On the other hand, it is possible to use vectors in Haskell to implement an in-place quicksort.

How much faster is the second algorithm than the first?

That depends on the implementation, of course. As can be seen below, for not too short lists, a decent in-place sort on a mutable vector or array is much faster than sorting lists, even if the time for the transformation from and to lists is included (*and that conversion makes up the bulk of the time*).

However, the list algorithms produce incremental output, while the array/vector algorithms don't produce any result before they have completed, therefore sorting lists can still be preferable.

I don't know exactly what the linked mutable array/vector algorithms did wrong. But they did something quite wrong.

For the mutable vector code, it seems that it used *boxed* vectors, and it was polymorphic, both can have significant performance impact, though the polymorphism shouldn't matter if the functions are `{-# INLINABLE #-}`

.

For the `IOUArray`

code, well, it looks fun, but slow. It uses an `IORef`

, `readArray`

and `writeArray`

and has no obvious strictness. The abysmal times it takes aren't too surprising, then.

Using a more direct translation of the (monomorphic) C code using an `STUArray`

, with a wrapper to make it work on lists¹,

```
{-# LANGUAGE BangPatterns #-}
module STUQuickSort (stuquick) where
import Data.Array.Base (unsafeRead, unsafeWrite)
import Data.Array.ST
import Control.Monad.ST
stuquick :: [Int] -> [Int]
stuquick [] = []
stuquick xs = runST (do
let !len = length xs
arr <- newListArray (0,len-1) xs
myqsort arr 0 (len-1)
-- Can't use getElems for large arrays, that overflows the stack, wth?
let pick acc i
| i < 0 = return acc
| otherwise = do
!v <- unsafeRead arr i
pick (v:acc) (i-1)
pick [] (len-1))
myqsort :: STUArray s Int Int -> Int -> Int -> ST s ()
myqsort a lo hi
| lo < hi = do
let lscan p h i
| i < h = do
v <- unsafeRead a i
if p < v then return i else lscan p h (i+1)
| otherwise = return i
rscan p l i
| l < i = do
v <- unsafeRead a i
if v < p then return i else rscan p l (i-1)
| otherwise = return i
swap i j = do
v <- unsafeRead a i
unsafeRead a j >>= unsafeWrite a i
unsafeWrite a j v
sloop p l h
| l < h = do
l1 <- lscan p h l
h1 <- rscan p l1 h
if (l1 < h1) then (swap l1 h1 >> sloop p l1 h1) else return l1
| otherwise = return l
piv <- unsafeRead a hi
i <- sloop piv lo hi
swap i hi
myqsort a lo (i-1)
myqsort a (i+1) hi
| otherwise = return ()
```

and a wrapper around a good sort (Introsort, not quicksort) on unboxed vectors,

```
module VSort where
import Data.Vector.Algorithms.Intro
import qualified Data.Vector.Unboxed as U
import Control.Monad.ST
vsort :: [Int] -> [Int]
vsort xs = runST (do
v <- U.unsafeThaw $ U.fromList xs
sort v
s <- U.unsafeFreeze v
return $ U.toList s)
```

I get times more in line with the expectations (**Note:** For these timings, the random list has been `deepseq`

ed before calling the sorting algorithm. Without that, the conversion to an `STUArray`

would be much slower, since it would first evaluate a long list of thunks to determine the length. The `fromList`

conversion of the vector package doesn't suffer from this problem. Moving the `deepseq`

to the conversion to `STUArray`

, the other sorting [and conversion, in the vector case] algorithms take a little less time, so the difference between vector-algorithms' introsort and the `STUArray`

quicksort becomes a little larger.):

```
list size: 200000 -O2 -fllvm -fllvm-O2
──────── ──────── ──────── ──────── ────────
Data.List.sort 0.663501s 0.665482s 0.652461s 0.792005s
Naive.quicksort 0.587091s 0.577796s 0.585754s 0.667573s
STUArray.quicksort 1.58023s 0.142626s 1.597479s 0.156411s
VSort.vsort 0.820639s 0.139967s 0.888566s 0.143918s
```

The times without optimisation are expectedly bad for the `STUArray`

. `unsafeRead`

and `unsafeWrite`

must be inlined to be fast. If not inlined, you get a dictionary lookup for each call. Thus for the large dataset, I omit the unoptimised ways:

```
list size: 3000000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 16.728576s 16.442377s
Naive.quicksort 14.297534s 12.253071s
STUArray.quicksort 2.307203s 2.200807s
VSort.vsort 2.069749s 1.921943s
```

You can see that an inplace sort on a mutable unboxed array is **much** faster than a list-based sort if done correctly. ~~Whether the difference between the ~~`STUArray`

sort and the sort on the unboxed mutable vector is due to the different algorithm or whether vectors are indeed faster here, I don't know. Since I've never observed vectors to be faster² than `STUArray`

s, I tend to believe the former.
The difference between the `STUArray`

quicksort and the introsort is in part due to the better conversion from and to lists that the vector package offers, in part due to the different algorithms.

