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Line 1: {{task\|Sorting Algorithms}} {{Sorting Algorithm}}~~[[Category:Recursion]]~~ [[Category:Sorting]] ~~{{wikipedia\|Quicksort}}~~ [[Category:Recursion]] {{Wikipedia\|Quicksort}} The task is to sort an array (or list) elements using the ''quicksort'' algorithm. The elements must have a strict weak order and the index of the array can be of any discrete type. For languages where this is not possible, sort an array of integers. ;Task: ~~Quicksort, also known as ''partition-exchange sort'', uses these steps.~~ Sort an array (or list) elements using the   [https://en.wikipedia.org/wiki/Quicksort ''quicksort'']   algorithm. The elements must have a   [https://en.wikipedia.org/wiki/Weak_ordering strict weak order]   and the index of the array can be of any discrete type. ~~# Choose any element of the array to be the pivot.~~ ~~# Divide all other elements (except the pivot) into two partitions.~~ For languages where this is not possible, sort an array of integers. ~~#* All elements less than the pivot must be in the first partition.~~ ~~#* All elements greater than the pivot must be in the second partition.~~ ~~# Use recursion to sort both partitions.~~ #Quicksort, ~~Join~~also ~~the~~known ~~first~~as ~~sorted~~  ''partition~~, the~~-exchange ~~pivot~~sort'', ~~and~~  ~~the~~uses ~~second~~these ~~sorted partition~~steps. ::#   Choose any element of the array to be the pivot. ::#   Divide all other elements (except the pivot) into two partitions. ::#*   All elements less than the pivot must be in the first partition. ::#*   All elements greater than the pivot must be in the second partition. ::#   Use recursion to sort both partitions. ::#   Join the first sorted partition, the pivot, and the second sorted partition. <br> The best pivot creates partitions of equal length (or lengths differing by   '''1'''). The worst pivot creates an empty partition (for example, if the pivot is the first or last element of a sorted array). The run-time of Quicksort ranges from   <big> ''[[O]](n ''log'' n)'' </big>   with the best pivots, to   <big> ''[[O]](n<sup>2</sup>)'' </big>   with the worst pivots, where   <big> ''n'' </big>   is the number of elements in the array. The best pivot creates partitions of equal length (or lengths differing by 1). The worst pivot creates an empty partition (for example, if the pivot is the first or last element of a sorted array). The runtime of Quicksort ranges from ''[[O]](n ''log'' n)'' with the best pivots, to ''[[O]](n<sup>2</sup>)'' with the worst pivots, where ''n'' is the number of elements in the array. This is a simple quicksort algorithm, adapted from Wikipedia. Line 49 ⟶ 64: quicksort(array '''from''' left '''to last index''') Quicksort has a reputation as the fastest sort. Optimized variants of quicksort are common features of many languages and libraries. One often contrasts quicksort with   [[../Merge sort\|merge sort]],   because both sorts have an average time of   <big> ''[[O]](n ''log'' n)''. </big> : ''"On average, mergesort does fewer comparisons than quicksort, so it may be better when complicated comparison routines are used. Mergesort also takes advantage of pre-existing order, so it would be favored for using sort() to merge several sorted arrays. On the other hand, quicksort is often faster for small arrays, and on arrays of a few distinct values, repeated many times."'' — http://perldoc.perl.org/sort.html Line 58 ⟶ 73: * Merge sort is a divide-then-conquer algorithm. The partioning happens in a trivial way, by splitting the input array in half. Most of the work happens during the recursive calls and the merge phase. <br> With quicksort, every element in the first partition is less than or equal to every element in the second partition. Therefore, the merge phase of quicksort is so trivial that it needs no mention! This task has not specified whether to allocate new arrays, or sort in place. This task also has not specified how to choose the pivot element. (Common ways to are to choose the first element, the middle element, or the median of three elements.) Thus there is a variety among the following implementations. <br><br> =={{header\|11l}}== {{trans\|Python}} <syntaxhighlight lang="11l">F _quicksort(&array, start, stop) -> Void I stop - start > 0 V pivot = array[start] V left = start V right = stop L left <= right L array[left] < pivot left++ L array[right] > pivot right-- I left <= right swap(&array[left], &array[right]) left++ right-- _quicksort(&array, start, right) _quicksort(&array, left, stop) F quicksort(&array) _quicksort(&array, 0, array.len - 1) V arr = [7, 6, 5, 9, 8, 4, 3, 1, 2, 0] quicksort(&arr) print(arr)</syntaxhighlight> {{out}} <pre> [0, 1, 2, 3, 4, 5, 6, 7, 8, 9] </pre> =={{header\|360 Assembly}}== {{trans\|REXX}} Structured version with ASM & ASSIST macros. <syntaxhighlight lang="360asm">* Quicksort 14/09/2015 & 23/06/2016 QUICKSOR CSECT USING QUICKSOR,R13 base register B 72(R15) skip savearea DC 17F'0' savearea STM R14,R12,12(R13) prolog ST R13,4(R15) " ST R15,8(R13) " LR R13,R15 " MVC A,=A(1) a(1)=1 MVC B,=A(NN) b(1)=hbound(t) L R6,=F'1' k=1 DO WHILE=(LTR,R6,NZ,R6) do while k<>0 ================== LR R1,R6 k SLA R1,2 ~ L R10,A-4(R1) l=a(k) LR R1,R6 k SLA R1,2 ~ L R11,B-4(R1) m=b(k) BCTR R6,0 k=k-1 LR R4,R11 m C R4,=F'2' if m<2 BL ITERATE then iterate LR R2,R10 l AR R2,R11 +m BCTR R2,0 -1 ST R2,X x=l+m-1 LR R2,R11 m SRA R2,1 m/2 AR R2,R10 +l ST R2,Y y=l+m/2 L R1,X x SLA R1,2 ~ L R4,T-4(R1) r4=t(x) L R1,Y y SLA R1,2 ~ L R5,T-4(R1) r5=t(y) LR R1,R10 l SLA R1,2 ~ L R3,T-4(R1) r3=t(l) IF CR,R4,LT,R3 if t(x)<t(l) ---+ IF CR,R5,LT,R4 if t(y)<t(x) \| LR R7,R4 p=t(x) \| L R1,X x \| SLA R1,2 ~ \| ST R3,T-4(R1) t(x)=t(l) \| ELSEIF CR,R5,GT,R3 elseif t(y)>t(l) \| LR R7,R3 p=t(l) \| ELSE , else \| LR R7,R5 p=t(y) \| L R1,Y y \| SLA R1,2 ~ \| ST R3,T-4(R1) t(y)=t(l) \| ENDIF , end if \| ELSE , else \| IF CR,R5,LT,R3 if t(y)<t(l) \| LR R7,R3 p=t(l) \| ELSEIF CR,R5,GT,R4 elseif t(y)>t(x) \| LR R7,R4 p=t(x) \| L R1,X x \| SLA R1,2 ~ \| ST R3,T-4(R1) t(x)=t(l) \| ELSE , else \| LR R7,R5 p=t(y) \| L R1,Y y \| SLA R1,2 ~ \| ST R3,T-4(R1) t(y)=t(l) \| ENDIF , end if \| ENDIF , end if ---+ LA R8,1(R10) i=l+1 L R9,X j=x FOREVER EQU * do forever --------------------+ LR R1,R8 i \| SLA R1,2 ~ \| LA R2,T-4(R1) @t(i) \| L R0,0(R2) t(i) \| DO WHILE=(CR,R8,LE,R9,AND, while i<=j and ---+ \| X CR,R0,LE,R7) t(i)<=p \| \| AH R8,=H'1' i=i+1 \| \| AH R2,=H'4' @t(i) \| \| L R0,0(R2) t(i) \| \| ENDDO , end while ---+ \| LR R1,R9 j \| SLA R1,2 ~ \| LA R2,T-4(R1) @t(j) \| L R0,0(R2) t(j) \| DO WHILE=(CR,R8,LT,R9,AND, while i<j and ---+ \| X CR,R0,GE,R7) t(j)>=p \| \| SH R9,=H'1' j=j-1 \| \| SH R2,=H'4' @t(j) \| \| L R0,0(R2) t(j) \| \| ENDDO , end while ---+ \| CR R8,R9 if i>=j \| BNL LEAVE then leave (segment finished) \| LR R1,R8 i \| SLA R1,2 ~ \| LA R2,T-4(R1) @t(i) \| LR R1,R9 j \| SLA R1,2 ~ \| LA R3,T-4(R1) @t(j) \| L R0,0(R2) w=t(i) + \| MVC 0(4,R2),0(R3) t(i)=t(j) \|swap t(i),t(j) \| ST R0,0(R3) t(j)=w + \| B FOREVER end do forever ----------------+ LEAVE EQU * LR R9,R8 j=i BCTR R9,0 j=i-1 LR R1,R9 j SLA R1,2 ~ LA R3,T-4(R1) @t(j) L R2,0(R3) t(j) LR R1,R10 l SLA R1,2 ~ ST R2,T-4(R1) t(l)=t(j) ST R7,0(R3) t(j)=p LA R6,1(R6) k=k+1 LR R1,R6 k SLA R1,2 ~ LA R4,A-4(R1) r4=@a(k) LA R5,B-4(R1) r5=@b(k) IF C,R8,LE,Y if i<=y ----+ ST R8,0(R4) a(k)=i \| L R2,X x \| SR R2,R8 -i \| LA R2,1(R2) +1 \| ST R2,0(R5) b(k)=x-i+1 \| LA R6,1(R6) k=k+1 \| ST R10,4(R4) a(k)=l \| LR R2,R9 j \| SR R2,R10 -l \| ST R2,4(R5) b(k)=j-l \| ELSE , else \| ST R10,4(R4) a(k)=l \| LR R2,R9 j \| SR R2,R10 -l \| ST R2,0(R5) b(k)=j-l \| LA R6,1(R6) k=k+1 \| ST R8,4(R4) a(k)=i \| L R2,X x \| SR R2,R8 -i \| LA R2,1(R2) +1 \| ST R2,4(R5) b(k)=x-i+1 \| ENDIF , end if ----+ ITERATE EQU * ENDDO , end while ===================== * * ******* print sorted table LA R3,PG ibuffer LA R4,T @t(i) DO WHILE=(C,R4,LE,=A(TEND)) do i=1 to hbound(t) L R2,0(R4) t(i) XDECO R2,XD edit t(i) MVC 0(4,R3),XD+8 put in buffer LA R3,4(R3) ibuffer=ibuffer+1 LA R4,4(R4) i=i+1 ENDDO , end do XPRNT PG,80 print buffer L R13,4(0,R13) epilog LM R14,R12,12(R13) " XR R15,R15 " BR R14 exit T DC F'10',F'9',F'9',F'6',F'7',F'16',F'1',F'16',F'17',F'15' DC F'1',F'9',F'18',F'16',F'8',F'20',F'18',F'2',F'19',F'8' TEND DS 0F NN EQU (TEND-T)/4) A DS (NN)F same size as T B DS (NN)F same size as T X DS F Y DS F PG DS CL80 XD DS CL12 YREGS END QUICKSOR</syntaxhighlight> {{out}} <pre> 1 1 2 6 7 8 8 9 9 9 10 15 16 16 16 17 18 18 19 20 </pre> =={{header\|AArch64 Assembly}}== {{works with\|as\|Raspberry Pi 3B version Buster 64 bits}} <syntaxhighlight lang="aarch64 assembly"> /* ARM assembly AARCH64 Raspberry PI 3B / / program quickSort64.s / /*****************************************/ / Constantes file / /*****************************************/ / for this file see task include a file in language AArch64 assembly / .include "../includeConstantesARM64.inc" /*******************************/ / Initialized data / /******************************/ .data szMessSortOk: .asciz "Table sorted.\n" szMessSortNok: .asciz "Table not sorted !!!!!.\n" sMessResult: .asciz "Value : @ \n" szCarriageReturn: .asciz "\n" .align 4 TableNumber: .quad 1,3,6,2,5,9,10,8,4,7,11 #TableNumber: .quad 10,9,8,7,6,-5,4,3,2,1 .equ NBELEMENTS, (. - TableNumber) / 8 /******************************/ / UnInitialized data / /******************************/ .bss sZoneConv: .skip 24 /******************************/ / code section / /******************************/ .text .global main main: // entry of program ldr x0,qAdrTableNumber // address number table mov x1,0 // first element mov x2,NBELEMENTS // number of élements bl quickSort ldr x0,qAdrTableNumber // address number table bl displayTable ldr x0,qAdrTableNumber // address number table mov x1,NBELEMENTS // number of élements bl isSorted // control sort cmp x0,1 // sorted ? beq 1f ldr x0,qAdrszMessSortNok // no !! error sort bl affichageMess b 100f 1: // yes ldr x0,qAdrszMessSortOk bl affichageMess 100: // standard end of the program mov x0,0 // return code mov x8,EXIT // request to exit program svc 0 // perform the system call qAdrsZoneConv: .quad sZoneConv qAdrszCarriageReturn: .quad szCarriageReturn qAdrsMessResult: .quad sMessResult qAdrTableNumber: .quad TableNumber qAdrszMessSortOk: .quad szMessSortOk qAdrszMessSortNok: .quad szMessSortNok /***************************************************************/ / control sorted table / /****************************************************************/ / x0 contains the address of table / / x1 contains the number of elements > 0 / / x0 return 0 if not sorted 1 if sorted / isSorted: stp x2,lr,[sp,-16]! // save registers stp x3,x4,[sp,-16]! // save registers mov x2,0 ldr x4,[x0,x2,lsl 3] 1: add x2,x2,1 cmp x2,x1 bge 99f ldr x3,[x0,x2, lsl 3] cmp x3,x4 blt 98f mov x4,x3 b 1b 98: mov x0,0 // not sorted b 100f 99: mov x0,1 // sorted 100: ldp x3,x4,[sp],16 // restaur 2 registers ldp x2,lr,[sp],16 // restaur 2 registers ret // return to address lr x30 /*************************************************/ / Appel récursif Tri Rapide quicksort / /*************************************************/ / x0 contains the address of table / / x1 contains index of first item / / x2 contains the number of elements > 0 / quickSort: stp x2,lr,[sp,-16]! // save registers stp x3,x4,[sp,-16]! // save registers str x5, [sp,-16]! // save registers sub x2,x2,1 // last item index cmp x1,x2 // first > last ? bge 100f // yes -> end mov x4,x0 // save x0 mov x5,x2 // save x2 bl partition1 // cutting into 2 parts mov x2,x0 // index partition mov x0,x4 // table address bl quickSort // sort lower part add x1,x2,1 // index begin = index partition + 1 add x2,x5,1 // number of elements bl quickSort // sort higter part 100: // end function ldr x5, [sp],16 // restaur 1 register ldp x3,x4,[sp],16 // restaur 2 registers ldp x2,lr,[sp],16 // restaur 2 registers ret // return to address lr x30 /****************************************************************/ / Partition table elements / /****************************************************************/ / x0 contains the address of table / / x1 contains index of first item / / x2 contains index of last item / partition1: stp x1,lr,[sp,-16]! // save registers stp x2,x3,[sp,-16]! // save registers stp x4,x5,[sp,-16]! // save registers stp x6,x7,[sp,-16]! // save registers ldr x3,[x0,x2,lsl 3] // load value last index mov x4,x1 // init with first index mov x5,x1 // init with first index 1: // begin loop ldr x6,[x0,x5,lsl 3] // load value cmp x6,x3 // compare value bge 2f ldr x7,[x0,x4,lsl 3] // if < swap value table str x6,[x0,x4,lsl 3] str x7,[x0,x5,lsl 3] add x4,x4,1 // and increment index 1 2: add x5,x5,1 // increment index 2 cmp x5,x2 // end ? blt 1b // no loop ldr x7,[x0,x4,lsl 3] // swap value str x3,[x0,x4,lsl 3] str x7,[x0,x2,lsl 3] mov x0,x4 // return index partition 100: ldp x6,x7,[sp],16 // restaur 2 registers ldp x4,x5,[sp],16 // restaur 2 registers ldp x2,x3,[sp],16 // restaur 2 registers ldp x1,lr,[sp],16 // restaur 2 registers ret // return to address lr x30 /****************************************************************/ / Display table elements / /****************************************************************/ / x0 contains the address of table / displayTable: stp x1,lr,[sp,-16]! // save registers stp x2,x3,[sp,-16]! // save registers mov x2,x0 // table address mov x3,0 1: // loop display table ldr x0,[x2,x3,lsl 3] ldr x1,qAdrsZoneConv bl conversion10S // décimal conversion ldr x0,qAdrsMessResult ldr x1,qAdrsZoneConv bl strInsertAtCharInc // insert result at // character bl affichageMess // display message add x3,x3,1 cmp x3,NBELEMENTS - 1 ble 1b ldr x0,qAdrszCarriageReturn bl affichageMess mov x0,x2 100: ldp x2,x3,[sp],16 // restaur 2 registers ldp x1,lr,[sp],16 // restaur 2 registers ret // return to address lr x30 /******************************************************/ / File Include fonctions / /******************************************************/ / for this file see task include a file in language AArch64 assembly / .include "../includeARM64.inc" </syntaxhighlight> <pre> Value : +1 Value : +2 Value : +3 Value : +4 Value : +5 Value : +6 Value : +7 Value : +8 Value : +9 Value : +10 Value : +11 Table sorted. </pre> =={{header\|ABAP}}== This works for ABAP Version 7.40 and above <syntaxhighlight lang="abap"> report z_quicksort. data(numbers) = value int4_table( ( 4 ) ( 65 ) ( 2 ) ( -31 ) ( 0 ) ( 99 ) ( 2 ) ( 83 ) ( 782 ) ( 1 ) ). perform quicksort changing numbers. write `[`. loop at numbers assigning field-symbol(<numbers>). write <numbers>. endloop. write `]`. form quicksort changing numbers type int4_table. data(less) = value int4_table( ). data(equal) = value int4_table( ). data(greater) = value int4_table( ). if lines( numbers ) > 1. data(pivot) = numbers[ lines( numbers ) / 2 ]. loop at numbers assigning field-symbol(<number>). if <number> < pivot. append <number> to less. elseif <number> = pivot. append <number> to equal. elseif <number> > pivot. append <number> to greater. endif. endloop. perform quicksort changing less. perform quicksort changing greater. clear numbers. append lines of less to numbers. append lines of equal to numbers. append lines of greater to numbers. endif. endform. </syntaxhighlight> {{out}} <pre> [ 31- 0 1 2 2 4 65 83 99 782 ] </pre> =={{header\|ACL2}}== <~~lang~~syntaxhighlight ~~Lisp~~lang="lisp">(defun partition (p xs) (if (endp xs) (mv nil nil) Line 80 ⟶ 566: (append (qsort less) (list (first xs)) (qsort more)))))</~~lang~~syntaxhighlight> Usage: <syntaxhighlight lang="text">> (qsort '(8 6 7 5 3 0 9)) (0 3 5 6 7 8 9)</~~lang~~syntaxhighlight> =={{header\|Action!