case.

• And Mergesort is a much more natural sorting algorithm for (immutable) liked lists, where it is freed from the need to work with auxiliary arrays. Oct 11, 2011 at 1:18

Thanks to lazy evaluation, a Haskell program doesn't (almost can't) do what it looks like it does.

Consider this program:

``````main = putStrLn (show (quicksort [8, 6, 7, 5, 3, 0, 9]))
``````

In an eager language, first `quicksort` would run, then `show`, then `putStrLn`. A function's arguments are computed before that function starts running.

In Haskell, it's the opposite. The function starts running first. The arguments are only computed when the function actually uses them. And a compound argument, like a list, is computed one piece at a time, as each piece of it is used.

So the first thing that happens in this program is that `putStrLn` starts running.

GHC's implementation of `putStrLn` works by copying the characters of the argument String into to an output buffer. But when it enters this loop, `show` has not run yet. Therefore, when it goes to copy the first character from the string, Haskell evaluates the fraction of the `show` and `quicksort` calls needed to compute that character. Then `putStrLn` moves on to the next character. So the execution of all three functions—`putStrLn`, `show`, and `quicksort`— is interleaved. `quicksort` executes incrementally, leaving a graph of unevaluated thunks as it goes to remember where it left off.

Now this is wildly different from what you might expect if you're familiar with, you know, any other programming language ever. It's not easy to visualize how `quicksort` actually behaves in Haskell in terms of memory accesses or even the order of comparisons. If you could only observe the behavior, and not the source code, you would not recognize what it's doing as a quicksort.

For example, the C version of quicksort partitions all the data before the first recursive call. In the Haskell version, the first element of the result will be computed (and could even appear on your screen) before the first partition is finished running—indeed before any work at all is done on `greater`.

P.S. The Haskell code would be more quicksort-like if it did the same number of comparisons as quicksort; the code as written does twice as many comparisons because `lesser` and `greater` are specified to be computed independently, doing two linear scans through the list. Of course it's possible in principle for the compiler to be smart enough to eliminate the extra comparisons; or the code could be changed to use `Data.List.partition`.

P.P.S. The classic example of Haskell algorithms turning out not to behave how you expected is the sieve of Eratosthenes for computing primes.

• lpaste.net/108190. -- it's doing the "deforested tree sort", there's an old reddit thread about it. cf. stackoverflow.com/questions/14786904/… and related. Jul 26, 2014 at 16:46
• looks Yes, that's a pretty good characterization of what the program actually does. Jul 28, 2014 at 15:56
• re the sieve remark, were it written as an equivalent `primes = unfoldr (\(p:xs)-> Just (p, filter ((> 0).(`rem` p)) xs)) [2..]`, its most immediate problem would be perhaps clearer. And that's before we consider switching to the true sieve algorithm. Jul 31, 2014 at 11:36
• I'm confused by your definition of what code "looks like it does". Your code "looks" to me like it calls `putStrLn` which a thunked application of `show` to a thunked application of `quicksort` to a list literal --- and that's exactly what it does! (before optimization --- but compare C code to the optimized assembler sometime!). Maybe you mean "thanks to lazy evaluation, a Haskell program doesn't do what similar-looking code does in other languages"? Dec 15, 2014 at 17:13
• @jcast I do think there's a practical difference between C and Haskell in this regard. It's really hard to carry on a pleasant debate about this kind of subject in a comment thread, as much as I'd love to have it out over coffee in real life. Let me know if you're ever in Nashville with an hour to spare! Dec 20, 2014 at 14:50

I believe that the reason most people say that the pretty Haskell Quicksort isn't a "true" Quicksort is the fact that it isn't in-place - clearly, it can't be when using immutable datatypes. But there is also the objection that it isn't "quick": partly because of the expensive ++, and also because there is a space leak - you hang on to the input list while doing the recursive call on the lesser elements, and in some cases - eg when the list is decreasing - this results in quadratic space usage. (You might say that making it run in linear space is the closest you can get to "in-place" using immutable data.) There are neat solutions to both problems, using accumulating parameters, tupling, and fusion; see S7.6.1 of Richard Bird's Introduction to Functional Programming Using Haskell.

It isn't the idea of mutating elements in-place in purely functional settings. The alternative methods in this thread with mutable arrays lost the spirit of purity.

There are at least two steps to optimize the basic version (which is the most expressive version) of quick-sort.