At Louis Wasserman's suggestion, I have run a quick benchmark using the other sorting algorithms from the vector-algorithms package, using a not-too-large dataset. The results aren't surprising, the good general-purpose algorithms heapsort, introsort and mergesort all do well, times near the quicksort on the unboxed mutable array (but of course, the quicksort would degrade to quadratic behaviour on almost sorted input, while these are guaranteed O(n*log n) worst case). The special-purpose sorting algorithms `AmericanFlag`

and radix sort do badly, since the input doesn't fit well to their purpose (radix sort would do better on larger inputs with a larger range, as is, it does too many more passes than needed for the data). Insertion sort is by far the worst, due to its quadratic behaviour.

```
AmericanFlag:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.083845s 1.084699s
Naive.quicksort 0.981276s 1.05532s
STUArray.quicksort 0.218407s 0.215564s
VSort.vsort 2.566838s 2.618817s
Heap:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.084252s 1.07894s
Naive.quicksort 0.915984s 0.887354s
STUArray.quicksort 0.219786s 0.225748s
VSort.vsort 0.213507s 0.20152s
Insertion:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.168837s 1.066058s
Naive.quicksort 1.081806s 0.879439s
STUArray.quicksort 0.241958s 0.209631s
VSort.vsort 36.21295s 27.564993s
Intro:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.09189s 1.112415s
Naive.quicksort 0.891161s 0.989799s
STUArray.quicksort 0.236596s 0.227348s
VSort.vsort 0.221742s 0.20815s
Merge:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.087929s 1.074926s
Naive.quicksort 0.875477s 1.019984s
STUArray.quicksort 0.215551s 0.221301s
VSort.vsort 0.236661s 0.230287s
Radix:
list size: 300000 -O2 -fllvm-O2
──────── ──────── ────────
Data.List.sort 1.085658s 1.085726s
Naive.quicksort 1.002067s 0.900985s
STUArray.quicksort 0.217371s 0.228973s
VSort.vsort 1.958216s 1.970619s
```

Conclusion: Unless you have a specific reason not to, using one of the good general-purpose sorting algorithms from vector-algorithms, with a wrapper to convert from and to lists if necessary, is the recommended way to sort large lists. (These algorithms also work well with boxed vectors, in my measurements approximately 50% slower than unboxed.) For short lists, the overhead of the conversion would be so large that it doesn't pay.

Now, at @applicative's suggestion, a look at the sorting times for vector-algorithms' introsort, a quicksort on unboxed vectors and an improved (shamelessly stealing the implementation of `unstablePartition`

) quicksort on `STUArray`

s.

The improved `STUArray`

quicksort:

```
{-# LANGUAGE BangPatterns #-}
module NQuick (stuqsort) where
import Data.Array.Base (unsafeRead, unsafeWrite, getNumElements)
import Data.Array.ST
import Control.Monad.ST
import Control.Monad (when)
stuqsort :: STUArray s Int Int -> ST s ()
stuqsort arr = do
n <- getNumElements arr
when (n > 1) (myqsort arr 0 (n-1))
myqsort :: STUArray s Int Int -> Int -> Int -> ST s ()
myqsort a lo hi = do
p <- unsafeRead a hi
j <- unstablePartition (< p) lo hi a
h <- unsafeRead a j
unsafeWrite a j p
unsafeWrite a hi h
when (j > lo+1) (myqsort a lo (j-1))
when (j+1 < hi) (myqsort a (j+1) hi)
unstablePartition :: (Int -> Bool) -> Int -> Int -> STUArray s Int Int -> ST s Int
{-# INLINE unstablePartition #-}
unstablePartition f !lf !rg !v = from_left lf rg
where
from_left i j
| i == j = return i
| otherwise = do
x <- unsafeRead v i
if f x
then from_left (i+1) j
else from_right i (j-1)
from_right i j
| i == j = return i
| otherwise = do
x <- unsafeRead v j
if f x
then do
y <- unsafeRead v i
unsafeWrite v i x
unsafeWrite v j y
from_left (i+1) j
else from_right i (j-1)
```