}}== Action! language does not support recursion. Therefore an iterative approach with a stack has been proposed. <syntaxhighlight lang="action!">DEFINE MAX_COUNT="100" INT ARRAY stack(MAX_COUNT) INT stackSize PROC PrintArray(INT ARRAY a INT size) INT i Put('[) FOR i=0 TO size-1 DO IF i>0 THEN Put(' ) FI PrintI(a(i)) OD Put(']) PutE() RETURN PROC InitStack() stackSize=0 RETURN BYTE FUNC IsEmpty() IF stackSize=0 THEN RETURN (1) FI RETURN (0) PROC Push(INT low,high) stack(stackSize)=low stackSize==+1 stack(stackSize)=high stackSize==+1 RETURN PROC Pop(INT POINTER low,high) stackSize==-1 high^=stack(stackSize) stackSize==-1 low^=stack(stackSize) RETURN INT FUNC Partition(INT ARRAY a INT low,high) INT part,v,i,tmp v=a(high) part=low-1 FOR i=low TO high-1 DO IF a(i)<=v THEN part==+1 tmp=a(part) a(part)=a(i) a(i)=tmp FI OD part==+1 tmp=a(part) a(part)=a(high) a(high)=tmp RETURN (part) PROC QuickSort(INT ARRAY a INT size) INT low,high,part InitStack() Push(0,size-1) WHILE IsEmpty()=0 DO Pop(@low,@high) part=Partition(a,low,high) IF part-1>low THEN Push(low,part-1) FI IF part+1<high THEN Push(part+1,high) FI OD RETURN PROC Test(INT ARRAY a INT size) PrintE("Array before sort:") PrintArray(a,size) QuickSort(a,size) PrintE("Array after sort:") PrintArray(a,size) PutE() RETURN PROC Main() INT ARRAY a(10)=[1 4 65535 0 3 7 4 8 20 65530], b(21)=[10 9 8 7 6 5 4 3 2 1 0 65535 65534 65533 65532 65531 65530 65529 65528 65527 65526], c(8)=[101 102 103 104 105 106 107 108], d(12)=[1 65535 1 65535 1 65535 1 65535 1 65535 1 65535] Test(a,10) Test(b,21) Test(c,8) Test(d,12) RETURN</syntaxhighlight> {{out}} [https://gitlab.com/amarok8bit/action-rosetta-code/-/raw/master/images/Quicksort.png Screenshot from Atari 8-bit computer] <pre> Array before sort: [1 4 -1 0 3 7 4 8 20 -6] Array after sort: [-6 -1 0 1 3 4 4 7 8 20] Array before sort: [10 9 8 7 6 5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10] Array after sort: [-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10] Array before sort: [101 102 103 104 105 106 107 108] Array after sort: [101 102 103 104 105 106 107 108] Array before sort: [1 -1 1 -1 1 -1 1 -1 1 -1 1 -1] Array after sort: [-1 -1 -1 -1 -1 -1 1 1 1 1 1 1] </pre> =={{header\|ActionScript}}== {{works with\|ActionScript\|3}}<br> The functional programming way <~~lang~~syntaxhighlight lang="actionscript">function quickSort (array:Array):Array { if (array.length <= 1) Line 99 ⟶ 707: array.filter(function (x:Number, index:int, array:Array):Boolean { return x == pivot; })).concat( quickSort(array.filter(function (x:Number, index:int, array:Array):Boolean { return x > pivot; }))); }</~~lang~~syntaxhighlight> The faster way <~~lang~~syntaxhighlight lang="actionscript">function quickSort (array:Array):Array { if (array.length <= 1) Line 125 ⟶ 733: equal).concat( quickSort(greater)); }</~~lang~~syntaxhighlight> =={{header\|Ada}}== This example is implemented as a generic procedure. ~~The procedure specification is:~~ ~~<lang ada>-----------------------------------------------------------------------~~ The procedure specification is: ~~-- Generic Quicksort procedure~~ <syntaxhighlight lang="ada">----------------------------------------------------------------------- -- Generic Quick_Sort procedure ----------------------------------------------------------------------- generic type ~~Element_Type~~Element is private; type ~~Index_Type~~Index is (<>); type Element_Array is array(~~Index_Type~~Index range <>) of ~~Element_Type~~Element; with function "<" (Left, Right : ~~Element_Type~~Element) return Boolean is <>; procedure Quick_Sort(A : in out Element_Array);</syntaxhighlight> ~~with function ">" (Left, Right : Element_Type) return Boolean is <>;~~ ~~procedure Sort(Item : in out Element_Array);</lang>~~ The procedure body deals with any discrete index type, either an integer type or an enumerated type. <~~lang~~syntaxhighlight lang="ada">----------------------------------------------------------------------- -- Generic ~~Quicksort~~Quick_Sort procedure ----------------------------------------------------------------------- procedure ~~Sort~~Quick_Sort (~~Item~~A : in out Element_Array) is procedure Swap(Left, Right : ~~in out Element_Type~~Index) is Temp : ~~Element_Type~~Element := A (Left); begin A (Left) := A (Right); A (Right) := Temp; end Swap; ~~Pivot_Index : Index_Type;~~ ~~Pivot_Value : Element_Type;~~ ~~Right : Index_Type := Item'Last;~~ ~~Left : Index_Type := Item'First;~~ begin if ~~Item~~A'Length > 1 then declare ~~Pivot_Index := Index_Type'Val((Index_Type'Pos(Item'Last) + 1 +~~ Pivot_Value : Element := A ~~Index_Type'Pos~~(~~Item~~A'First~~)) / 2~~); ~~Pivot_Value~~Right : Index := ~~Item(Pivot_Index)~~A'Last; Left : Index := A'First; begin ~~Left := Item'First;~~ ~~Right~~ ~~:= Item'Last;~~loop while Left < Right and not (Pivot_Value < A (Left)) loop ~~loop~~ ~~while~~ Left <:= ~~Item~~Index'~~Last~~Succ ~~and then Item~~(Left) ~~< Pivot_Value loop~~; end ~~Left := Index_Type'Succ(Left)~~loop; ~~end~~ while Pivot_Value < A (Right) loop; ~~while~~ Right >:= ~~Item~~Index'~~First~~Pred ~~and then Item~~(Right) ~~> Pivot_Value loop~~; end ~~Right := Index_Type'Pred(Right)~~loop; ~~end~~ ~~loop~~exit when Right <= Left; ~~exit~~ ~~when~~Swap (Left >=, Right); ~~Swap(Item(~~ Left), ~~Item~~:= Index'Succ (~~Right)~~Left); if ~~Left~~Right <:= ~~Item~~Index'~~Last and~~Pred (Right ~~> Item'First then~~); end loop; ~~Left := Index_Type'Succ(Left);~~ if Right := ~~Index_Type~~A'~~Pred(Right);~~Last then ~~end~~ ifRight := Index'Pred (Right); ~~end~~ ~~loop~~ Swap (A'First, A'Last); if ~~Right~~end ~~> Item'First then~~if; if Left ~~Sort(Item(Item~~= A'First~~..Index_Type'Pred(Right)));~~ then ~~end~~ if Left := Index'Succ (Left); if ~~Left~~end ~~< Item'Last then~~if; Quick_Sort (A ~~Sort~~(~~Item(Left~~A'First ..~~Item'Last~~ Right)); Quick_Sort (A (Left .. A'Last)); ~~end if;~~ end; end if; end ~~Sort~~Quick_Sort;</~~lang~~syntaxhighlight> An example of how this procedure may be used is: <syntaxhighlight lang ="ada">~~with Sort;~~ with Ada.Text_Io; with Ada.Float_Text_IO; use Ada.Float_Text_IO; with Quick_Sort; procedure Sort_Test is type Days is (Mon, Tue, Wed, Thu, Fri, Sat, Sun); type Sales is array (Days range <>) of Float; procedure Sort_Days is new ~~Sort~~Quick_Sort(Float, Days, Sales); procedure Print (Item : Sales) is begin for I in Item'range loop Line 220 ⟶ 826: Print(Weekly_Sales); end Sort_Test;</~~lang~~syntaxhighlight> =={{header\|ALGOL 68}}== <syntaxhighlight lang="algol68">#--- Swap function ---# ~~From: http://en.wikibooks.org/wiki/Algorithm_implementation/Sorting/Quicksort#ALGOL_68~~ ~~<lang algol68>~~PROC ~~partition~~swap = (REF [] ~~DATA~~INT array, ~~PROC (REF~~INT ~~DATA~~first, ~~REF~~INT ~~DATA~~second) ~~BOOL cmp)INT~~VOID: ( ( ~~INT begin:=LWB array;~~ INT ~~end~~temp :=~~UPB~~ array[first]; array[first] := array[second]; ~~WHILE begin < end DO~~ array[second]:= temp ~~WHILE begin < end DO~~ ); ~~IF cmp(array[begin], array[end]) THEN~~ ~~DATA tmp=array[begin];~~ #--- Quick sort 3 arg function ---# ~~array[begin]:=array[end];~~ PROC quick = (REF [] INT array, INT first, INT last) VOID: ~~array[end]:=tmp;~~ ( ~~GO TO break while decr end~~ INT smaller := first + 1, ~~FI;~~ ~~end~~ - larger := 1last, pivot := array[first]; WHILE smaller <= larger DO WHILE array[smaller] < pivot AND smaller < last DO smaller +:= 1 OD; WHILE array[larger] > pivot AND larger > first DO larger -:= 1 OD; IF smaller < larger THEN swap(array, smaller, larger); smaller +:= 1; larger -:= 1 ELSE smaller +:= 1 FI OD; ~~break while decr end: SKIP;~~ swap(array, first, larger); ~~WHILE begin < end DO~~ ~~IF cmp(array[begin], array[end]) THEN~~ IF first < larger-1 THEN ~~DATA tmp=array[begin];~~ quick(array~~[begin]:=array[end];~~, first, larger-1) ~~array[end]:=tmp~~FI; IF last > larger +1 THEN ~~GO TO break while incr begin~~ quick(array, larger+1, last) ~~FI;~~ ~~begin +:= 1~~FI ~~OD;~~ ~~break while incr begin: SKIP~~ ~~OD;~~ ~~begin~~ ); #--- Quick sort 1 arg function ---# ~~PROC qsort=(REF [] DATA array, PROC (REF DATA, REF DATA) BOOL cmp)VOID: (~~ PROC quicksort IF= ~~LWB~~(REF ~~array < UPB~~[]INT array) ~~THEN~~VOID: ( ~~INT i := partition(array, cmp);~~ IF UPB array > 1 THEN ~~PAR ( # remove PAR for single threaded sort #~~ ~~qsort~~quick(array~~[:i-~~, 1], ~~cmp~~UPB array), ~~qsort(array[i+1:], cmp)~~ ) FI ); #*************************************************************# main: ( [10]INT a; FOR i FROM 1 TO UPB a DO a[i] := ROUND(random1000) OD; print(("Before:", a)); quicksort(a); print((newline, newline)); print(("After: ", a)) ) </syntaxhighlight> {{out}} <pre> Before: +73 +921 +179 +961 +50 +324 +82 +178 +243 +458 After: +50 +73 +82 +178 +179 +243 +324 +458 +921 +961 </pre> =={{header\|ALGOL W}}== <syntaxhighlight lang="algolw">% Quicksorts in-place the array of integers v, from lb to ub % procedure quicksort ( integer array v( * ) ; integer value lb, ub ) ; if ub > lb then begin % more than one element, so must sort % integer left, right, pivot; left := lb; right := ub; % choosing the middle element of the array as the pivot % pivot := v( left + ( ( right + 1 ) - left ) div 2 ); while begin while left <= ub and v( left ) < pivot do left := left + 1; while right >= lb and v( right ) > pivot do right := right - 1; left <= right end do begin integer swap; swap := v( left ); v( left ) := v( right ); v( right ) := swap; left := left + 1; right := right - 1 end while_left_le_right ; quicksort( v, lb, right ); quicksort( v, left, ub ) end quicksort ;</syntaxhighlight> =={{header\|APL}}== {{works with\|Dyalog APL}}{{trans\|J}} <syntaxhighlight lang="apl"> qsort ← {1≥⍴⍵:⍵ ⋄ e←⍵[?⍴⍵] ⋄ (∇(⍵<e)/⍵) , ((⍵=e)/⍵) , (∇(⍵>e)/⍵)} qsort 31 4 1 5 9 2 6 5 3 5 8 1 2 3 4 5 5 5 6 8 9 31</syntaxhighlight> Of course, in real APL applications, one would use ⍋ (Grade Up) to sort (which will pick a sorting algorithm suited to the argument): <syntaxhighlight lang="apl"> sort ← {⍵[⍋⍵]} sort 31 4 1 5 9 2 6 5 3 5 8 1 2 3 4 5 5 5 6 8 9 31</syntaxhighlight> =={{header\|AppleScript}}== ===Functional=== Emphasising clarity and simplicity more than run-time performance. (Practical scripts will often delegate sorting to the OS X shell, or, since OS X Yosemite, to Foundation classes through the ObjC interface). {{trans\|JavaScript}} (Functional ES5 version) <syntaxhighlight lang="applescript">-- quickSort :: (Ord a) => [a] -> [a] on quickSort(xs) if length of xs > 1 then set {h, t} to uncons(xs) -- lessOrEqual :: a -> Bool script lessOrEqual on \|λ\|(x) x ≤ h end \|λ\| end script set {less, more} to partition(lessOrEqual, t) quickSort(less) & h & quickSort(more) else xs end if end quickSort -- TEST ----------------------------------------------------------------------- on run quickSort([11.8, 14.1, 21.3, 8.5, 16.7, 5.7]) --> {5.7, 8.5, 11.8, 14.1, 16.7, 21.3} end run -- GENERIC FUNCTIONS ---------------------------------------------------------- -- partition :: predicate -> List -> (Matches, nonMatches) -- partition :: (a -> Bool) -> [a] -> ([a], [a]) on partition(f, xs) tell mReturn(f) set lst to {{}, {}} repeat with x in xs set v to contents of x set end of item ((\|λ\|(v) as integer) + 1) of lst to v end repeat return {item 2 of lst, item 1 of lst} end tell end partition -- uncons :: [a] -> Maybe (a, [a]) on uncons(xs) if length of xs > 0 then {item 1 of xs, rest of xs} else missing value end if end uncons -- Lift 2nd class handler function into 1st class script wrapper -- mReturn :: Handler -> Script on mReturn(f) if class of f is script then f else script property \|λ\| : f end script end if end mReturn</syntaxhighlight> {{Out}} <syntaxhighlight lang="applescript">{5.7, 8.5, 11.8, 14.1, 16.7, 21.3}</syntaxhighlight> ---- ===Straightforward=== Emphasising clarity, quick sorting, ''and'' correct AppleScript: <syntaxhighlight lang="applescript">-- In-place Quicksort (basic algorithm). -- Algorithm: S.A.R. (Tony) Hoare, 1960. on quicksort(theList, l, r) -- Sort items l thru r of theList. set listLength to (count theList) if (listLength < 2) then return -- Convert negative and/or transposed range indices. if (l < 0) then set l to listLength + l + 1 if (r < 0) then set r to listLength + r + 1 if (l > r) then set {l, r} to {r, l} -- Script object containing the list as a property (to allow faster references to its items) -- and the recursive subhandler. script o property lst : theList on qsrt(l, r) set pivot to my lst's item ((l + r) div 2) set i to l set j to r repeat until (i > j) set lv to my lst's item i repeat while (pivot > lv) set i to i + 1 set lv to my lst's item i end repeat set rv to my lst's item j repeat while (rv > pivot) set j to j - 1 set rv to my lst's item j end repeat if (j > i) then set my lst's item i to rv set my lst's item j to lv else if (i > j) then exit repeat end if set i to i + 1 set j to j - 1 end repeat if (j > l) then qsrt(l, j) if (i < r) then qsrt(i, r) end qsrt end script tell o to qsrt(l, r) return -- nothing. end quicksort property sort : quicksort -- Demo: local aList set aList to {28, 9, 95, 22, 67, 55, 20, 41, 60, 53, 100, 72, 19, 67, 14, 42, 29, 20, 74, 39} sort(aList, 1, -1) -- Sort items 1 thru -1 of aList. return aList</syntaxhighlight> {{output}} <syntaxhighlight lang="applescript">{9, 14, 19, 20, 20, 22, 28, 29, 39, 41, 42, 53, 55, 60, 67, 67, 72, 74, 95, 100}</syntaxhighlight> =={{header\|Arc}}== <syntaxhighlight lang="arc">(def qs (seq) (if (empty seq) nil (let pivot (car seq) (join (qs (keep [< _ pivot] (cdr seq))) (list pivot) (qs (keep [>= _ pivot] (cdr seq)))))))</syntaxhighlight> =={{header\|ARM Assembly}}== {{works with\|as\|Raspberry Pi}} <syntaxhighlight lang="arm assembly"> /* ARM assembly Raspberry PI / / program quickSort.s / / look pseudo code in wikipedia quicksort / /**********************************/ / Constantes / /*********************************/ .equ STDOUT, 1 @ Linux output console .equ EXIT, 1 @ Linux syscall .equ WRITE, 4 @ Linux syscall /******************************/ / Initialized data / /******************************/ .data szMessSortOk: .asciz "Table sorted.\n" szMessSortNok: .asciz "Table not sorted !!!!!.\n" sMessResult: .ascii "Value : " sMessValeur: .fill 11, 1, ' ' @ size => 11 szCarriageReturn: .asciz "\n" .align 4 ~~MODE DATA = INT;~~ iGraine: .int 123456 ~~PROC cmp=(REF DATA a,b)BOOL: a>b;~~ .equ NBELEMENTS, 10 #TableNumber: .int 9,5,6,1,2,3,10,8,4,7 #TableNumber: .int 1,3,5,2,4,6,10,8,4,7 #TableNumber: .int 1,3,5,2,4,6,10,8,4,7 #TableNumber: .int 1,2,3,4,5,6,10,8,4,7 TableNumber: .int 10,9,8,7,6,5,4,3,2,1 #TableNumber: .int 13,12,11,10,9,8,7,6,5,4,3,2,1 /******************************/ / UnInitialized data / /******************************/ .bss /******************************/ / code section / /******************************/ .text .global main main: @ entry of program 1: ~~main:(~~ ldr r0,iAdrTableNumber @ address number table ~~[]DATA const l=(5,4,3,2,1);~~ ~~[UPB const l]DATA l:=const l;~~ ~~qsort(l,cmp);~~ ~~printf(($g(3)$,l))~~ ~~)</lang>~~ mov r1,#0 @ indice first item ~~== {{header\|APL}} ==~~ mov r2,#NBELEMENTS @ number of élements ~~{{works with\|Dyalog APL}}{{trans\|J}}~~ bl triRapide @ call quicksort ~~<lang apl> qsort ← {1≥⍴⍵:⍵⋄e←⍵[?