1. Optimize the concatenation (++), which is a linear operation, by accumulators:

``````qsort xs = qsort' xs []

qsort' [] r = r
qsort' [x] r = x:r
qsort' (x:xs) r = qpart xs [] [] r where
qpart [] as bs r = qsort' as (x:qsort' bs r)
qpart (x':xs') as bs r | x' <= x = qpart xs' (x':as) bs r
| x' >  x = qpart xs' as (x':bs) r
``````
2. Optimize to ternary quick sort (3-way partition, mentioned by Bentley and Sedgewick), to handle duplicated elements:

``````tsort :: (Ord a) => [a] -> [a]
tsort [] = []
tsort (x:xs) = tsort [a | a<-xs, a<x] ++ x:[b | b<-xs, b==x] ++ tsort [c | c<-xs, c>x]
``````
3. Combine 2 and 3, refer to Richard Bird's book:

``````psort xs = concat \$ pass xs []

pass [] xss = xss
pass (x:xs) xss = step xs [] [x] [] xss where
step [] as bs cs xss = pass as (bs:pass cs xss)
step (x':xs') as bs cs xss | x' <  x = step xs' (x':as) bs cs xss
| x' == x = step xs' as (x':bs) cs xss
| x' >  x = step xs' as bs (x':cs) xss
``````

Or alternatively if the duplicated elements are not the majority:

``````    tqsort xs = tqsort' xs []

tqsort' []     r = r
tqsort' (x:xs) r = qpart xs [] [x] [] r where
qpart [] as bs cs r = tqsort' as (bs ++ tqsort' cs r)
qpart (x':xs') as bs cs r | x' <  x = qpart xs' (x':as) bs cs r
| x' == x = qpart xs' as (x':bs) cs r
| x' >  x = qpart xs' as bs (x':cs) r
``````

Unfortunately, median-of-three can't be implemented with the same effect, for example:

``````    qsort [] = []
qsort [x] = [x]
qsort [x, y] = [min x y, max x y]
qsort (x:y:z:rest) = qsort (filter (< m) (s:rest)) ++ [m] ++ qsort (filter (>= m) (l:rest)) where
xs = [x, y, z]
[s, m, l] = [minimum xs, median xs, maximum xs]
``````

because it still performs poorly for the following 4 cases:

1. [1, 2, 3, 4, ...., n]

2. [n, n-1, n-2, ..., 1]

3. [m-1, m-2, ...3, 2, 1, m+1, m+2, ..., n]

4. [n, 1, n-1, 2, ... ]

All these 4 cases are well handled by imperative median-of-three approach.

Actually, the most suitable sort algorithm for a purely functional setting is still merge-sort, but not quick-sort.

• There's another optimization you missed: use partition instead of 2 filters to produce the sub-lists (or foldr on a similar inner function to produce 3 sub-lists). Dec 26, 2014 at 5:52

There is no clear definition of what is and what isn't a true quicksort.

They are calling it not a true quicksort, because it doesn't sort in-place:

True quicksort in C sorts in-place

• well, it's a `O` we are talking about. Dec 14, 2021 at 1:24

It looks like the Haskell version would keep allocating more space for each sub list it divides. So it might run out of memory at scale. Having said that it’s much more elegant. I suppose that’s the trade off you make when you choose functional vs imperative programming.

Because taking the first element from the list results in very bad runtime. Use median of 3: first, middle, last.

• Taking the first element is ok if the list is random. Oct 10, 2011 at 19:54
• But sorting a sorted or nearly sorted list is common. Oct 10, 2011 at 19:58
• qsort is average n log n, worst n^2. Oct 10, 2011 at 20:13
• Technically, it's not any worse than picking a random value unless the input is already sorted or nearly sorted. Bad pivots are the pivots that are away from the median; the first element is only a bad pivot if it is near the minimum or maximum. Oct 10, 2011 at 20:19
• The choice of the pivot is a small detail, the underlying cause is the fact it's not in-place. Jan 15, 2013 at 13:20

Ask anybody to write quicksort in Haskell, and you will get essentially the same program--it is obviously quicksort. Here are some advantages and disadvantages:

Pro: It improves on "true" quicksort by being stable, i.e. it preserves sequence order among equal elements.

Pro: It is trivial to generalize to a three-way split (< = >), which avoids quadratic behavior due to some value occurring O(n) times.

Pro: It's easier to read--even if one had to include the definition of filter.

Con: It uses more memory.

Con: It is costly to generalize the pivot choice by further sampling, which could avoid quadratic behavior on certain low-entropy orderings.