# Quicksort in F# - syntax question

I have a simple f# quick sort function defined as:

``````let rec qsort(xs:List<int>) =

let smaller = xs |> List.filter(fun e -> e < xs.Head)
let larger = xs |> List.filter(fun e -> e > xs.Head)
match xs with
| [] -> []
``````

Is there a way in f# to write it more like Haskell:

``````qsort       :: [Int] -> [Int]
qsort []     = []
qsort (x:xs) =
qsort smaller ++ [x] ++ qsort larger
where
smaller = [a | a <- xs, a <= x]
larger  = [b | b <- xs, b >= x]
``````

I know the f# algorithm is missing a <= and >=. The question is more about syntax/readibility.

Thanks.

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FWIW, this is not quicksort. In particular, the last time I benchmarked that Haskell it was 6,000x slower than a real quicksort written in F#. For information about the real quicksort algorithm (and not the Haskell communities bastardized version that completely misses the whole point of being quick!), read Hoare's original 1961 paper: comjnl.oxfordjournals.org/cgi/content/short/5/1/10 – Jon Harrop Jan 3 '11 at 23:43

You want your second match clause to be `x :: xs`, and to use the @ (append) operator where your Haskell example uses ++:

``````let rec qsort xs =
match xs with
| [] -> []
| x :: xs ->
let smaller = qsort (xs |> List.filter(fun e -> e <= x))
let larger  = qsort (xs |> List.filter(fun e -> e >  x))
smaller @ [x] @ larger
``````

It's not quite the same as the Haskell definition by cases syntax, but hopefully similar enough for you!

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Minor note: I think `smaller @ x::larger`, rather than `smaller @ x @ larger`, is less pretty but a little faster in practice since it avoid re-copying your target list. – Juliet Dec 30 '09 at 20:38
"e >= x" should be "e > x" otherwise you will end up duplicating elements. – RodYan Jan 6 '10 at 19:11
@RodYan xs does not contain x, so you are not duplicating anything. – curial Nov 30 '12 at 10:58
@curial for example qsort [1; 1] will return [1; 1; 1] – xvorsx Sep 20 '13 at 8:12
@xvorsx you are right :) – curial Sep 20 '13 at 8:45

This is the most 'Haskellian' way I can think of, the only thing missing is being able to declare smaller/larger as a 'where' clause:

``````let rec qsort:int list -> int list = function
| [] -> []
| x::xs -> let smaller = [for a in xs do if a<=x then yield a]
let larger =  [for b in xs do if b>x then yield b]
qsort smaller @ [x] @ qsort larger
``````

I know it's not part of your question, but I'd use `List.partition` to split the list in smaller/larger in a single pass:

``````let rec qsort = function
| [] -> []
| x::xs -> let smaller,larger = List.partition (fun y -> y<=x) xs
qsort smaller @ [x] @ qsort larger
``````
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Props for adding the List.partition suggestion – Daniel Jan 14 '11 at 19:28

This seems to be as concise as it can get (combining the ideas from other answers, and using currying for operators):

``````let rec qsort = function
| [] -> []
| (x:int) :: xs ->
let smaller = List.filter ((>=) x) xs
let larger  = List.filter ((<) x) xs
qsort smaller @ [x] @ qsort larger
``````
-
`let smaller = List.filter ((<=) x) xs` btw. returns not the elements that are smaller, it returns the element that are greater than x. To get all elements smaller x you have to write `fun y -> y <= x` but the shortcut you used expands to `fun y -> x <= y` Note that `x` in your version is the first argument not the second! Additional you can't use `>=` and `<=` at the same time. `qsort [5;1;5;3]` otherwise returns `[1;3;5;5;5]`, nearly everyone seems to get this wrong. Because of this, i would not recommend partial application with operators in this case. – Sid Burn Jun 1 '15 at 21:51

haskell 'where' syntax, which lets you use the name of a function before its definition, kind of maps to f# 'let rec ... and'

``````let qsort xs =
let rec sort xs =
match ls with
|[] -> ....
|h::t -> (smaller t) @ h @ (larger t)

and smaller ls =    //the 'and' lets you define the
//  function after where it is used,
//  like with 'where' in haskell
... define smaller in terms of sort
and larger ls =
... same

sort xs
``````
-

...Or you could make a tail recursive qsort by using CPS:

``````let qSort lst =
let rec qs l cont =
match l with
| []      -> cont []
| (x::xs) -> qs (List.filter (fun e -> e <= x) xs) (fun smaller ->
qs (List.filter (fun e -> e >  x) xs) (fun larger  ->
smaller @ (x :: larger) |> cont))
qs lst id
``````
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``````let  rec QuickSort l =
match   l with
|  []  ->  []
|   _   ->  QuickSort([for e in l do if e < (List.head l) then yield e]) @[(List.head l)]@ QuickSort([for e in l do if e > (List.head l) then yield e])
``````
-

Don't forget that List has a partition method, so

``````let rec quicksort ls =
match ls with
| [] -> []
| h :: t -> let fore, aft = List.partition (fun i -> i < h) t
(quicksort fore) @ (h :: quicksort aft)
``````
-

I had done some analysis of sorting algorithms in F# a few years ago in a very imperative style; I was trying to beat the .NET stock implementation, and managed to do so here. Went to make the following reply to myself today, but FPish won't let me create an account. Argh! Gotta make my post somewhere, and here's as good as anywhere, lol...

While reading "Learn You a Haskell For Great Good" yesterday, the author set up an example for implementing quicksort. The description was quite clear and even before I got to the sample code, an elegant recursive solution (in Haskell) popped into my head. Guess I had never really had an intuitive feel for how quicksort does its thing, because the trivial solution is quite easy, if not very efficient.

Here is my version in F#:

``````let rec quicksort = function
| [] -> []
| pivot :: xs ->
(left pivot xs) @ pivot :: (right pivot xs)
and left pivot xs = quicksort [ for x in xs do if x <= pivot then yield x ]
and right pivot xs = quicksort [ for x in xs do if x > pivot then yield x ]
``````

And, the equivalent Haskell (I like this one... clean!):

``````quicksort :: Ord a => [a] -> [a]
quicksort [] = []
quicksort (pivot : xs) =
left ++ pivot : right
where
left = quicksort [ x | x <- xs, x <= pivot ]
right = quicksort [ x | x <- xs, x > pivot ]
``````

For grins, here's another F# version (mostly tail-recursive) that's about 2x the speed of the trivial version. Haven't bothered to time this against my original post, though, so no idea how it stacks up to the mutable version in my OP on FPish.net (FSHub) from a few years ago...

``````let rec quicksort' xs =
let rec aux pivot left right = function
| [] -> (quicksort' left) @ pivot :: (quicksort' right)
| x :: xs ->
if x <= pivot then
aux pivot (x :: left) right xs
else
aux pivot left (x::right) xs
match xs with
| [] -> []
| x :: xs -> aux x [] [] xs
``````
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