⍴⍵]⋄ (∇(⍵<e)/⍵) , ((⍵=e)/⍵) , ∇(⍵>e)/⍵}~~ ldr r0,iAdrTableNumber @ address number table ~~qsort 1 3 5 7 9 8 6 4 2~~ bl displayTable ~~1 2 3 4 5 6 7 8 9</lang>~~ ldr r0,iAdrTableNumber @ address number table mov r1,#NBELEMENTS @ number of élements bl isSorted @ control sort cmp r0,#1 @ sorted ? beq 2f ldr r0,iAdrszMessSortNok @ no !! error sort bl affichageMess b 100f 2: @ yes ldr r0,iAdrszMessSortOk bl affichageMess 100: @ standard end of the program mov r0, #0 @ return code mov r7, #EXIT @ request to exit program svc #0 @ perform the system call iAdrsMessValeur: .int sMessValeur iAdrszCarriageReturn: .int szCarriageReturn iAdrsMessResult: .int sMessResult iAdrTableNumber: .int TableNumber iAdrszMessSortOk: .int szMessSortOk iAdrszMessSortNok: .int szMessSortNok /***************************************************************/ / control sorted table / /****************************************************************/ / r0 contains the address of table / / r1 contains the number of elements > 0 / / r0 return 0 if not sorted 1 if sorted / isSorted: push {r2-r4,lr} @ save registers mov r2,#0 ldr r4,[r0,r2,lsl #2] 1: add r2,#1 cmp r2,r1 movge r0,#1 bge 100f ldr r3,[r0,r2, lsl #2] cmp r3,r4 movlt r0,#0 blt 100f mov r4,r3 b 1b 100: pop {r2-r4,lr} bx lr @ return ~~Of course, in real APL applications, one would use ⍋ to sort (which will pick a sorting algorithm suited to the argument).~~ /*************************************************/ / Appel récursif Tri Rapide quicksort / /*************************************************/ / r0 contains the address of table / / r1 contains index of first item / / r2 contains the number of elements > 0 / triRapide: push {r2-r5,lr} @ save registers sub r2,#1 @ last item index cmp r1,r2 @ first > last ? bge 100f @ yes -> end mov r4,r0 @ save r0 mov r5,r2 @ save r2 bl partition1 @ cutting into 2 parts mov r2,r0 @ index partition mov r0,r4 @ table address bl triRapide @ sort lower part add r1,r2,#1 @ index begin = index partition + 1 add r2,r5,#1 @ number of elements bl triRapide @ sort higter part 100: @ end function pop {r2-r5,lr} @ restaur registers bx lr @ return /****************************************************************/ / Partition table elements / /****************************************************************/ / r0 contains the address of table / / r1 contains index of first item / / r2 contains index of last item / partition1: push {r1-r7,lr} @ save registers ldr r3,[r0,r2,lsl #2] @ load value last index mov r4,r1 @ init with first index mov r5,r1 @ init with first index 1: @ begin loop ldr r6,[r0,r5,lsl #2] @ load value cmp r6,r3 @ compare value ldrlt r7,[r0,r4,lsl #2] @ if < swap value table strlt r6,[r0,r4,lsl #2] strlt r7,[r0,r5,lsl #2] addlt r4,#1 @ and increment index 1 add r5,#1 @ increment index 2 cmp r5,r2 @ end ? blt 1b @ no loop ldr r7,[r0,r4,lsl #2] @ swap value str r3,[r0,r4,lsl #2] str r7,[r0,r2,lsl #2] mov r0,r4 @ return index partition 100: pop {r1-r7,lr} bx lr /****************************************************************/ / Display table elements / /****************************************************************/ / r0 contains the address of table / displayTable: push {r0-r3,lr} @ save registers mov r2,r0 @ table address mov r3,#0 1: @ loop display table ldr r0,[r2,r3,lsl #2] ldr r1,iAdrsMessValeur @ display value bl conversion10 @ call function ldr r0,iAdrsMessResult bl affichageMess @ display message add r3,#1 cmp r3,#NBELEMENTS - 1 ble 1b ldr r0,iAdrszCarriageReturn bl affichageMess 100: pop {r0-r3,lr} bx lr /****************************************************************/ / display text with size calculation / /****************************************************************/ / r0 contains the address of the message / affichageMess: push {r0,r1,r2,r7,lr} @ save registres mov r2,#0 @ counter length 1: @ loop length calculation ldrb r1,[r0,r2] @ read octet start position + index cmp r1,#0 @ if 0 its over addne r2,r2,#1 @ else add 1 in the length bne 1b @ and loop @ so here r2 contains the length of the message mov r1,r0 @ address message in r1 mov r0,#STDOUT @ code to write to the standard output Linux mov r7, #WRITE @ code call system "write" svc #0 @ call systeme pop {r0,r1,r2,r7,lr} @ restaur des 2 registres / bx lr @ return /*****************************************************************/ / Converting a register to a decimal unsigned / /****************************************************************/ / r0 contains value and r1 address area / / r0 return size of result (no zero final in area) / / area size => 11 bytes / .equ LGZONECAL, 10 conversion10: push {r1-r4,lr} @ save registers mov r3,r1 mov r2,#LGZONECAL 1: @ start loop bl divisionpar10U @ unsigned r0 <- dividende. quotient ->r0 reste -> r1 add r1,#48 @ digit strb r1,[r3,r2] @ store digit on area cmp r0,#0 @ stop if quotient = 0 subne r2,#1 @ else previous position bne 1b @ and loop @ and move digit from left of area mov r4,#0 2: ldrb r1,[r3,r2] strb r1,[r3,r4] add r2,#1 add r4,#1 cmp r2,#LGZONECAL ble 2b @ and move spaces in end on area mov r0,r4 @ result length mov r1,#' ' @ space 3: strb r1,[r3,r4] @ store space in area add r4,#1 @ next position cmp r4,#LGZONECAL ble 3b @ loop if r4 <= area size 100: pop {r1-r4,lr} @ restaur registres bx lr @return /*************************************************/ / division par 10 unsigned / /*************************************************/ / r0 dividende / / r0 quotient / / r1 remainder / divisionpar10U: push {r2,r3,r4, lr} mov r4,r0 @ save value //mov r3,#0xCCCD @ r3 <- magic_number lower raspberry 3 //movt r3,#0xCCCC @ r3 <- magic_number higter raspberry 3 ldr r3,iMagicNumber @ r3 <- magic_number raspberry 1 2 umull r1, r2, r3, r0 @ r1<- Lower32Bits(r1r0) r2<- Upper32Bits(r1r0) mov r0, r2, LSR #3 @ r2 <- r2 >> shift 3 add r2,r0,r0, lsl #2 @ r2 <- r0 5 sub r1,r4,r2, lsl #1 @ r1 <- r4 - (r2 * 2) = r4 - (r0 * 10) pop {r2,r3,r4,lr} bx lr @ leave function iMagicNumber: .int 0xCCCCCCCD </syntaxhighlight> =={{header\|Arturo}}== <syntaxhighlight lang="rebol">quickSort: function [items][ if 2 > size items -> return items pivot: first items left: select slice items 1 (size items)-1 'x -> x < pivot right: select slice items 1 (size items)-1 'x -> x >= pivot ((quickSort left) ++ pivot) ++ quickSort right ] print quickSort [3 1 2 8 5 7 9 4 6]</syntaxhighlight> {{out}} <pre>1 2 3 4 5 6 7 8 9</pre> =={{header\|ATS}}== === A quicksort working on non-linear linked lists === <syntaxhighlight lang="ats">(------------------------------------------------------------------) (* Quicksort in ATS2, for non-linear lists. ) (------------------------------------------------------------------) #include "share/atspre_staload.hats" #define NIL list_nil () #define :: list_cons (------------------------------------------------------------------) ( A simple quicksort working on "garbage-collected" linked lists, with first element as pivot. This is meant as a demonstration, not as a superior sort algorithm. It is based on the "not-in-place" task pseudocode. ) datatype comparison_result = \| first_is_less_than_second of () \| first_is_equal_to_second of () \| first_is_greater_than_second of () extern fun {a : t@ype} list_quicksort$comparison (x : a, y : a) :<> comparison_result extern fun {a : t@ype} list_quicksort {n : int} (lst : list (a, n)) :<> list (a, n) ( - - - - - - - - - - - - - - - - - - - - - - ) implement {a} list_quicksort {n} (lst) = let fun partition {n : nat} .<n>. ( Proof of termination. ) (lst : list (a, n), pivot : a) :<> [n1, n2, n3 : int \| n1 + n2 + n3 == n] @(list (a, n1), list (a, n2), list (a, n3)) = ( This implementation is not tail recursive. I may get a scolding for using ATS to risk stack overflow! However, I need more practice writing non-tail routines. :) Also, a lot of programmers in other languages would do it this way--especially if the lists are evaluated lazily. ) case+ lst of \| NIL => @(NIL, NIL, NIL) \| head :: tail => let val @(lt, eq, gt) = partition (tail, pivot) prval () = lemma_list_param lt prval () = lemma_list_param eq prval () = lemma_list_param gt in case+ list_quicksort$comparison<a> (head, pivot) of \| first_is_less_than_second () => @(head :: lt, eq, gt) \| first_is_equal_to_second () => @(lt, head :: eq, gt) \| first_is_greater_than_second () => @(lt, eq, head :: gt) end fun quicksort {n : nat} .<n>. ( Proof of termination. ) (lst : list (a, n)) :<> list (a, n) = case+ lst of \| NIL => lst \| _ :: NIL => lst \| head :: tail => let ( We are careful here to run "partition" on "tail" rather than "lst", so the termination metric will be provably decreasing. (Really the compiler forces us to take such care, or else to change :<> to :<!ntm>) ) val pivot = head prval () = lemma_list_param tail val @(lt, eq, gt) = partition {n - 1} (tail, pivot) prval () = lemma_list_param lt prval () = lemma_list_param eq prval () = lemma_list_param gt val eq = pivot :: eq and lt = quicksort lt and gt = quicksort gt in lt + (eq + gt) end prval () = lemma_list_param lst in quicksort {n} lst end (------------------------------------------------------------------) val example_strings = $list ("choose", "any", "element", "of", "the", "array", "to", "be", "the", "pivot", "divide", "all", "other", "elements", "except", "the", "pivot", "into", "two", "partitions", "all", "elements", "less", "than", "the", "pivot", "must", "be", "in", "the", "first", "partition", "all", "elements", "greater", "than", "the", "pivot", "must", "be", "in", "the", "second", "partition", "use", "recursion", "to", "sort", "both", "partitions", "join", "the", "first", "sorted", "partition", "the", "pivot", "and", "the", "second", "sorted", "partition") implement list_quicksort$comparison<string> (x, y) = let val i = strcmp (x, y) in if i < 0 then first_is_less_than_second else if i = 0 then first_is_equal_to_second else first_is_greater_than_second end implement main0 () = let val sorted_strings = list_quicksort<string> example_strings fun print_strings {n : nat} .<n>. (strings : list (string, n), i : int) : void = case+ strings of \| NIL => if i <> 1 then println! () else () \| head :: tail => begin print! head; if i = 8 then begin println! (); print_strings (tail, 1) end else begin print! " "; print_strings (tail, succ i) end end in println! (length example_strings); println! (length sorted_strings); print_strings (sorted_strings, 1) end (------------------------------------------------------------------)</syntaxhighlight> {{out}} <pre>$ patscc -O3 -DATS_MEMALLOC_GCBDW quicksort_task_for_lists.dats -lgc && ./a.out 62 62 all all all and any array be be be both choose divide element elements elements elements except first first greater in in into join less must must of other partition partition partition partition partitions partitions pivot pivot pivot pivot pivot recursion second second sort sorted sorted than than the the the the the the the the the the to to two use</pre> === A quicksort working on linear linked lists === This program was derived from the quicksort for non-linear linked lists. <syntaxhighlight lang="ats">(------------------------------------------------------------------) ( Quicksort in ATS2, for linear lists. ) (------------------------------------------------------------------) #include "share/atspre_staload.hats" #define NIL list_vt_nil () #define :: list_vt_cons (------------------------------------------------------------------) ( A simple quicksort working on linear linked lists, with first element as pivot. This is meant as a demonstration, not as a superior sort algorithm. It is based on the "not-in-place" task pseudocode. ) #define FIRST_IS_LESS_THAN_SECOND 1 #define FIRST_IS_EQUAL_TO_SECOND 2 #define FIRST_IS_GREATER_THAN_SECOND 3 typedef comparison_result = [i : int \| (i == FIRST_IS_LESS_THAN_SECOND \|\| i == FIRST_IS_EQUAL_TO_SECOND \|\| i == FIRST_IS_GREATER_THAN_SECOND)] int i extern fun {a : vt@ype} list_vt_quicksort$comparison (x : !a, y : !a) :<> comparison_result extern fun {a : vt@ype} list_vt_quicksort {n : int} (lst : list_vt (a, n)) :<!wrt> list_vt (a, n) ( - - - - - - - - - - - - - - - - - - - - - - ) implement {a} list_vt_quicksort {n} (lst) = let fun partition {n : nat} .<n>. ( Proof of termination. ) (lst : list_vt (a, n), pivot : !a) :<> [n1, n2, n3 : int \| n1 + n2 + n3 == n] @(list_vt (a, n1), list_vt (a, n2), list_vt (a, n3)) = ( This implementation is not tail recursive. I may get a scolding for using ATS to risk stack overflow! However, I need more practice writing non-tail routines. :) Also, a lot of programmers in other languages would do it this way--especially if the lists are evaluated lazily. ) case+ lst of \| ~ NIL => @(NIL, NIL, NIL) \| ~ head :: tail => let val @(lt, eq, gt) = partition (tail, pivot) prval () = lemma_list_vt_param lt prval () = lemma_list_vt_param eq prval () = lemma_list_vt_param gt in case+ list_vt_quicksort$comparison<a> (head, pivot) of \| FIRST_IS_LESS_THAN_SECOND => @(head :: lt, eq, gt) \| FIRST_IS_EQUAL_TO_SECOND => @(lt, head :: eq, gt) \| FIRST_IS_GREATER_THAN_SECOND => @(lt, eq, head :: gt) end fun quicksort {n : nat} .<n>. ( Proof of termination. ) (lst : list_vt (a, n)) :<!wrt> list_vt (a, n) = case+ lst of \| NIL => lst \| _ :: NIL => lst \| ~ head :: tail => let ( We are careful here to run "partition" on "tail" rather than "lst", so the termination metric will be provably decreasing. (Really the compiler forces us to take such care, or else to add !ntm to the effects.) ) val pivot = head prval () = lemma_list_vt_param tail val @(lt, eq, gt) = partition {n - 1} (tail, pivot) prval () = lemma_list_vt_param lt prval () = lemma_list_vt_param eq prval () = lemma_list_vt_param gt val eq = pivot :: eq and lt = quicksort lt and gt = quicksort gt in list_vt_append (lt, list_vt_append (eq, gt)) end prval () = lemma_list_vt_param lst in quicksort {n} lst end (------------------------------------------------------------------) implement list_vt_quicksort$comparison<Strptr1> (x, y) = let val i = compare (x, y) in if i < 0 then FIRST_IS_LESS_THAN_SECOND else if i = 0 then FIRST_IS_EQUAL_TO_SECOND else FIRST_IS_GREATER_THAN_SECOND end implement list_vt_map$fopr<string><Strptr1> (s) = string0_copy s implement list_vt_freelin$clear<Strptr1> (x) = strptr_free x implement main0 () = let val example_strings = $list_vt ("choose", "any", "element", "of", "the", "array", "to", "be", "the", "pivot", "divide", "all", "other", "elements", "except", "the", "pivot", "into", "two", "partitions", "all", "elements", "less", "than", "the", "pivot", "must", "be", "in", "the", "first", "partition", "all", "elements", "greater", "than", "the", "pivot", "must", "be", "in", "the", "second", "partition", "use", "recursion", "to", "sort", "both", "partitions", "join", "the", "first", "sorted", "partition", "the", "pivot", "and", "the", "second", "sorted", "partition") val example_strptrs = list_vt_map<string><Strptr1> (example_strings) val sorted_strptrs = list_vt_quicksort<Strptr1> example_strptrs fun print_strptrs {n : nat} .