The vector quicksort:

```
module VectorQuick (vquicksort) where
import qualified Data.Vector.Unboxed.Mutable as UM
import qualified Data.Vector.Generic.Mutable as GM
import Control.Monad.ST
import Control.Monad (when)
vquicksort :: UM.STVector s Int -> ST s ()
vquicksort uv = do
let li = UM.length uv - 1
ui = UM.unsafeSlice 0 li uv
p <- UM.unsafeRead uv li
j <- GM.unstablePartition (< p) ui
h <- UM.unsafeRead uv j
UM.unsafeWrite uv j p
UM.unsafeWrite uv li h
when (j > 1) (vquicksort (UM.unsafeSlice 0 j uv))
when (j + 1 < li) (vquicksort (UM.unsafeSlice (j+1) (li-j) uv))
```

The timing code:

```
{-# LANGUAGE BangPatterns #-}
module Main (main) where
import System.Environment (getArgs)
import System.CPUTime
import System.Random
import Text.Printf
import Data.Array.Unboxed
import Data.Array.ST hiding (unsafeThaw)
import Data.Array.Unsafe (unsafeThaw)
import Data.Array.Base (unsafeAt, unsafeNewArray_, unsafeWrite)
import Control.Monad.ST
import Control.Monad
import qualified Data.Vector.Unboxed as U
import qualified Data.Vector.Unboxed.Mutable as UM
import NQuick
import VectorQuick
import qualified Data.Vector.Algorithms.Intro as I
nextR :: StdGen -> (Int, StdGen)
nextR = randomR (minBound, maxBound)
buildArray :: StdGen -> Int -> UArray Int Int
buildArray sg size = runSTUArray (do
arr <- unsafeNewArray_ (0, size-1)
let fill i g
| i < size = do
let (r, g') = nextR g
unsafeWrite arr i r
fill (i+1) g'
| otherwise = return arr
fill 0 sg)
buildVector :: StdGen -> Int -> U.Vector Int
buildVector sg size = U.fromList $ take size (randoms sg)
time :: IO a -> IO ()
time action = do
t0 <- getCPUTime
action
t1 <- getCPUTime
let tm :: Double
tm = fromInteger (t1 - t0) * 1e-9
printf "%.3f ms\n" tm
stu :: UArray Int Int -> Int -> IO ()
stu ua sz = do
let !sa = runSTUArray (do
st <- unsafeThaw ua
stuqsort st
return st)
forM_ [0, sz `quot` 2, sz-1] (print . (sa `unsafeAt`))
intro :: U.Vector Int -> Int -> IO ()
intro uv sz = do
let !sv = runST (do
st <- U.unsafeThaw uv
I.sort st
U.unsafeFreeze st)
forM_ [0, sz `quot` 2, sz-1] (print . U.unsafeIndex sv)
vquick :: U.Vector Int -> Int -> IO ()
vquick uv sz = do
let !sv = runST (do
st <- U.unsafeThaw uv
vquicksort st
U.unsafeFreeze st)
forM_ [0, sz `quot` 2, sz-1] (print . U.unsafeIndex sv)
main :: IO ()
main = do
args <- getArgs
let !num = case args of
(a:_) -> read a
_ -> 1000000
!sg <- getStdGen
let !ar = buildArray sg num
!vc = buildVector sg num
!v2 = buildVector sg (foo num)
algos = [ ("Intro", intro v2), ("STUArray", stu ar), ("Vquick", vquick vc) ]
printf "Created data to be sorted, last elements %d %d %d\n" (ar ! (num-1)) (vc U.! (num-1)) (v2 U.! (num-1))
forM_ algos $ \(name, act) -> do
putStrLn name
time (act num)
-- For the prevention of sharing
foo :: Int -> Int
foo n
| n < 0 = -n
| n > 0 = n
| otherwise = 3
```

The results (times only):

```
$ ./timeSorts 3000000
Intro
587.911 ms
STUArray
402.939 ms
Vquick
414.936 ms
$ ./timeSorts 1000000
Intro
193.970 ms
STUArray
131.980 ms
Vquick
134.979 ms
```

The practically identical quicksorts on the `STUArray`

and the unboxed vector take practically the same time, as expected. (The old quicksort implementation was about 15% slower than the introsort. Comparing to the times above, about 70-75% there was spent converting from/to lists.)

On the random input, the quicksorts perform significantly better than the introsort, but on almost-sorted input, their performance would degrade while introsort wouldn't.

¹ Making the code polymorphic with `STUArray`

s is a pain at best, doing it with `IOUArray`

s and having both the sorting and the wrapper `{-# INLINABLE #-}`

produces the same performance with optimisations - without, the polymorphic code is significantly slower.

² Using the same algorithms, both were always equally fast within the precision of measurement when I compared (not very often).