<n>. (strptrs : !list_vt (Strptr1, n), i : int) : void = case+ strptrs of \| NIL => if i <> 1 then println! () else () \| @ head :: tail => begin print! head; if i = 8 then begin println! (); print_strptrs (tail, 1) end else begin print! " "; print_strptrs (tail, succ i) end; fold@ strptrs end in println! (length example_strings); println! (length sorted_strptrs); print_strptrs (sorted_strptrs, 1); list_vt_freelin<Strptr1> sorted_strptrs; list_vt_free<string> example_strings end (------------------------------------------------------------------)</syntaxhighlight> {{out}} <pre>$ patscc -O3 -DATS_MEMALLOC_LIBC quicksort_task_for_list_vt.dats && ./a.out 62 62 all all all and any array be be be both choose divide element elements elements elements except first first greater in in into join less must must of other partition partition partition partition partitions partitions pivot pivot pivot pivot pivot recursion second second sort sorted sorted than than the the the the the the the the the the to to two use</pre> === A quicksort working on arrays of non-linear elements === <syntaxhighlight lang="ats">(------------------------------------------------------------------) ( Quicksort in ATS2, for arrays of non-linear values. ) (------------------------------------------------------------------) #include "share/atspre_staload.hats" #define NIL list_nil () #define :: list_cons (------------------------------------------------------------------) ( A simple quicksort working on arrays of non-linear values, using a programmer-selectible pivot. It is based on the "in-place" task pseudocode. ) extern fun {a : t@ype} ( A "less-than" predicate. ) array_quicksort$lt (x : a, y : a) : bool extern fun {a : t@ype} array_quicksort$select_pivot {n : int} {i, j : nat \| i < j; j < n} (arr : &array (a, n) >> _, first : size_t i, last : size_t j) : a extern fun {a : t@ype} array_quicksort {n : int} (arr : &array (a, n) >> _, n : size_t n) : void ( - - - - - - - - - - - - - - - - - - - - - - ) fn {a : t@ype} swap {n : int} {i, j : nat \| i < n; j < n} (arr : &array(a, n) >> _, i : size_t i, j : size_t j) : void = { val x = arr[i] and y = arr[j] val () = (arr[i] := y) and () = (arr[j] := x) } implement {a} array_quicksort {n} (arr, n) = let sortdef index = {i : nat \| i < n} typedef index (i : int) = [0 <= i; i < n] size_t i typedef index = [i : index] index i macdef lt = array_quicksort$lt<a> fun quicksort {i, j : index} (arr : &array(a, n) >> _, first : index i, last : index j) : void = if first < last then { val pivot : a = array_quicksort$select_pivot<a> (arr, first, last) fun search_rightwards (arr : &array (a, n), left : index) : index = if arr[left] \lt pivot then let val () = assertloc (succ left <> n) in search_rightwards (arr, succ left) end else left fun search_leftwards (arr : &array (a, n), left : index, right : index) : index = if right < left then right else if pivot \lt arr[right] then let val () = assertloc (right <> i2sz 0) in search_leftwards (arr, left, pred right) end else right fun partition (arr : &array (a, n) >> _, left0 : index, right0 : index) : @(index, index) = let val left = search_rightwards (arr, left0) val right = search_leftwards (arr, left, right0) in if left <= right then let val () = assertloc (succ left <> n) and () = assertloc (right <> i2sz 0) in swap (arr, left, right); partition (arr, succ left, pred right) end else @(left, right) end val @(left, right) = partition (arr, first, last) val () = quicksort (arr, first, right) and () = quicksort (arr, left, last) } in if i2sz 2 <= n then quicksort {0, n - 1} (arr, i2sz 0, pred n) end (------------------------------------------------------------------) val example_strings = $list ("choose", "any", "element", "of", "the", "array", "to", "be", "the", "pivot", "divide", "all", "other", "elements", "except", "the", "pivot", "into", "two", "partitions", "all", "elements", "less", "than", "the", "pivot", "must", "be", "in", "the", "first", "partition", "all", "elements", "greater", "than", "the", "pivot", "must", "be", "in", "the", "second", "partition", "use", "recursion", "to", "sort", "both", "partitions", "join", "the", "first", "sorted", "partition", "the", "pivot", "and", "the", "second", "sorted", "partition") implement array_quicksort$lt<string> (x, y) = strcmp (x, y) < 0 implement array_quicksort$select_pivot<string> {n} (arr, first, last) = ( Median of three, with swapping around of elements during pivot selection. See https://archive.ph/oYENx ) let macdef lt = array_quicksort$lt<string> val middle = first + ((last - first) / i2sz 2) val xfirst = arr[first] and xmiddle = arr[middle] and xlast = arr[last] in if (xmiddle \lt xfirst) xor (xlast \lt xfirst) then begin swap (arr, first, middle); if xlast \lt xmiddle then swap (arr, first, last); xfirst end else if (xmiddle \lt xfirst) xor (xmiddle \lt xlast) then begin if xlast \lt xfirst then swap (arr, first, last); xmiddle end else begin swap (arr, middle, last); if xmiddle \lt xfirst then swap (arr, first, last); xlast end end implement main0 () = let prval () = lemma_list_param example_strings val n = length example_strings val @(pf, pfgc \| p) = array_ptr_alloc<string> (i2sz n) macdef arr = !p val () = array_initize_list (arr, n, example_strings) val () = array_quicksort<string> (arr, i2sz n) val sorted_strings = list_vt2t (array2list (arr, i2sz n)) val () = array_ptr_free (pf, pfgc \| p) fun print_strings {n : nat} .<n>. (strings : list (string, n), i : int) : void = case+ strings of \| NIL => if i <> 1 then println! () else () \| head :: tail => begin print! head; if i = 8 then begin println! (); print_strings (tail, 1) end else begin print! " "; print_strings (tail, succ i) end end in println! (length example_strings); println! (length sorted_strings); print_strings (sorted_strings, 1) end (------------------------------------------------------------------)</syntaxhighlight> {{out}} <pre>$ patscc -O3 -DATS_MEMALLOC_GCBDW quicksort_task_for_arrays.dats -lgc && ./a.out 62 62 all all all and any array be be be both choose divide element elements elements elements except first first greater in in into join less must must of other partition partition partition partition partitions partitions pivot pivot pivot pivot pivot recursion second second sort sorted sorted than than the the the the the the the the the the to to two use</pre> === A quicksort working on arrays of linear elements === The quicksort for arrays of non-linear elements ''makes a copy'' of the pivot value, and compares this copy with array elements ''by value''. Here, however, the array elements are ''linear'' values. They cannot be copied, unless a special "copy" procedure is provided. We do not want to require such a procedure. So we must do something else. What we do is move the pivot to the last element of the array, by safely swapping it with the original last element. We partition the array to the left of the last element, comparing array elements with the pivot (that is, the last element) ''by reference''. <syntaxhighlight lang="ats">(------------------------------------------------------------------) ( Quicksort in ATS2, for arrays of (possibly) linear values. ) (------------------------------------------------------------------) #include "share/atspre_staload.hats" #define NIL list_vt_nil () #define :: list_vt_cons (------------------------------------------------------------------) ( A simple quicksort working on arrays of non-linear values, using a programmer-selectible pivot. It is based on the "in-place" task pseudocode. ) extern fun {a : vt@ype} ( A "less-than" predicate. ) array_quicksort$lt {px, py : addr} (pfx : !(a @ px), pfy : !(a @ py) \| px : ptr px, py : ptr py) : bool extern fun {a : vt@ype} array_quicksort$select_pivot_index {n : int} {i, j : nat \| i < j; j < n} (arr : &array (a, n), first : size_t i, last : size_t j) : [k : int \| i <= k; k <= j] size_t k extern fun {a : vt@ype} array_quicksort {n : int} (arr : &array (a, n) >> _, n : size_t n) : void ( - - - - - - - - - - - - - - - - - - - - - - ) prfn ( Subdivide an array view into three views. ) array_v_subdivide3 {a : vt@ype} {p : addr} {n1, n2, n3 : nat} (pf : @[a][n1 + n2 + n3] @ p) :<prf> @(@[a][n1] @ p, @[a][n2] @ (p + n1 sizeof a), @[a][n3] @ (p + (n1 + n2) * sizeof a)) = let prval (pf1, pf23) = array_v_split {a} {p} {n1 + n2 + n3} {n1} pf prval (pf2, pf3) = array_v_split {a} {p + n1 * sizeof a} {n2 + n3} {n2} pf23 in @(pf1, pf2, pf3) end prfn (* Join three contiguous array views into one view. ) array_v_join3 {a : vt@ype} {p : addr} {n1, n2, n3 : nat} (pf1 : @[a][n1] @ p, pf2 : @[a][n2] @ (p + n1 sizeof a), pf3 : @[a][n3] @ (p + (n1 + n2) * sizeof a)) :<prf> @[a][n1 + n2 + n3] @ p = let prval pf23 = array_v_unsplit {a} {p + n1 * sizeof a} {n2, n3} (pf2, pf3) prval pf = array_v_unsplit {a} {p} {n1, n2 + n3} (pf1, pf23) in pf end fn {a : vt@ype} (* Safely swap two elements of an array. ) swap_elems_1 {n : int} {i, j : nat \| i <= j; j < n} {p : addr} (pfarr : !array_v(a, p, n) >> _ \| p : ptr p, i : size_t i, j : size_t j) : void = let fn {a : vt@ype} swap {n : int} {i, j : nat \| i < j; j < n} {p : addr} (pfarr : !array_v(a, p, n) >> _ \| p : ptr p, i : size_t i, j : size_t j) : void = { ( Safely swapping linear elements requires that views of those elements be split off from the rest of the array. Why? Because those elements will temporarily be in an uninitialized state. (Actually they will be "?!", but the difference is unimportant here.) Remember, a linear value is consumed by using it. The view for the whole array can be reassembled only after new values have been stored, making the entire array once again initialized. ) prval @(pf1, pf2, pf3) = array_v_subdivide3 {a} {p} {i, j - i, n - j} pfarr prval @(pfi, pf2_) = array_v_uncons pf2 prval @(pfj, pf3_) = array_v_uncons pf3 val pi = ptr_add<a> (p, i) and pj = ptr_add<a> (p, j) val xi = ptr_get<a> (pfi \| pi) and xj = ptr_get<a> (pfj \| pj) val () = ptr_set<a> (pfi \| pi, xj) and () = ptr_set<a> (pfj \| pj, xi) prval pf2 = array_v_cons (pfi, pf2_) prval pf3 = array_v_cons (pfj, pf3_) prval () = pfarr := array_v_join3 (pf1, pf2, pf3) } in if i < j then swap {n} {i, j} {p} (pfarr \| p, i, j) else () ( i = j must be handled specially, due to linear typing.) end fn {a : vt@ype} ( Safely swap two elements of an array. ) swap_elems_2 {n : int} {i, j : nat \| i <= j; j < n} (arr : &array(a, n) >> _, i : size_t i, j : size_t j) : void = swap_elems_1 (view@ arr \| addr@ arr, i, j) overload swap_elems with swap_elems_1 overload swap_elems with swap_elems_2 overload swap with swap_elems fn {a : vt@ype} ( Safely compare two elements of an array. ) lt_elems_1 {n : int} {i, j : nat \| i < n; j < n} {p : addr} (pfarr : !array_v(a, p, n) \| p : ptr p, i : size_t i, j : size_t j) : bool = let fn compare {n : int} {i, j : nat \| i < j; j < n} {p : addr} (pfarr : !array_v(a, p, n) \| p : ptr p, i : size_t i, j : size_t j, gt : bool) : bool = let prval @(pf1, pf2, pf3) = array_v_subdivide3 {a} {p} {i, j - i, n - j} pfarr prval @(pfi, pf2_) = array_v_uncons pf2 prval @(pfj, pf3_) = array_v_uncons pf3 val pi = ptr_add<a> (p, i) and pj = ptr_add<a> (p, j) val retval = if gt then array_quicksort$lt<a> (pfj, pfi \| pj, pi) else array_quicksort$lt<a> (pfi, pfj \| pi, pj) prval pf2 = array_v_cons (pfi, pf2_) prval pf3 = array_v_cons (pfj, pf3_) prval () = pfarr := array_v_join3 (pf1, pf2, pf3) in retval end in if i < j then compare {n} {i, j} {p} (pfarr \| p, i, j, false) else if j < i then compare {n} {j, i} {p} (pfarr \| p, j, i, true) else false end fn {a : vt@ype} ( Safely compare two elements of an array. ) lt_elems_2 {n : int} {i, j : nat \| i < n; j < n} (arr : &array (a, n), i : size_t i, j : size_t j) : bool = lt_elems_1 (view@ arr \| addr@ arr, i, j) overload lt_elems with lt_elems_1 overload lt_elems with lt_elems_2 implement {a} array_quicksort {n} (arr, n) = let sortdef index = {i : nat \| i < n} typedef index (i : int) = [0 <= i; i < n] size_t i typedef index = [i : index] index i macdef lt = array_quicksort$lt<a> fun quicksort {i, j : index} (arr : &array(a, n) >> _, first : index i, last : index j) : void = if first < last then { val pivot = array_quicksort$select_pivot_index<a> (arr, first, last) ( Swap the pivot with the last element. ) val () = swap (arr, pivot, last) val pivot = last fun search_rightwards (arr : &array (a, n), left : index) : index = if lt_elems<a> (arr, left, pivot) then let val () = assertloc (succ left <> n) in search_rightwards (arr, succ left) end else left fun search_leftwards (arr : &array (a, n), left : index, right : index) : index = if right < left then right else if lt_elems<a> (arr, pivot, right) then let val () = assertloc (right <> i2sz 0) in search_leftwards (arr, left, pred right) end else right fun partition (arr : &array (a, n) >> _, left0 : index, right0 : index) : @(index, index) = let val left = search_rightwards (arr, left0) val right = search_leftwards (arr, left, right0) in if left <= right then let val () = assertloc (succ left <> n) and () = assertloc (right <> i2sz 0) in swap (arr, left, right); partition (arr, succ left, pred right) end else @(left, right) end val @(left, right) = partition (arr, first, pred last) val () = quicksort (arr, first, right) and () = quicksort (arr, left, last) } in if i2sz 2 <= n then quicksort {0, n - 1} (arr, i2sz 0, pred n) end (------------------------------------------------------------------) implement array_quicksort$lt<Strptr1> (pfx, pfy \| px, py) = compare (!px, !py) < 0 implement array_quicksort$select_pivot_index<Strptr1> {n} (arr, first, last) = ( Median of three. ) let val middle = first + ((last - first) / i2sz 2) in if lt_elems<Strptr1> (arr, middle, first) xor lt_elems<Strptr1> (arr, last, first) then first else if lt_elems<Strptr1> (arr, middle, first) xor lt_elems<Strptr1> (arr, middle, last) then middle else last end implement list_vt_map$fopr<string><Strptr1> (s) = string0_copy s implement list_vt_freelin$clear<Strptr1> (x) = strptr_free x implement main0 () = let val example_strings = $list_vt ("choose", "any", "element", "of", "the", "array", "to", "be", "the", "pivot", "divide", "all", "other", "elements", "except", "the", "pivot", "into", "two", "partitions", "all", "elements", "less", "than", "the", "pivot", "must", "be", "in", "the", "first", "partition", "all", "elements", "greater", "than", "the", "pivot", "must", "be", "in", "the", "second", "partition", "use", "recursion", "to", "sort", "both", "partitions", "join", "the", "first", "sorted", "partition", "the", "pivot", "and", "the", "second", "sorted", "partition") val example_strptrs = list_vt_map<string><Strptr1> (example_strings) prval () = lemma_list_vt_param example_strptrs val n = length example_strptrs val @(pf, pfgc \| p) = array_ptr_alloc<Strptr1> (i2sz n) macdef arr = !p val () = array_initize_list_vt<Strptr1> (arr, n, example_strptrs) val () = array_quicksort<Strptr1> (arr, i2sz n) val sorted_strptrs = array2list (arr, i2sz n) fun print_strptrs {n : nat} .<n>. (strptrs : !list_vt (Strptr1, n), i : int) : void = case+ strptrs of \| NIL => if i <> 1 then println! () else () \| @ head :: tail => begin print! head; if i = 8 then begin println! (); print_strptrs (tail, 1) end else begin print! " "; print_strptrs (tail, succ i) end; fold@ strptrs end in println! (length example_strings); println! (length sorted_strptrs); print_strptrs (sorted_strptrs, 1); list_vt_freelin<Strptr1> sorted_strptrs; array_ptr_free (pf, pfgc \| p); list_vt_free<string> example_strings end (------------------------------------------------------------------)</syntaxhighlight> {{out}} <pre>$ patscc -O3 -DATS_MEMALLOC_LIBC quicksort_task_for_arrays_2.dats 62 62 all all all and any array be be be both choose divide element elements elements elements except first first greater in in into join less must must of other partition partition partition partition partitions partitions pivot pivot pivot pivot pivot recursion second second sort sorted sorted than than the the the the the the the the the the to to two use</pre> === A ''stable'' quicksort working on linear lists === See the code at [[Quickselect_algorithm#Quickselect_working_on_linear_lists\|the quickselect task]]. {{out}} <pre>$ patscc -O3 -DATS_MEMALLOC_LIBC quickselect_task_for_list_vt.dats && ./a.out quicksort stable sort by first character: duck, deer, dolphin, elephant, earwig, giraffe, pronghorn, wildebeest, woodlouse, whip-poor-will</pre> =={{header\|AutoHotkey}}== Translated from the python example: <syntaxhighlight lang="autohotkey">a := [4, 65, 2, -31, 0, 99, 83, 782, 7] for k, v in QuickSort(a) Out .= "," v MsgBox, % SubStr(Out, 2) return QuickSort(a) { if (a.MaxIndex() <= 1) return a Less := [], Same := [], More := [] Pivot := a[1] for k, v in a { if (v < Pivot) less.Insert(v) else if (v > Pivot) more.Insert(v) else same.Insert(v) } Less := QuickSort(Less) Out := QuickSort(More) if (Same.MaxIndex()) Out.Insert(1, Same) ; insert all values of same at index 1 if (Less.MaxIndex()) Out.Insert(1, Less) ; insert all values of less at index 1 return Out }</syntaxhighlight> Old implementation for AutoHotkey 1.0: <syntaxhighlight lang="autohotkey">MsgBox % quicksort("8,4,9,2,1") quicksort(list) { StringSplit, list, list, `, If (list0 <= 1) Return list pivot := list1 Loop, Parse, list, `, { If (A_LoopField < pivot) less = %less%,%A_LoopField% Else If (A_LoopField > pivot) more = %more%,%A_LoopField% Else pivotlist = %pivotlist%,%A_LoopField% } StringTrimLeft, less, less, 1 StringTrimLeft, more, more, 1 StringTrimLeft, pivotList, pivotList, 1 less := quicksort(less) more := quicksort(more) Return less . pivotList . more }</syntaxhighlight> =={{header\|AWK}}== <~~lang~~syntaxhighlight lang="awk"> # the following qsort implementation extracted from: # Line 395 ⟶ 2,531: } } </syntaxhighlight> ~~</lang>~~ =={{header\|~~AutoHotkey~~BASIC}}== ==={{header\|ANSI BASIC}}=== ~~translated from python example~~ {{works with\|Decimal BASIC}} ~~<lang AutoHotkey>MsgBox % quicksort("8,4,9,2,1")~~ <syntaxhighlight lang="basic"> 100 REM Sorting algorithms/Quicksort 110 DECLARE EXTERNAL SUB QuickSort 120 DIM Arr(0 TO 19) 130 LET A = LBOUND(Arr) 140 LET B = UBOUND(Arr) 150 RANDOMIZE 160 FOR I = A TO B 170 LET Arr(I) = ROUND(INT(RND 99)) 180 NEXT I 190 PRINT "Unsorted:" 200 FOR I = A TO B 210 PRINT USING "## ": Arr(I); 220 NEXT I 230 PRINT 240 PRINT "Sorted:" 250 CALL QuickSort(Arr, A, B) 260 FOR I = A TO B 270 PRINT USING "## ": Arr(I); 280 NEXT I 290 PRINT 300 END 310 REM ** 320 EXTERNAL SUB QuickSort (Arr(), L, R) 330 LET LIndex = L 340 LET RIndex = R 350 IF R > L THEN 360 LET Pivot = INT((L + R) / 2) 370 DO WHILE (LIndex <= Pivot) AND (RIndex >= Pivot) 380 DO WHILE (Arr(LIndex) < Arr(Pivot)) AND (LIndex <= Pivot) 390 LET LIndex = LIndex + 1 400 LOOP 410 DO WHILE (Arr(RIndex) > Arr(Pivot)) AND (RIndex >= Pivot) 420 LET RIndex = RIndex - 1 430 LOOP 440 LET Temp = Arr(LIndex) 450 LET Arr(LIndex) = Arr(RIndex) 460 LET Arr(RIndex) = Temp 470 LET LIndex = LIndex + 1 480 LET RIndex = RIndex - 1 490 IF (LIndex - 1) = Pivot THEN 500 LET RIndex = RIndex + 1 510 LET Pivot = RIndex 520 ELSEIF (RIndex + 1) = Pivot THEN 530 LET LIndex = LIndex - 1 540 LET Pivot = LIndex 550 END IF 560 LOOP 570 CALL QuickSort (Arr, L, Pivot - 1) 580 CALL QuickSort (Arr, Pivot + 1, R) 590 END IF 600 END SUB </syntaxhighlight> {{out}} (example) <pre> Unsorted: 17 79 23 91 28 91 29 58 47 59 8 35 93 23 34 28 35 31 7 25 Sorted: 7 8 17 23 23 25 28 28 29 31 34 35 35 47 58 59 79 91 91 93 </pre> ==={{header\|BBC BASIC}}=== ~~quicksort(list)~~ <syntaxhighlight lang="bbcbasic"> DIM test(9) { test() = 4, 65, 2, -31, 0, 99, 2, 83, 782, 1 ~~StringSplit, list, list, `,~~ PROCquicksort(test(), 0, 10) ~~If (list0 <= 1)~~ FOR i% = 0 TO 9 ~~Return list~~ PRINT test(i%) ; ~~pivot := list1~~ NEXT ~~Loop, Parse, list, `,~~ PRINT { If ~~(A_LoopField~~ ~~< pivot)~~END ~~less = %less%,%A_LoopField%~~ DEF PROCquicksort(a(), s%, n%) ~~Else If (A_LoopField > pivot)~~ ~~more =~~LOCAL ~~%more~~l%, p, r%~~A_LoopField~~, t% IF n% < 2 THEN ENDPROC ~~Else~~ ~~pivotlist~~t% = s%~~pivotlist%,%A_LoopField~~ + n% - 1 l% = s% } r% = t% ~~StringTrimLeft, less, less, 1~~ p = a((l% + r%) DIV 2) ~~StringTrimLeft, more, more, 1~~ REPEAT ~~StringTrimLeft, pivotList, pivotList, 1~~ WHILE a(l%) < p l% += 1 : ENDWHILE ~~less := quicksort(less)~~ WHILE a(r%) > p r% -= 1 : ENDWHILE ~~more := quicksort(more)~~ IF l% <= r% THEN ~~Return less . pivotList . more~~ SWAP a(l%), a(r%) ~~}</lang>~~ l% += 1 r% -= 1 ENDIF UNTIL l% > r% IF s% < r% PROCquicksort(a(), s%, r% - s% + 1) IF l% < t% PROCquicksort(a(), l%, t% - l% + 1 ) ENDPROC</syntaxhighlight> {{out}} <pre> -31 0 1 2 2 4 65 83 99 782 </pre> ==={{header\|~~BASIC~~Chipmunk Basic}}=== {{works with\|Chipmunk Basic\|3.6.4}} {{trans\|Yabasic}} <syntaxhighlight lang="qbasic">100 dim array(15) 110 a = 0 120 b = ubound(array) 130 randomize timer 140 for i = a to b 150 array(i) = rnd(1)1000 160 next i 170 print "unsort "; 180 for i = a to b 190 print using "####";array(i); 200 if i = b then print ""; else print ", "; 210 next i 220 quicksort(array(),a,b) 230 print : print " sort "; 240 for i = a to b 250 print using "####";array(i); 260 if i = b then print ""; else print ", "; 270 next i 280 print 290 end 300 sub quicksort(array(),l,r) 310 size = r-l+1 320 if size < 2 then return 330 i = l 340 j = r 350 pivot = array(l+int(size/2)) 360 rem repeat 370 while array(i) < pivot 380 i = i+1 390 wend 400 while pivot < array(j) 410 j = j-1 420 wend 430 if i <= j then temp = array(i) : array(i) = array(j) : array(j) = temp : i = i+1 : j = j-1 440 if i <= j then goto 360 450 if l < j then quicksort(array(),l,j) 460 if i < r then quicksort(array(),i,r) 470 end sub</syntaxhighlight> ==={{header\|Craft Basic}}=== <syntaxhighlight lang="basic">define size = 10, point = 0, top = 0 define high = 0, low = 0, pivot = 0 dim list[size] dim stack[size] gosub fill gosub sort gosub show end sub fill for i = 0 to size - 1 let list[i] = int(rnd 100) next i return sub sort let low = 0 let high = size - 1 let top = -1 let top = top + 1 let stack[top] = low let top = top + 1 let stack[top] = high do if top < 0 then break endif let high = stack[top] let top = top - 1 let low = stack[top] let top = top - 1 let i = low - 1 for j = low to high - 1 if list[j] <= list[high] then let i = i + 1 let t = list[i] let list[i] = list[j] let list[j] = t endif next j let point = i + 1 let t = list[point] let list[point] = list[high] let list[high] = t let pivot = i + 1 if pivot - 1 > low then let top = top + 1 let stack[top] = low let top = top + 1 let stack[top] = pivot - 1 endif if pivot + 1 < high then let top = top + 1 let stack[top] = pivot + 1 let top = top + 1 let stack[top] = high endif wait loop top >= 0 return sub show for i = 0 to size - 1 print i, ": ", list[i] next i return</syntaxhighlight> ==={{header\|FreeBASIC}}=== <syntaxhighlight lang="freebasic">' version 23-10-2016 ' compile with: fbc -s console ' sort from lower bound to the highter bound ' array's can have subscript range from -2147483648 to +2147483647 Sub quicksort(qs() As Long, l As Long, r As Long) Dim As ULong size = r - l +1 If size < 2 Then Exit Sub Dim As Long i = l, j = r Dim As Long pivot = qs(l + size \ 2) Do While qs(i) < pivot i += 1 Wend While pivot < qs(j) j -= 1 Wend If i <= j Then Swap qs(i), qs(j) i += 1 j -= 1 End If Loop Until i > j If l < j Then quicksort(qs(), l, j) If i < r Then quicksort(qs(), i, r) End Sub ' ------=< MAIN >=------ Dim As Long i, array(-7 To 7) Dim As Long a = LBound(array), b = UBound(array) Randomize Timer For i = a To b : array(i) = i : Next For i = a To b ' little shuffle Swap array(i), array(Int(Rnd * (b - a +1)) + a) Next Print "unsorted "; For i = a To b : Print Using "####"; array(i); : Next : Print quicksort(array(), LBound(array), UBound(array)) Print " sorted "; For i = a To b : Print Using "####"; array(i); : Next : Print ' empty keyboard buffer While Inkey <> "" : Wend Print : Print "hit any key to end program" Sleep End</syntaxhighlight> {{out}} <pre>unsorted -5 -6 -1 0 2 -4 -7 6 -2 -3 4 7 5 1 3 sorted -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7</pre> ==={{header\|FutureBasic}}=== <syntaxhighlight lang="futurebasic"> include "NSLog.incl" local fn Quicksort( qs as CFMutableArrayRef, l as NSInteger, r as NSInteger ) UInt64 size = r - l + 1 if size < 2 then exit fn NSinteger i = l, j = r NSinteger pivot = fn NumberIntegerValue( qs[l+size / 2] ) do while fn NumberIntegerValue( qs[i] ) < pivot i++ wend while pivot < fn NumberIntegerValue( qs[j] ) j-- wend if ( i <= j ) MutableArrayExchangeObjects( qs, i, j ) i++ j-- end if until i > j if l < j then fn Quicksort( qs, l, j ) if i < r then fn Quicksort( qs, i, r ) end fn CFMutableArrayRef qs CFArrayRef unsorted NSUInteger i, amount qs = fn MutableArrayWithCapacity(0) for i = 0 to 25 if i mod 2 == 0 then amount = 100 else amount = 10000 MutableArrayInsertObjectAtIndex( qs, fn NumberWithInteger( rnd(amount) ), i ) next unsorted = fn ArrayWithArray( qs ) fn QuickSort( qs, 0, len(qs) - 1 ) NSLog( @"\n-----------------\nUnsorted : Sorted\n-----------------" ) for i = 0 to 25 NSLog( @"%8ld : %-8ld", fn NumberIntegerValue( unsorted[i] ), fn NumberIntegerValue( qs[i] ) ) next randomize HandleEvents </syntaxhighlight> {{output}} <pre> ----------------- Unsorted : Sorted ----------------- 97 : 5 6168 : 30 61 : 34 8847 : 40 55 : 46 2570 : 49 40 : 55 4676 : 61 94 : 62 693 : 67 62 : 79 3419 : 94 30 : 97 936 : 693 5 : 733 9910 : 936 67 : 1395 8460 : 1796 79 : 2570 9352 : 3419 49 : 4676 1395 : 6168 34 : 8460 733 : 8847 46 : 9352 1796 : 9910 </pre> ==={{header\|IS-BASIC}}=== <syntaxhighlight lang="is-basic">100 PROGRAM "QuickSrt.bas" 110 RANDOMIZE 120 NUMERIC A(5 TO 19) 130 CALL INIT(A) 140 CALL WRITE(A) 150 CALL QSORT(LBOUND(A),UBOUND(A)) 160 CALL WRITE(A) 170 DEF INIT(REF A) 180 FOR I=LBOUND(A) TO UBOUND(A) 190 LET A(I)=RND(98)+1 200 NEXT 210 END DEF 220 DEF WRITE(REF A) 230 FOR I=LBOUND(A) TO UBOUND(A) 240 PRINT A(I); 250 NEXT 260 PRINT 270 END DEF 280 DEF QSORT(AH,FH) 290 NUMERIC E 300 LET E=AH:LET U=FH:LET K=A(E) 310 DO UNTIL E=U 320 DO UNTIL E=U OR A(U)<K 330 LET U=U-1 340 LOOP 350 IF E<U THEN 360 LET A(E)=A(U):LET E=E+1 370 DO UNTIL E=U OR A(E)>K 380 LET E=E+1 390 LOOP 400 IF E<U THEN LET A(U)=A(E):LET U=U-1 410 END IF 420 LOOP 430 LET A(E)=K 440 IF AH<E-1 THEN CALL QSORT(AH,E-1) 450 IF E+1<FH THEN CALL QSORT(E+1,FH) 460 END DEF</syntaxhighlight> ==={{header\|PureBasic}}=== <syntaxhighlight lang="purebasic">Procedure qSort(Array a(1), firstIndex, lastIndex) Protected low, high, pivotValue low = firstIndex high = lastIndex pivotValue = a((firstIndex + lastIndex) / 2) Repeat While a(low) < pivotValue low + 1 Wend While a(high) > pivotValue high - 1 Wend If low <= high Swap a(low), a(high) low + 1 high - 1 EndIf Until low > high If firstIndex < high qSort(a(), firstIndex, high) EndIf If low < lastIndex qSort(a(), low, lastIndex) EndIf EndProcedure Procedure quickSort(Array a(1)) qSort(a(),0,ArraySize(a())) EndProcedure</syntaxhighlight> ==={{header\|QB64}}=== <syntaxhighlight lang="qb64"> ' Written by Sanmayce, 2021-Oct-29 ' The indexes are signed, but the elements are unsigned. _Define A-Z As _INTEGER64 Sub Quicksort_QB64 (QWORDS~&&()) Left = LBound(QWORDS~&&) Right = UBound(QWORDS~&&) LeftMargin = Left ReDim Stack&&(Left To Right) StackPtr = 0 StackPtr = StackPtr + 1 Stack&&(StackPtr + LeftMargin) = Left StackPtr = StackPtr + 1 Stack&&(StackPtr + LeftMargin) = Right Do 'Until StackPtr = 0 Right = Stack&&(StackPtr + LeftMargin) StackPtr = StackPtr - 1 Left = Stack&&(StackPtr + LeftMargin) StackPtr = StackPtr - 1 Do 'Until Left >= Right Pivot~&& = QWORDS~&&((Left + Right) \ 2) Indx = Left Jndx = Right Do Do While (QWORDS~&&(Indx) < Pivot~&&) Indx = Indx + 1 Loop Do While (QWORDS~&&(Jndx) > Pivot~&&) Jndx = Jndx - 1 Loop If Indx <= Jndx Then If Indx < Jndx Then Swap QWORDS~&&(Indx), QWORDS~&&(Jndx) Indx = Indx + 1 Jndx = Jndx - 1 End If Loop While Indx <= Jndx If Indx < Right Then StackPtr = StackPtr + 1 Stack&&(StackPtr + LeftMargin) = Indx StackPtr = StackPtr + 1 Stack&&(StackPtr + LeftMargin) = Right End If Right = Jndx Loop Until Left >= Right Loop Until StackPtr = 0 End Sub</syntaxhighlight> ==={{header\|QuickBASIC}}=== {{works with\|FreeBASIC}} {{works with\|PowerBASIC for DOS}} Line 432 ⟶ 3,058: This is specifically for <code>INTEGER</code>s, but can be modified for any data type by changing <code>arr()</code>'s type. <~~lang~~syntaxhighlight lang="qbasic">DECLARE SUB quicksort (arr() AS INTEGER, leftN AS INTEGER, rightN AS INTEGER) DIM q(99) AS INTEGER Line 481 ⟶ 3,107: quicksort arr(), pivot + 1, rightN END IF END SUB</~~lang~~syntaxhighlight> ==={{header\|~~BBC~~Run BASIC}}=== <syntaxhighlight lang="runbasic">' ------------------------------- ~~<lang bbcbasic> DIM test(9)~~ ' quick sort ~~test() = 4, 65, 2, -31, 0, 99, 2, 83, 782, 1~~ ' ------------------------------- ~~PROCquicksort(test(), 0, 10)~~ size = 50 ~~FOR i% = 0 TO 9~~ dim s(size) ' array to sort ~~PRINT test(i%) ;~~ for i = 1 to size ' fill it with some random numbers ~~NEXT~~ s(i) = rnd(0) * 100 ~~PRINT~~ next i ~~END~~ lft = 1 ~~DEF PROCquicksort(a(), s%, n%)~~ rht = size ~~LOCAL l%, p, r%, t%~~ ~~IF n% < 2 THEN ENDPROC~~ [qSort] ~~t% = s% + n% - 1~~ l%lftHold = s%lft r%rhtHold = t%rht pivot p = as(~~(l% + r%) DIV 2~~lft) while lft < ~~REPEAT~~rht while (s(rht) >= pivot) ~~WHILE~~and a(~~l%)~~lft < prht) l%: rht += rht - 1 : ~~ENDWHILE~~wend if lft <> rht then ~~WHILE a(r%) > p r% -= 1 : ENDWHILE~~ s(lft) ~~IF l% <~~= ~~r% THEN~~s(rht) lft ~~SWAP~~= ~~a(l%),~~lft ~~a(r%)~~+ 1 end ~~l% += 1~~if while (s(lft) <= pivot) and (lft r%< rht) : lft -= lft + 1 :wend if lft <> rht ~~ENDIF~~then ~~UNTIL~~s(rht) l%= ~~> r%~~s(lft) IFrht s% < r% ~~PROCquicksort(a(),~~= ~~s%, r%~~rht - ~~s% +~~ 1) end if ~~IF l% < t% PROCquicksort(a(), l%, t% - l% + 1 )~~ wend ~~ENDPROC</lang>~~ ~~'''Output:'''~~ s(lft) = pivot pivot = lft lft = lftHold rht = rhtHold if lft < pivot then rht = pivot - 1 goto [qSort] end if if rht > pivot then lft = pivot + 1 goto [qSort] end if for i = 1 to size print i;"-->";s(i) next i</syntaxhighlight> ==={{header\|True BASIC}}=== <syntaxhighlight lang="qbasic">SUB quicksort (arr(), l, r) LET lidx = round(l) LET ridx = round(r) IF (r-l) > 0 THEN LET pivot = round((l+r)/2) DO WHILE (lidx <= pivot) AND (ridx >= pivot) DO WHILE (arr(lidx) < arr(pivot)) AND (lidx <= pivot) LET lidx = lidx+1 LOOP DO WHILE (arr(ridx) > arr(pivot)) AND (ridx >= pivot) LET ridx = ridx-1 LOOP LET temp = arr(lidx) LET arr(lidx) = arr(ridx) LET arr(ridx) = temp LET lidx = lidx+1 LET ridx = ridx-1 IF (lidx-1) = pivot THEN LET ridx = ridx+1 LET pivot = ridx ELSEIF (ridx+1) = pivot THEN LET lidx = lidx-1 LET pivot = lidx END IF LOOP CALL quicksort (arr(), l, pivot-1) CALL quicksort (arr(), pivot+1, r) END IF END SUB DIM arr(15) LET a = round(LBOUND(arr)) LET b = round(UBOUND(arr)) RANDOMIZE FOR n = a TO b LET arr(n) = round(INT(RND99)) NEXT n PRINT "unsort "; FOR n = a TO b PRINT arr(n); " "; NEXT n PRINT PRINT " sort "; CALL quicksort (arr(), a, b) FOR n = a TO b PRINT arr(n); " "; NEXT n END</syntaxhighlight> ==={{header\|uBasic/4tH}}=== <syntaxhighlight lang="text">PRINT "Quick sort:" n = FUNC (_InitArray) PROC _ShowArray (n) PROC _Quicksort (n) PROC _ShowArray (n) PRINT END _InnerQuick PARAM(2) LOCAL(4) IF b@ < 2 THEN RETURN f@ = a@ + b@ - 1 c@ = a@ e@ = f@ d@ = @((c@ + e@) / 2) DO DO WHILE @(c@) < d@ c@ = c@ + 1 LOOP DO WHILE @(e@) > d@ e@ = e@ - 1 LOOP IF c@ - 1 < e@ THEN PROC _Swap (c@, e@) c@ = c@ + 1 e@ = e@ - 1 ENDIF UNTIL c@ > e@ LOOP IF a@ < e@ THEN PROC _InnerQuick (a@, e@ - a@ + 1) IF c@ < f@ THEN PROC _InnerQuick (c@, f@ - c@ + 1) RETURN _Quicksort PARAM(1) ' Quick sort PROC _InnerQuick (0, a@) RETURN _Swap PARAM(2) ' Swap two array elements PUSH @(a@) @(a@) = @(b@) @(b@) = POP() RETURN _InitArray ' Init example array PUSH 4, 65, 2, -31, 0, 99, 2, 83, 782, 1 FOR i = 0 TO 9 @(i) = POP() NEXT RETURN (i) _ShowArray PARAM (1) ' Show array subroutine FOR i = 0 TO a@-1 PRINT @(i), NEXT PRINT RETURN</syntaxhighlight> ==={{header\|VBA}}=== This is the "simple" quicksort, using temporary arrays. <syntaxhighlight lang="vb">Public Sub Quick(a() As Variant, last As Integer) ' quicksort a Variant array (1-based, numbers or strings) Dim aLess() As Variant Dim aEq() As Variant Dim aGreater() As Variant Dim pivot As Variant Dim naLess As Integer Dim naEq As Integer Dim naGreater As Integer If last > 1 Then 'choose pivot in the middle of the array pivot = a(Int((last + 1) / 2)) 'construct arrays naLess = 0 naEq = 0 naGreater = 0 For Each el In a() If el > pivot Then naGreater = naGreater + 1 ReDim Preserve aGreater(1 To naGreater) aGreater(naGreater) = el ElseIf el < pivot Then naLess = naLess + 1 ReDim Preserve aLess(1 To naLess) aLess(naLess) = el Else naEq = naEq + 1 ReDim Preserve aEq(1 To naEq) aEq(naEq) = el End If Next 'sort arrays "less" and "greater" Quick aLess(), naLess Quick aGreater(), naGreater 'concatenate P = 1 For i = 1 To naLess a(P) = aLess(i): P = P + 1 Next For i = 1 To naEq a(P) = aEq(i): P = P + 1 Next For i = 1 To naGreater a(P) = aGreater(i): P = P + 1 Next End If End Sub Public Sub QuicksortTest() Dim a(1 To 26) As Variant 'populate a with numbers in descending order, then sort For i = 1 To 26: a(i) = 26 - i: Next Quick a(), 26 For i = 1 To 26: Debug.Print a(i);: Next Debug.Print 'now populate a with strings in descending order, then sort For i = 1 To 26: a(i) = Chr$(Asc("z") + 1 - i) & "-stuff": Next Quick a(), 26 For i = 1 To 26: Debug.Print a(i); " ";: Next Debug.Print End Sub</syntaxhighlight> {{out}} <pre>quicksorttest 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 a-stuff b-stuff c-stuff d-stuff e-stuff f-stuff g-stuff h-stuff i-stuff j-stuff k-stuff l-stuff m-stuff n-stuff o-stuff p-stuff q-stuff r-stuff s-stuff t-stuff u-stuff v-stuff w-stuff x-stuff y-stuff z-stuff </pre> Note: the "quicksort in place" ==={{header\|VBScript}}=== {{trans\|BBC BASIC}} <syntaxhighlight lang="vb">Function quicksort(arr,s,n) If n < 2 Then Exit Function End If t = s + n - 1 l = s r = t p = arr(Int((l + r)/2)) Do Until l > r Do While arr(l) < p l = l + 1 Loop Do While arr(r) > p r = r -1 Loop If l <= r Then tmp = arr(l) arr(l) = arr(r) arr(r) = tmp l = l + 1 r = r - 1 End If Loop If s < r Then Call quicksort(arr,s,r-s+1) End If If l < t Then Call quicksort(arr,l,t-l+1) End If quicksort = arr End Function myarray=Array(9,8,7,6,5,5,4,3,2,1,0,-1) m = quicksort(myarray,0,12) WScript.Echo Join(m,",")</syntaxhighlight> {{out}} <pre>-1,0,1,2,3,4,5,5,6,7,8,9</pre> ==={{header\|Visual Basic}}=== {{works with\|Visual Basic\|5}} {{works with\|Visual Basic\|6}} QuickSort without swapping <syntaxhighlight lang="vb">Sub QuickSort(arr() As Integer, ByVal f As Integer, ByVal l As Integer) i = f 'First j = l 'Last Key = arr(i) 'Pivot Do While i < j Do While i < j And Key < arr(j) j = j - 1 Loop If i < j Then arr(i) = arr(j): i = i + 1 Do While i < j And Key > arr(i) i = i + 1 Loop If i < j Then arr(j) = arr(i): j = j - 1 Loop arr(i) = Key If i - 1 > f Then QuickSort arr(), f, i - 1 If j + 1 < l Then QuickSort arr(), j + 1, l End Sub</syntaxhighlight> ==={{header\|XBasic}}=== {{trans\|ANSI BASIC\|Added functions for generating pseudorandom numbers.}} '''Note.''' XBasic has also a standard function <code>XstQuickSort</code> in the ''xst'' library. {{works with\|Windows XBasic}} <syntaxhighlight lang="basic"> ' Sorting algorithms/Quicksort PROGRAM "quicksort" VERSION "1.0" IMPORT "xst" DECLARE FUNCTION Entry () DECLARE FUNCTION QuickSort (@arr%[], l%%, r%%) ' Pseudo-random number generator ' Based on the rand, srand functions from Kernighan & Ritchie's book ' 'The C Programming Language' DECLARE FUNCTION Rand() DECLARE FUNCTION SRand(seed%%) FUNCTION Entry () DIM arr%[19] a%% = 0 b%% = UBOUND(arr%[]) XstGetSystemTime (@msec) SRand(INT(msec) MOD 32768) FOR i%% = a%% TO b%% arr%[i%%] = INT(Rand() / 32768.0 99.0) NEXT i%% PRINT "Unsorted:" FOR i%% = a%% TO b%% PRINT FORMAT$("## ", arr%[i%%]); NEXT i%% PRINT PRINT "Sorted:" QuickSort(@arr%[], a%%, b%%) FOR i%% = a%% TO b%% PRINT FORMAT$("## ", arr%[i%%]); NEXT i%% PRINT END FUNCTION FUNCTION QuickSort (@arr%[], l%%, r%%) leftIndex%% = l%% rightIndex%% = r%% IF r%% > l%% THEN pivot%% = (l%% + r%%) \ 2 DO WHILE (leftIndex%% <= pivot%%) AND (rightIndex%% >= pivot%%) DO WHILE (arr%[leftIndex%%] < arr%[pivot%%]) AND (leftIndex%% <= pivot%%) INC leftIndex%% LOOP DO WHILE (arr%[rightIndex%%] > arr%[pivot%%]) AND (rightIndex%% >= pivot%%) DEC rightIndex%% LOOP SWAP arr%[leftIndex%%], arr%[rightIndex%%] INC leftIndex%% DEC rightIndex%% SELECT CASE TRUE CASE leftIndex%% - 1 = pivot%%: INC rightIndex%% pivot%% = rightIndex%% CASE rightIndex%% + 1 = pivot%%: DEC leftIndex%% pivot%% = leftIndex%% END SELECT LOOP QuickSort (@arr%[], l%%, pivot%% - 1) QuickSort (@arr%[], pivot%% + 1, r%%) END IF END FUNCTION ' Return pseudo-random integer on 0..32767 FUNCTION Rand() #next&& = #next&& * 1103515245 + 12345 END FUNCTION USHORT(#next&& / 65536) MOD 32768 ' Set seed for Rand() FUNCTION SRand(seed%%) #next&& = seed%% END FUNCTION END PROGRAM </syntaxhighlight> {{out}} (example) <pre> Unsorted: ~~-31 0 1 2 2 4 65 83 99 782~~ 18 37 79 14 23 13 64 37 84 37 22 64 25 43 26 13 12 83 21 41 Sorted: 12 13 13 14 18 21 22 23 25 26 37 37 37 41 43 64 64 79 83 84 </pre> ==={{header\|Yabasic}}=== Rosetta Code problem: https://rosettacode.org/wiki/Sorting_algorithms/Quicksort by Jjuanhdez, 03/2023 <syntaxhighlight lang="basic">dim array(15) a = 0 b = arraysize(array(),1) for i = a to b array(i) = ran(1000) next i print "unsort "; for i = a to b print array(i) using("####"); if i = b then print ""; else print ", "; : fi next i quickSort(array(), a, b) print "\n sort "; for i = a to b print array(i) using("####"); if i = b then print ""; else print ", "; : fi next i print end sub quickSort(array(), l, r) local asize, i, j, pivot size = r - l +1 if size < 2 return i = l j = r pivot = array(l + int(size / 2)) repeat while array(i) < pivot i = i + 1 wend while pivot < array(j) j = j - 1 wend if i <= j then temp = array(i) array(i) = array(j) array(j) = temp i = i + 1 j = j - 1 fi until i > j if l < j quickSort(array(), l, j) if i < r quickSort(array(), i, r) end sub</syntaxhighlight> {{out}} <pre>unsort 582, 796, 598, 478, 27, 125, 477, 679, 133, 513, 154, 93, 451, 463, 20 sort 20, 27, 93, 125, 133, 154, 451, 463, 477, 478, 513, 582, 598, 679, 796 </pre> =={{header\|BCPL}}== <~~lang~~syntaxhighlight ~~BCPL~~lang="bcpl">// This can be run using Cintcode BCPL freely available from www.cl.cam.ac.uk/users/mr10. GET "libhdr.h" Line 570 ⟶ 3,624: } newline() }</~~lang~~syntaxhighlight> =={{header\|Beads}}== <syntaxhighlight lang="beads">beads 1 program Quicksort calc main_init var arr = [1, 3, 5, 1, 7, 9, 8, 6, 4, 2] var arr2 = arr quicksort(arr, 1, tree_count(arr)) var tempStr : str loop across:arr index:ix tempStr = tempStr & ' ' & to_str(arr[ix]) log tempStr calc quicksort( arr:array of num startIndex highIndex ) if (startIndex < highIndex) var partitionIndex = partition(arr, startIndex, highIndex) quicksort(arr, startIndex, partitionIndex - 1) quicksort(arr, partitionIndex+1, highIndex) calc partition( arr:array of num startIndex highIndex ):num var pivot = arr[highIndex] var i = startIndex - 1 var j = startIndex loop while:(j <= highIndex - 1) if arr[j] < pivot inc i swap arr[i] <=> arr[j] inc j swap arr[i+1] <=> arr[highIndex] return (i+1) </syntaxhighlight> {{out}} 1 1 2 3 4 5 6 7 8 9 =={{header\|Bracmat}}== Instead of comparing elements explicitly, this solution puts the two elements-to-compare in a sum. After evaluating the sum its terms are sorted. Numbers are sorted numerically, strings alphabetically and compound expressions by comparing nodes and leafs in a left-to right order. Now there are three cases: either the terms stayed put, or they were swapped, or they were equal and were combined into one term with a factor <code>2</code> in front. To not let the evaluator add numbers together, each term is constructed as a dotted list. <syntaxhighlight lang="bracmat">( ( Q = Less Greater Equal pivot element . !arg:%(?pivot:?Equal) %?arg & :?Less:?Greater & whl ' ( !arg:%?element ?arg & (.!element)+(.!pivot) { BAD: 1900+90 adds to 1990, GOOD: (.1900)+(.90) is sorted to (.90)+(.1900) } : ( (.!element)+(.!pivot) & !element !Less:?Less \| (.!pivot)+(.!element) & !element !Greater:?Greater \| ?&!element !Equal:?Equal ) ) & Q$!Less !Equal Q$!Greater \| !arg ) & out$Q$(1900 optimized variants of 4001/2 Quicksort (quick,sort) are (quick,sober) features of 90 languages) );</syntaxhighlight> {{out}} <pre> 90 1900 4001/2 Quicksort are features languages of of optimized variants (quick,sober) (quick,sort)</pre> =={{header\|Bruijn}}== <syntaxhighlight lang="bruijn"> :import std/Combinator . :import std/Number . :import std/List . sort y [[0 [[[case-sort]]] case-end]] case-sort (4 lesser) ++ (2 : (4 greater)) lesser (\lt? 2) <#> 1 greater (\ge? 2) <#> 1 case-end empty :test (sort ((+3) : ((+2) : {}(+1)))) ((+1) : ((+2) : {}(+3))) </syntaxhighlight> =={{header\|C}}== <syntaxhighlight lang="c"> ~~<lang c>~~ #include <stdio.h> ~~void quick_sort (int a, int n) {~~ ~~if (n < 2)~~ void quicksort(int A, int len); ~~return;~~ ~~int p = a[n / 2];~~ int lmain =(void) a;{ int ra[] = a{4, +65, n2, -31, 0, 99, 2, 83, 782, 1}; int n ~~while~~= (lsizeof <=a / r)sizeof {a[0]; ~~if (l < p) {~~ int ~~l++~~i; for (i = 0; i < n; i++) ~~continue;~~{ printf("%d ", a[i]); } printf("\n"); quicksort(a, n); for (i = 0; i < n; i++) { printf("%d ", a[i]); } printf("\n"); return 0; } void quicksort(int A, int len) { if (len < 2) return; int pivot = A[len / 2]; int i, j; for (i = 0, j = len - 1; ; i++, j--) { while (A[i] < pivot) i++; while (A[j] > pivot) j--; if (i >= j) break; int temp = A[i]; A[i] = A[j]; A[j] = temp; } quicksort(A, i); quicksort(A + i, len - i); } </syntaxhighlight> {{out}} <pre> 4 65 2 -31 0 99 2 83 782 1 -31 0 1 2 2 4 65 83 99 782 </pre> Randomized sort with separated components. <syntaxhighlight lang="c"> #include <stdlib.h> // REQ: rand() void swap(int a, int b) { int c = a; a = b; b = c; } int partition(int A[], int p, int q) { swap(&A[p + (rand() % (q - p + 1))], &A[q]); // PIVOT = A[q] int i = p - 1; for(int j = p; j <= q; j++) { if(A[j] <= A[q]) { swap(&A[++i], &A[j]); } } return i; } void quicksort(int A[], int p, int q) { if(p < q) { int pivotIndx = partition(A, p, q); quicksort(A, p, pivotIndx - 1); quicksort(A, pivotIndx + 1, q); } } </syntaxhighlight> =={{header\|C sharp\|C#}}== <syntaxhighlight lang="csharp">// // The Tripartite conditional enables Bentley-McIlroy 3-way Partitioning. // This performs additional compares to isolate islands of keys equal to // the pivot value. Use unless key-equivalent classes are of small size. // #define Tripartite namespace RosettaCode { using System; using System.Diagnostics; public class QuickSort<T> where T : IComparable { #region Constants public const UInt32 INSERTION_LIMIT_DEFAULT = 12; private const Int32 SAMPLES_MAX = 19; #endregion #region Properties public UInt32 InsertionLimit { get; } private T[] Samples { get; } private Int32 Left { get; set; } private Int32 Right { get; set; } private Int32 LeftMedian { get; set; } private Int32 RightMedian { get; set; } #endregion #region Constructors public QuickSort(UInt32 insertionLimit = INSERTION_LIMIT_DEFAULT) { this.InsertionLimit = insertionLimit; this.Samples = new T[SAMPLES_MAX]; } #endregion #region Sort Methods public void Sort(T[] entries) { Sort(entries, 0, entries.Length - 1); } public void Sort(T[] entries, Int32 first, Int32 last) { var length = last + 1 - first; while (length > 1) { if (length < InsertionLimit) { InsertionSort<T>.Sort(entries, first, last); return; } ~~if (r > p) {~~ Left = ~~r--~~first; Right = last; ~~continue; // we need to check the condition (l <= r) every time we change the value of l or r~~ var median = pivot(entries); partition(median, entries); //[Note]Right < Left var leftLength = Right + 1 - first; var rightLength = last + 1 - Left; // // First recurse over shorter partition, then loop // on the longer partition to elide tail recursion. // if (leftLength < rightLength) { Sort(entries, first, Right); first = Left; length = rightLength; } ~~int~~else ~~t = l;~~{ l++ = rSort(entries, Left, last); r-- last = tRight; length = leftLength; } } } ~~quick_sort(a, r - a + 1);~~ /// <summary>Return an odd sample size proportional to the log of a large interval size.</summary> ~~quick_sort(l, a + n - l);~~ private static Int32 sampleSize(Int32 length, Int32 max = SAMPLES_MAX) { var logLen = (Int32)Math.Log10(length); var samples = Math.Min(2 logLen + 1, max); return Math.Min(samples, length); } /// <summary>Estimate the median value of entries[Left:Right]</summary> /// <remarks>A sample median is used as an estimate the true median.</remarks> private T pivot(T[] entries) { var length = Right + 1 - Left; var samples = sampleSize(length); // Sample Linearly: for (var sample = 0; sample < samples; sample++) { // Guard against Arithmetic Overflow: var index = (Int64)length * sample / samples + Left; Samples[sample] = entries[index]; } InsertionSort<T>.Sort(Samples, 0, samples - 1); return Samples[samples / 2]; } private void partition(T median, T[] entries) { var first = Left; var last = Right; #if Tripartite LeftMedian = first; RightMedian = last; #endif while (true) { //[Assert]There exists some index >= Left where entries[index] >= median //[Assert]There exists some index <= Right where entries[index] <= median // So, there is no need for Left or Right bound checks while (median.CompareTo(entries[Left]) > 0) Left++; while (median.CompareTo(entries[Right]) < 0) Right--; //[Assert]entries[Right] <= median <= entries[Left] if (Right <= Left) break; Swap(entries, Left, Right); swapOut(median, entries); Left++; Right--; //[Assert]entries[first:Left - 1] <= median <= entries[Right + 1:last] } if (Left == Right) { Left++; Right--; } //[Assert]Right < Left swapIn(entries, first, last); //[Assert]entries[first:Right] <= median <= entries[Left:last] //[Assert]entries[Right + 1:Left - 1] == median when non-empty } #endregion #region Swap Methods [Conditional("Tripartite")] private void swapOut(T median, T[] entries) { if (median.CompareTo(entries[Left]) == 0) Swap(entries, LeftMedian++, Left); if (median.CompareTo(entries[Right]) == 0) Swap(entries, Right, RightMedian--); } [Conditional("Tripartite")] private void swapIn(T[] entries, Int32 first, Int32 last) { // Restore Median entries while (first < LeftMedian) Swap(entries, first++, Right--); while (RightMedian < last) Swap(entries, Left++, last--); } /// <summary>Swap entries at the left and right indicies.</summary> public void Swap(T[] entries, Int32 left, Int32 right) { Swap(ref entries[left], ref entries[right]); } /// <summary>Swap two entities of type T.</summary> public static void Swap(ref T e1, ref T e2) { var e = e1; e1 = e2; e2 = e; } #endregion } #region Insertion Sort static class InsertionSort<T> where T : IComparable { public static void Sort(T[] entries, Int32 first, Int32 last) { for (var next = first + 1; next <= last; next++) insert(entries, first, next); } /// <summary>Bubble next entry up to its sorted location, assuming entries[first:next - 1] are already sorted.</summary> private static void insert(T[] entries, Int32 first, Int32 next) { var entry = entries[next]; while (next > first && entries[next - 1].CompareTo(entry) > 0) entries[next] = entries[--next]; entries[next] = entry; } } #endregion }</syntaxhighlight> '''Example''': <syntaxhighlight lang="csharp"> using Sort; using System; class Program { static void Main(String[] args) { var entries = new Int32[] { 1, 3, 5, 7, 9, 8, 6, 4, 2 }; var sorter = new QuickSort<Int32>(); sorter.Sort(entries); Console.WriteLine(String.Join(" ", entries)); } }</syntaxhighlight> {{out}} <pre>1 2 3 4 5 6 7 8 9</pre> A very inefficient way to do qsort in C# to prove C# code can be just as compact and readable as any dynamic code <syntaxhighlight lang="csharp">using System; using System.Collections.Generic; using System.Linq; namespace QSort { class QSorter { private static IEnumerable<IComparable> empty = new List<IComparable>(); public static IEnumerable<IComparable> QSort(IEnumerable<IComparable> iEnumerable) { if(iEnumerable.Any()) { var pivot = iEnumerable.First(); return QSort(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) > 0)). Concat(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) == 0)). Concat(QSort(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) < 0))); } return empty; } } }</syntaxhighlight> =={{header\|CafeOBJ}}== There is no builtin list type in CafeOBJ, so a user written list module is included. <syntaxhighlight lang="$CafeOBJ"> mod! SIMPLE-LIST(X :: TRIV){ [NeList < List ] op [] : -> List op [_] : Elt -> List op (_:_) : Elt List -> NeList -- consr op _++_ : List List -> List {assoc} -- concatenate var E : Elt vars L L' : List eq [ E ] = E : [] . eq [] ++ L = L . eq (E : L) ++ L' = E : (L ++ L') . } mod! QUICKSORT{ ~~int main () {~~ pr(SIMPLE-LIST(NAT)) ~~int a[] = {4, 65, 2, -31, 0, 99, 2, 83, 782, 1};~~ op qsort_ : List -> List ~~int n = sizeof a / sizeof a[0];~~ op smaller__ : List Nat -> List ~~quick_sort(a, n);~~ op larger__ : List Nat -> List ~~return 0;~~ vars x y : Nat vars xs ys : List eq qsort [] = [] . eq qsort (x : xs) = (qsort (smaller xs x)) ++ [ x ] ++ (qsort (larger xs x)) . eq smaller [] x = [] . eq smaller (x : xs) y = if x <= y then (x : (smaller xs y)) else (smaller xs y) fi . eq larger [] x = [] . eq larger (x : xs) y = if x <= y then (larger xs y) else (x : (larger xs y)) fi . } open QUICKSORT . ~~</lang>~~ red qsort(5 : 4 : 3 : 2 : 1 : 0 : []) . red qsort(5 : 5 : 4 : 3 : 5 : 2 : 1 : 1 : 0 : []) . eof </syntaxhighlight> =={{header\|C++}}== The following implements quicksort with a median-of-three pivot. As idiomatic in C++, the argument <tt>last</tt> is a one-past-end iterator. Note that this code takes advantage of <tt>std::partition</tt>, which is O(n). Also note that it needs a random-access iterator for efficient calculation of the median-of-three pivot (more exactly, for O(1) calculation of the iterator <tt>mid</tt>). <~~lang~~syntaxhighlight lang="cpp">#include <iterator> #include <algorithm> // for std::partition #include <functional> // for std::less Line 676 ⟶ 4,136: { quicksort(first, last, std::less<typename std::iterator_traits<RandomAccessIterator>::value_type>()); }</~~lang~~syntaxhighlight> A simpler version of the above that just uses the first element as the pivot and only does one "partition". <~~lang~~syntaxhighlight lang="cpp">#include <iterator> #include <algorithm> // for std::partition #include <functional> // for std::less Line 700 ⟶ 4,160: { quicksort(first, last, std::less<typename std::iterator_traits<RandomAccessIterator>::value_type>()); }</~~lang~~syntaxhighlight> ~~=={{header\|C sharp\|C#}}==~~ ~~Note that actually Array.Sort and ArrayList.Sort both use an unstable implementation of the quicksort algorithm.~~ ~~<lang csharp>using System;~~ ~~using System.Collections.Generic;~~ ~~namespace QuickSort~~ { ~~class Program~~ { ~~static void Main(string[] args)~~ { ~~List<int> unsorted = new List<int> { 1, 3, 5, 7, 9, 8, 6, 4, 2 };~~ ~~List<int> sorted = quicksort(unsorted);~~ ~~Console.WriteLine(string.Join(",", sorted));~~ ~~Console.ReadKey();~~ } ~~private static List<int> quicksort(List<int> arr)~~ { ~~List<int> loe = new List<int>(), gt = new List<int>();~~ ~~if (arr.Count < 2)~~ ~~return arr;~~ ~~int pivot = arr.Count / 2;~~ ~~int pivot_val = arr[pivot];~~ ~~arr.RemoveAt(pivot);~~ ~~foreach (int i in arr)~~ { ~~if (i <= pivot_val)~~ ~~loe.Add(i);~~ ~~else if (i > pivot_val)~~ ~~gt.Add(i);~~ } ~~List<int> resultSet = new List<int>();~~ ~~resultSet.AddRange(quicksort(loe));~~ ~~gt.Add(pivot_val);~~ ~~resultSet.AddRange(quicksort(gt));~~ ~~return resultSet;~~ } } ~~}</lang>~~ ~~A very inefficient way to do qsort in C# to prove C# code can be just as compact and readable as any dynamic code~~ ~~<lang csharp>using System;~~ ~~using System.Collections.Generic;~~ ~~using System.Linq;~~ ~~namespace QSort~~ { ~~class QSorter~~ { ~~private static IEnumerable<IComparable> empty = new List<IComparable>();~~ ~~public static IEnumerable<IComparable> QSort(IEnumerable<IComparable> iEnumerable)~~ { ~~if(iEnumerable.Any())~~ { ~~var pivot = iEnumerable.First();~~ ~~return QSort(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) > 0)).~~ ~~Concat(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) == 0)).~~ ~~Concat(QSort(iEnumerable.Where((anItem) => pivot.CompareTo(anItem) < 0)));~~ } ~~return empty;~~ } } ~~}</lang>~~ =={{header\|Clojure}}== A very Haskell-like solution using list comprehensions and lazy evaluation. <~~lang~~syntaxhighlight lang="lisp">(defn qsort [L] (if (empty? L) '() Line 779 ⟶ 4,171: (lazy-cat (qsort (for [y L2 :when (< y pivot)] y)) (list pivot) (qsort (for [y L2 :when (>= y pivot)] y))))))</~~lang~~syntaxhighlight> Another short version (using quasiquote): <~~lang~~syntaxhighlight lang="lisp">(defn qsort [[pvt & rs]] (if pvt `(~@(qsort (filter #(< % pvt) rs)) ~pvt ~@(qsort (filter #(>= % pvt) rs)))))</~~lang~~syntaxhighlight> Another, more readable version (no macros): <~~lang~~syntaxhighlight lang="lisp">(defn qsort [[pivot & xs]] (when pivot (let [smaller #(< % pivot)] (lazy-cat (qsort (filter smaller xs)) [pivot] (qsort (remove smaller xs))))))</~~lang~~syntaxhighlight> A 3-group quicksort (fast when many values are equal): <~~lang~~syntaxhighlight lang="lisp">(defn qsort3 [[pvt :as coll]] (when pvt (let [{left -1 mid 0 right 1} (group-by #(compare % pvt) coll)] (lazy-cat (qsort3 left) mid (qsort3 right)))))</~~lang~~syntaxhighlight> A lazier version of above (unlike group-by, filter returns (and reads) a lazy sequence) <~~lang~~syntaxhighlight lang="lisp">(defn qsort3 [[pivot :as coll]] (when pivot (lazy-cat (qsort (filter #(< % pivot) coll)) (filter #{pivot} coll) (qsort (filter #(> % pivot) coll)))))</~~lang~~syntaxhighlight> =={{header\|~~CoffeeScript~~COBOL}}== {{works with\|Visual COBOL}} ~~<lang coffeescript>~~ <syntaxhighlight lang="cobol"> IDENTIFICATION DIVISION. ~~# This shows quicksort-in-place.~~ PROGRAM-ID. quicksort RECURSIVE. ~~quicksort = (a) ->~~ ~~swap~~ = ~~(i,~~ j) -> ~~return~~ if i ==DATA jDIVISION. LOCAL-STORAGE SECTION. ~~[a[i], a[j]] = [a[j], a[i]]~~ 01 temp PIC S9(8). ~~divide~~ = ~~(v,~~ ~~start,~~ ~~end)~~ -> 01 pivot PIC S9(8). ~~first_big = start~~ j = ~~start~~ 01 left-most-idx PIC 9(5). ~~while j <= end~~ 01 right-most-idx PIC 9(5). ~~if a[j] < v~~ ~~swap first_big, j~~ 01 left-idx PIC 9(5). ~~first_big += 1~~ 01 right-idx PIC 9(5). ~~j += 1~~ ~~first_big~~ LINKAGE SECTION. 78 Arr-Length VALUE 50. ~~partition = (start, end) ->~~ v = ~~a[end]~~ ~~first_big~~ = ~~divide~~ v,01 ~~start,~~ ~~end~~arr-1area. 03 arr PIC S9(8) OCCURS Arr-Length TIMES. ~~swap first_big, end~~ ~~first_big~~ 01 left-val PIC 9(5). 01 right-val PIC 9(5). ~~qs = (start, end) ->~~ ~~return~~ if ~~start~~ ~~>= end~~ PROCEDURE DIVISION USING REFERENCE arr-area, OPTIONAL left-val, ~~m = partition start, end~~ OPTIONAL right-val. ~~qs start, m-1~~ IF left-val IS OMITTED OR right-val IS OMITTED ~~qs m+1, end~~ MOVE 1 TO left-most-idx, left-idx MOVE Arr-Length TO right-most-idx, right-idx ~~qs 0, a.length - 1~~ ELSE MOVE left-val TO left-most-idx, left-idx ~~# test~~ MOVE right-val TO right-most-idx, right-idx ~~do ->~~ a = ~~[1,~~ 3, 5, 7, 9, 8, 6, ~~4, 2, 0, 3.5]~~END-IF ~~quicksort(a)~~ ~~console.log~~ a # [ 0, 1, 2, 3, ~~3.5,~~ 4,IF 5,right-most-idx 6,- 7,left-most-idx 8,< ~~9 ]~~1 GOBACK ~~</lang>~~ END-IF COMPUTE pivot = arr ((left-most-idx + right-most-idx) / 2) PERFORM UNTIL left-idx > right-idx PERFORM VARYING left-idx FROM left-idx BY 1 UNTIL arr (left-idx) >= pivot END-PERFORM PERFORM VARYING right-idx FROM right-idx BY -1 UNTIL arr (right-idx) <= pivot END-PERFORM IF left-idx <= right-idx MOVE arr (left-idx) TO temp MOVE arr (right-idx) TO arr (left-idx) MOVE temp TO arr (right-idx) ADD 1 TO left-idx SUBTRACT 1 FROM right-idx END-IF END-PERFORM CALL "quicksort" USING REFERENCE arr-area, CONTENT left-most-idx, right-idx CALL "quicksort" USING REFERENCE arr-area, CONTENT left-idx, right-most-idx GOBACK .</syntaxhighlight> =={{header\|CoffeeScript}}== <syntaxhighlight lang="coffeescript"> quicksort = ([x, xs...]) -> return [] unless x? smallerOrEqual = (a for a in xs when a <= x) larger = (a for a in xs when a > x) (quicksort smallerOrEqual).concat(x).concat(quicksort larger) </syntaxhighlight> =={{header\|Common Lisp}}== Line 855 ⟶ 4,285: The functional programming way <~~lang~~syntaxhighlight lang="lisp">(defun quicksort (list &aux (pivot (car list)) ) (if (cdr list) (nconc (quicksort (remove-if-not #'(lambda (x) (< x pivot)) list)) (remove-if-not #'(lambda (x) (= x pivot)) list) (quicksort (remove-if-not #'(lambda (x) (> x pivot)) list))) list))</~~lang~~syntaxhighlight> With flet <~~lang~~syntaxhighlight lang="lisp">(defun qs (list) (if (cdr list) (flet ((pivot (test) (remove (car list) list :test-not test))) (nconc (qs (pivot #'>)) (pivot #'=) (qs (pivot #'<)))) list))</~~lang~~syntaxhighlight> In-place non-functional <~~lang~~syntaxhighlight lang="lisp">(defun quicksort (sequence) (labels ((swap (a b) (rotatef (elt sequence a) (elt sequence b))) (sub-sort (left right) Line 886 ⟶ 4,316: (sub-sort (1+ index) right))))) (sub-sort 0 (1- (length sequence))) sequence))</~~lang~~syntaxhighlight> Functional with destructuring <syntaxhighlight lang="lisp"> (defun quicksort (list) (when list (destructuring-bind (x . xs) list (nconc (quicksort (remove-if (lambda (a) (> a x)) xs)) `(,x) (quicksort (remove-if (lambda (a) (<= a x)) xs))))))</syntaxhighlight> =={{header\|Cowgol}}== <syntaxhighlight lang="cowgol">include "cowgol.coh"; # Comparator interface, on the model of C, i.e: # foo < bar => -1, foo == bar => 0, foo > bar => 1 typedef CompRslt is int(-1, 1); interface Comparator(foo: intptr, bar: intptr): (rslt: CompRslt); # Quicksort an array of pointer-sized integers given a comparator function # (This is the closest you can get to polymorphism in Cowgol). # Because Cowgol does not support recursion, a pointer to free memory # for a stack must also be given. sub qsort(A: [intptr], len: intptr, comp: Comparator, stack: [intptr]) is # The partition function can be taken almost verbatim from Wikipedia sub partition(lo: intptr, hi: intptr): (p: intptr) is # This is not quite as bad as it looks: /2 compiles into a single shift # and "@bytesof intptr" is always power of 2 so compiles into shift(s). var pivot := [A + (hi/2 + lo/2) * @bytesof intptr]; var i := lo - 1; var j := hi + 1; loop loop i := i + 1; if comp([A + i@bytesof intptr], pivot) != -1 then break; end if; end loop; loop j := j - 1; if comp([A + j@bytesof intptr], pivot) != 1 then break; end if; end loop; if i >= j then p := j; return; end if; var ii := i * @bytesof intptr; var jj := j * @bytesof intptr; var t := [A+ii]; [A+ii] := [A+jj]; [A+jj] := t; end loop; end sub; # Cowgol lacks recursion, so we'll have to solve it by implementing # the stack ourselves. var sp: intptr := 0; # stack index sub push(n: intptr) is sp := sp + 1; [stack] := n; stack := @next stack; end sub; sub pop(): (n: intptr) is sp := sp - 1; stack := @prev stack; n := [stack]; end sub; # start by sorting [0..length-1] push(len-1); push(0); while sp != 0 loop var lo := pop(); var hi := pop(); if lo < hi then var p := partition(lo, hi); push(hi); # note the order - we need to push the high pair push(p+1); # first for it to be done last push(p); push(lo); end if; end loop; end sub; # Test: sort a list of numbers sub NumComp implements Comparator is # Compare the inputs as numbers if foo < bar then rslt := -1; elseif foo > bar then rslt := 1; else rslt := 0; end if; end sub; # Numbers var numbers: intptr[] := { 65,13,4,84,29,5,96,73,5,11,17,76,38,26,44,20,36,12,44,51,79,8,99,7,19,95,26 }; # Room for the stack var stackbuf: intptr[256]; # Sort the numbers in place qsort(&numbers as [intptr], @sizeof numbers, NumComp, &stackbuf as [intptr]); # Print the numbers (hopefully in order) var i: @indexof numbers := 0; while i < @sizeof numbers loop print_i32(numbers[i] as uint32); print_char(' '); i := i + 1; end loop; print_nl();</syntaxhighlight> {{out}} <pre>4 5 5 7 8 11 12 13 17 19 20 26 26 29 36 38 44 44 51 65 73 76 79 84 95 96 99</pre> =={{header\|Crystal}}== {{trans\|Ruby}} <syntaxhighlight lang="ruby">def quick_sort(a : Array(Int32)) : Array(Int32) return a if a.size <= 1 p = a[0] lt, rt = a[1 .. -1].partition { \|x\| x < p } return quick_sort(lt) + [p] + quick_sort(rt) end a = [7, 6, 5, 9, 8, 4, 3, 1, 2, 0] puts quick_sort(a) # => [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]</syntaxhighlight> =={{header\|Curry}}== Copied from [http://www.informatik.uni-kiel.de/~curry/examples/ Curry: Example Programs]. <~~lang~~syntaxhighlight lang="curry">-- quicksort using higher-order functions: qsort :: [Int] -> [Int] Line 896 ⟶ 4,456: qsort (x:l) = qsort (filter (<x) l) ++ x : qsort (filter (>=x) l) goal = qsort [2,3,1,0]</~~lang~~syntaxhighlight> =={{header\|D}}== A ~~high-level~~Functional version: <~~lang~~syntaxhighlight lang="d">import std.stdio : writefln, writeln; import std.algorithm: filter; import std.array; T[] quickSort(T)(T[] ~~items~~xs) {=> ~~if (items~~xs.length <== 0 ? [] : 1) xs[1 .. $].filter!(x => x< xs[0]).array.quickSort ~ xs[0 .. 1] ~ xs[1 .. $].filter!(x => x>=xs[0]).array.quickSort; void main() => [4, 65, 2, -31, 0, 99, 2, 83, 782, 1].quickSort.writeln; </syntaxhighlight> {{out}} <pre>[-31, 0, 1, 2, 2, 4, 65, 83, 99, 782]</pre> A simple high-level version (same output): <syntaxhighlight lang="d">import std.stdio, std.array; T[] quickSort(T)(T[] items) pure nothrow { if (items.empty) return items; T[] less, ~~more~~notLess; foreach (x; items[1 .. $]) (x < items[0] ? less : ~~more~~notLess) ~= x; return ~~quickSort(~~less).quickSort ~ items[0] ~ notLess.quickSort~~(more)~~; } void main() { ~~writeln(quickSort(~~[4, 65, 2, -31, 0, 99, 2, 83, 782, 1])).quickSort.writeln; }</~~lang~~syntaxhighlight> ~~Output:~~ ~~<pre>[-31, 0, 1, 2, 2, 4, 65, 83, 99, 782]</pre>~~ Often short functional sieves are not a true implementations of the Sieve of Eratosthenes: ~~An in-place version:~~ http://www.cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf ~~<lang d>import std.stdio;~~ ~~import std.algorithm;~~ Similarly, one could argue that a true QuickSort is in-place, ~~void quickSort(T)(T[] items)~~ as this more efficient version (same output): { <syntaxhighlight lang="d">import std.stdio, std.algorithm; void quickSort(T)(T[] items) pure nothrow @safe @nogc { if (items.length >= 2) { auto parts = partition3(items, items[$ / 2]); ~~quickSort(~~parts[0]).quickSort; ~~quickSort(~~parts[2]).quickSort; } } void main() { { auto items = [4, 65, 2, -31, 0, 99, 2, 83, 782, 1]; ~~quickSort(~~items).quickSort; ~~writeln(~~items).writeln; }</~~lang~~syntaxhighlight> =={{header\|Delphi}}== {{works with\|Delphi\|6.0}} {{libheader\|SysUtils,StdCtrls}} This quick sort routine is infinitely versatile. It sorts an array of pointers. The advantage of this is that pointers can contain anything, ranging from integers, to strings, to floating point numbers to objects. The way each pointer is interpreted is through the compare routine, which is customized for the particular situation. The compare routine can interpret each pointer as a string, an integer, a float or an object and it can treat those items in different ways. For example, the order in which it compares strings controls whether the sort is alphabetical or reverse alphabetical. In this case, I show an integer sort, an alphabetic string sort, a reverse alphabetical string sort and a string sort by length. <syntaxhighlight lang="Delphi"> {Dynamic array of pointers} type TPointerArray = array of Pointer; procedure QuickSort(SortList: TPointerArray; L, R: Integer; SCompare: TListSortCompare); {Do quick sort on items held in TPointerArray} {SCompare controls how the pointers are interpreted} var I, J: Integer; var P,T: Pointer; begin repeat begin I := L; J := R; P := SortList[(L + R) shr 1]; repeat begin while SCompare(SortList[I], P) < 0 do Inc(I); while SCompare(SortList[J], P) > 0 do Dec(J); if I <= J then begin {Exchange itesm} T:=SortList[I]; SortList[I]:=SortList[J]; SortList[J]:=T; if P = SortList[I] then P := SortList[J] else if P = SortList[J] then P := SortList[I]; Inc(I); Dec(J); end; end until I > J; if L < J then QuickSort(SortList, L, J, SCompare); L := I; end until I >= R; end; procedure DisplayStrings(Memo: TMemo; PA: TPointerArray); {Display pointers as strings} var I: integer; var S: string; begin S:='['; for I:=0 to High(PA) do begin if I>0 then S:=S+' '; S:=S+string(PA[I]^); end; S:=S+']'; Memo.Lines.Add(S); end; procedure DisplayIntegers(Memo: TMemo; PA: TPointerArray); {Display pointer array as integers} var I: integer; var S: string; begin S:='['; for I:=0 to High(PA) do begin if I>0 then S:=S+' '; S:=S+IntToStr(Integer(PA[I])); end; S:=S+']'; Memo.Lines.Add(S); end; function IntCompare(Item1, Item2: Pointer): Integer; {Compare for integer sort} begin Result:=Integer(Item1)-Integer(Item2); end; function StringCompare(Item1, Item2: Pointer): Integer; {Compare for alphabetical string sort} begin Result:=AnsiCompareText(string(Item1^),string(Item2^)); end; function StringRevCompare(Item1, Item2: Pointer): Integer; {Compare for reverse alphabetical order} begin Result:=AnsiCompareText(string(Item2^),string(Item1^)); end; function StringLenCompare(Item1, Item2: Pointer): Integer; {Compare for string length sort} begin Result:=Length(string(Item1^))-Length(string(Item2^)); end; {Arrays of strings and integers} var IA: array [0..9] of integer = (23, 14, 62, 28, 56, 91, 33, 30, 75, 5); var SA: array [0..15] of string = ('Now','is','the','time','for','all','good','men','to','come','to','the','aid','of','the','party.'); procedure ShowQuickSort(Memo: TMemo); var L: TStringList; var PA: TPointerArray; var I: integer; begin Memo.Lines.Add('Integer Sort'); SetLength(PA,Length(IA)); for I:=0 to High(IA) do PA[I]:=Pointer(IA[I]); Memo.Lines.Add('Before Sorting'); DisplayIntegers(Memo,PA); QuickSort(PA,0,High(PA),IntCompare); Memo.Lines.Add('After Sorting'); DisplayIntegers(Memo,PA); Memo.Lines.Add(''); Memo.Lines.Add('String Sort - Alphabetical'); SetLength(PA,Length(SA)); for I:=0 to High(SA) do PA[I]:=Pointer(@SA[I]); Memo.Lines.Add('Before Sorting'); DisplayStrings(Memo,PA); QuickSort(PA,0,High(PA),StringCompare); Memo.Lines.Add('After Sorting'); DisplayStrings(Memo,PA); Memo.Lines.Add(''); Memo.Lines.Add('String Sort - Reverse Alphabetical'); QuickSort(PA,0,High(PA),StringRevCompare); Memo.Lines.Add('After Sorting'); DisplayStrings(Memo,PA); Memo.Lines.Add(''); Memo.Lines.Add('String Sort - By Length'); QuickSort(PA,0,High(PA),StringLenCompare); Memo.Lines.Add('After Sorting'); DisplayStrings(Memo,PA); end; </syntaxhighlight> {{out}} <pre> Integer Sort Before Sorting [23 14 62 28 56 91 33 30 75 5] After Sorting [5 14 23 28 30 33 56 62 75 91] String Sort - Alphabetical Before Sorting [Now is the time for all good men to come to the aid of the party.] After Sorting [aid all come for good is men Now party. of the the the time to to] String Sort - Reverse Alphabetical After Sorting [to to time the the the party. of Now men is good for come all aid] String Sort - By Length After Sorting [of is to to men aid all for Now the the the time come good party.] Elapsed Time: 16.478 ms. </pre> =={{header\|Dart}}== <~~lang~~syntaxhighlight lang="dart">quickSort(List a) { if (a.length <= 1) { return a; Line 976 ⟶ 4,727: print("After sort"); arr.forEach((var i)=>print("$i")); }</~~lang~~syntaxhighlight> =={{header\|E}}== <~~lang~~syntaxhighlight lang="e">def quicksort := { def swap(container, ixA, ixB) { Line 1,025 ⟶ 4,777: quicksortR(array, 0, array.size() - 1) } }</~~lang~~syntaxhighlight> =={{header\|EasyLang}}== <syntaxhighlight lang="text"> proc qsort left right . d[] . while left < right # partition piv = d[left] mid = left for i = left + 1 to right if d[i] < piv mid += 1 swap d[i] d[mid] . . swap d[left] d[mid] # if mid < (right + left) / 2 qsort left mid - 1 d[] left = mid + 1 else qsort mid + 1 right d[] right = mid - 1 . . . proc sort . d[] . qsort 1 len d[] d[] . d[] = [ 29 4 72 44 55 26 27 77 92 5 ] sort d[] print d[] </syntaxhighlight> =={{header\|EchoLisp}}== <syntaxhighlight lang="scheme"> (lib 'list) ;; list-partition (define compare 0) ;; counter (define (quicksort L compare-predicate: proc aux: (part null)) (if (<= (length L) 1) L (begin ;; counting the number of comparisons (set! compare (+ compare (length (rest L)))) ;; pivot = first element of list (set! part (list-partition (rest L) proc (first L))) (append (quicksort (first part) proc ) (list (first L)) (quicksort (second part) proc))))) </syntaxhighlight> {{out}} <syntaxhighlight lang="scheme"> (shuffle (iota 15)) → (10 0 14 11 13 9 2 5 4 8 1 7 12 3 6) (quicksort (shuffle (iota 15)) <) → (0 1 2 3 4 5 6 7 8 9 10 11 12 13 14) ;; random list of numbers in [0 .. n[ ;; count number of comparisons (define (qtest (n 10000)) (set! compare 0) (quicksort (shuffle (iota n)) >) (writeln 'n n 'compare# compare )) (qtest 1000) n 1000 compare# 12764 (qtest 10000) n 10000 compare# 277868 (qtest 100000) n 100000 compare# 6198601 </syntaxhighlight> =={{header\|Eero}}== Translated from Objective-C example on this page. <syntaxhighlight lang="objc">#import <Foundation/Foundation.h> void quicksortInPlace(MutableArray array, const long first, const long last) if first >= last return Value pivot = array[(first + last) / 2] left := first right := last while left <= right while array[left] < pivot left++ while array[right] > pivot right-- if left <= right array.exchangeObjectAtIndex: left++, withObjectAtIndex: right-- quicksortInPlace(array, first, right) quicksortInPlace(array, left, last) Array quicksort(Array unsorted) a := [] a.addObjectsFromArray: unsorted quicksortInPlace(a, 0, a.count - 1) return a int main(int argc, const char * argv[]) autoreleasepool a := [1, 3, 5, 7, 9, 8, 6, 4, 2] Log( 'Unsorted: %@', a) Log( 'Sorted: %@', quicksort(a) ) b := ['Emil', 'Peg', 'Helen', 'Juergen', 'David', 'Rick', 'Barb', 'Mike', 'Tom'] Log( 'Unsorted: %@', b) Log( 'Sorted: %@', quicksort(b) ) return 0</syntaxhighlight> Alternative implementation (not necessarily as efficient, but very readable) <syntaxhighlight lang="objc">#import <Foundation/Foundation.h> implementation Array (Quicksort) plus: Array array, return Array = self.arrayByAddingObjectsFromArray: array filter: BOOL (^)(id) predicate, return Array array := [] for id item in self if predicate(item) array.addObject: item return array.copy quicksort, return Array = self if self.count > 1 id x = self[self.count / 2] lesser := self.filter: (id y \| return y < x) greater := self.filter: (id y \| return y > x) return lesser.quicksort + [x] + greater.quicksort end int main() autoreleasepool a := [1, 3, 5, 7, 9, 8, 6, 4, 2] Log( 'Unsorted: %@', a) Log( 'Sorted: %@', a.quicksort ) b := ['Emil', 'Peg', 'Helen', 'Juergen', 'David', 'Rick', 'Barb', 'Mike', 'Tom'] Log( 'Unsorted: %@', b) Log( 'Sorted: %@', b.quicksort ) return 0</syntaxhighlight> {{out}} <pre> 2013-09-04 16:54:31.780 a.out[2201:507] Unsorted: ( 1, 3, 5, 7, 9, 8, 6, 4, 2 ) 2013-09-04 16:54:31.781 a.out[2201:507] Sorted: ( 1, 2, 3, 4, 5, 6, 7, 8, 9 ) 2013-09-04 16:54:31.781 a.out[2201:507] Unsorted: ( Emil, Peg, Helen, Juergen, David, Rick, Barb, Mike, Tom ) 2013-09-04 16:54:31.782 a.out[2201:507] Sorted: ( Barb, David, Emil, Helen, Juergen, Mike, Peg, Rick, Tom ) </pre> =={{header\|Eiffel}}== The <syntaxhighlight lang="eiffel">QUICKSORT</syntaxhighlight> class: <syntaxhighlight lang="eiffel"> class QUICKSORT [G -> COMPARABLE] create make feature {NONE} --Implementation is_sorted (list: ARRAY [G]): BOOLEAN require not_void: list /= Void local i: INTEGER do Result := True from i := list.lower + 1 invariant i >= list.lower + 1 and i <= list.upper + 1 until i > list.upper loop Result := Result and list [i - 1] <= list [i] i := i + 1 variant list.upper + 1 - i end end concatenate_array (a: ARRAY [G] b: ARRAY [G]): ARRAY [G] require not_void: a /= Void and b /= Void do create Result.make_from_array (a) across b as t loop Result.force (t.item, Result.upper + 1) end ensure same_size: a.count + b.count = Result.count end quicksort_array (list: ARRAY [G]): ARRAY [G] require not_void: list /= Void local less_a: ARRAY [G] equal_a: ARRAY [G] more_a: ARRAY [G] pivot: G do create less_a.make_empty create more_a.make_empty create equal_a.make_empty create Result.make_empty if list.count <= 1 then Result := list else pivot := list [list.lower] across list as li invariant less_a.count + equal_a.count + more_a.count <= list.count loop if li.item < pivot then less_a.force (li.item, less_a.upper + 1) elseif li.item = pivot then equal_a.force (li.item, equal_a.upper + 1) elseif li.item > pivot then more_a.force (li.item, more_a.upper + 1) end end Result := concatenate_array (Result, quicksort_array (less_a)) Result := concatenate_array (Result, equal_a) Result := concatenate_array (Result, quicksort_array (more_a)) end ensure same_size: list.count = Result.count sorted: is_sorted (Result) end feature -- Initialization make do end quicksort (a: ARRAY [G]): ARRAY [G] do Result := quicksort_array (a) end end </syntaxhighlight> A test application: <syntaxhighlight lang="eiffel"> class APPLICATION create make feature {NONE} -- Initialization make -- Run application. local test: ARRAY [INTEGER] sorted: ARRAY [INTEGER] sorter: QUICKSORT [INTEGER] do create sorter.make test := <<1, 3, 2, 4, 5, 5, 7, -1>> sorted := sorter.quicksort (test) across sorted as s loop print (s.item) print (" ") end print ("%N") end end </syntaxhighlight> =={{header\|Elena}}== ELENA 6.x : <syntaxhighlight lang="elena">import extensions; import system'routines; import system'collections; extension op { quickSort() { if (self.isEmpty()) { ^ self }; var pivot := self[0]; auto less := new ArrayList(); auto pivotList := new ArrayList(); auto more := new ArrayList(); self.forEach::(item) { if (item < pivot) { less.append(item) } else if (item > pivot) { more.append(item) } else { pivotList.append(item) } }; less := less.quickSort(); more := more.quickSort(); less.appendRange(pivotList); less.appendRange(more); ^ less } } public program() { var list := new int[]{3, 14, 1, 5, 9, 2, 6, 3}; console.printLine("before:", list.asEnumerable()); console.printLine("after :", list.quickSort().asEnumerable()); }</syntaxhighlight> {{out}} <pre> before:3,14,1,5,9,2,6,3 after :1,2,3,3,5,6,9,14 </pre> =={{header\|Elixir}}== <syntaxhighlight lang="elixir">defmodule Sort do def qsort([]), do: [] def qsort([h \| t]) do {lesser, greater} = Enum.split_with(t, &(&1 < h)) qsort(lesser) ++ [h] ++ qsort(greater) end end</syntaxhighlight> =={{header\|Erlang}}== like haskell. Used by [[Measure_relative_performance_of_sorting_algorithms_implementations]]. If changed keep the interface or change [[Measure_relative_performance_of_sorting_algorithms_implementations]] ~~<lang erlang>qsort([]) -> [];~~ <syntaxhighlight lang="erlang"> -module( quicksort ). -export( [qsort/1] ). qsort([]) -> []; qsort([X\|Xs]) -> qsort([ Y \|\| Y <- Xs, Y < X]) ++ [X] ++ qsort([ Y \|\| Y <- Xs, Y >= X]).~~</lang>~~ </syntaxhighlight> multi-process implementation (number processes = number of processor cores): <syntaxhighlight lang="erlang"> quick_sort(L) -> qs(L, trunc(math:log2(erlang:system_info(schedulers)))). qs([],_) -> []; qs([H\|T], N) when N > 0 -> {Parent, Ref} = {self(), make_ref()}, spawn(fun()-> Parent ! {l1, Ref, qs([E\|\|E<-T, E<H], N-1)} end), spawn(fun()-> Parent ! {l2, Ref, qs([E\|\|E<-T, H =< E], N-1)} end), {L1, L2} = receive_results(Ref, undefined, undefined), L1 ++ [H] ++ L2; qs([H\|T],_) -> qs([E\|\|E<-T, E<H],0) ++ [H] ++ qs([E\|\|E<-T, H =< E],0). receive_results(Ref, L1, L2) -> receive {l1, Ref, L1R} when L2 == undefined -> receive_results(Ref, L1R, L2); {l2, Ref, L2R} when L1 == undefined -> receive_results(Ref, L1, L2R); {l1, Ref, L1R} -> {L1R, L2}; {l2, Ref, L2R} -> {L1, L2R} after 5000 -> receive_results(Ref, L1, L2) end. </syntaxhighlight> =={{header\|Emacs Lisp}}== '''Unoptimized''' {{libheader\|seq.el}} <syntaxhighlight lang="lisp">(require 'seq) (defun quicksort (xs) (if (null xs) () (let* ((head (car xs)) (tail (cdr xs)) (lower-part (quicksort (seq-filter (lambda (x) (<= x head)) tail))) (higher-part (quicksort (seq-filter (lambda (x) (> x head)) tail)))) (append lower-part (list head) higher-part))))</syntaxhighlight> =={{header\|ERRE}}== <syntaxhighlight lang="erre"> PROGRAM QUICKSORT_DEMO DIM ARRAY[21] !$DYNAMIC DIM QSTACK[0] !$INCLUDE="PC.LIB" PROCEDURE QSORT(ARRAY[],START,NUM) FIRST=START ! initialize work variables LAST=START+NUM-1 LOOP REPEAT TEMP=ARRAY[(LAST+FIRST) DIV 2] ! seek midpoint I=FIRST J=LAST REPEAT ! reverse both < and > below to sort descending WHILE ARRAY[I]<TEMP DO I=I+1 END WHILE WHILE ARRAY[J]>TEMP DO J=J-1 END WHILE EXIT IF I>J IF I<J THEN SWAP(ARRAY[I],ARRAY[J]) END IF I=I+1 J=J-1 UNTIL NOT(I<=J) IF I<LAST THEN ! Done QSTACK[SP]=I ! Push I QSTACK[SP+1]=LAST ! Push Last SP=SP+2 END IF LAST=J UNTIL NOT(FIRST<LAST) EXIT IF SP=0 SP=SP-2 FIRST=QSTACK[SP] ! Pop First LAST=QSTACK[SP+1] ! Pop Last END LOOP END PROCEDURE BEGIN RANDOMIZE(TIMER) ! generate a new series each run ! create an array FOR X=1 TO 21 DO ! fill with random numbers ARRAY[X]=RND(1)500 ! between 0 and 500 END FOR PRIMO=6 ! sort starting here NUM=10 ! sort this many elements CLS PRINT("Before Sorting:";TAB(31);"After sorting:") PRINT("===============";TAB(31);"==============") FOR X=1 TO 21 DO ! show them before sorting IF X>=PRIMO AND X<=PRIMO+NUM-1 THEN PRINT("==>";) END IF PRINT(TAB(5);) WRITE("###.##";ARRAY[X]) END FOR ! create a stack !$DIM QSTACK[INT(NUM/5)+10] QSORT(ARRAY[],PRIMO,NUM) !$ERASE QSTACK LOCATE(2,1) FOR X=1 TO 21 DO ! print them after sorting LOCATE(2+X,30) IF X>=PRIMO AND X<=PRIMO+NUM-1 THEN PRINT("==>";) ! point to sorted items END IF LOCATE(2+X,35) WRITE("###.##";ARRAY[X]) END FOR END PROGRAM </syntaxhighlight> =={{header\|F Sharp\|F#}}== <~~lang~~syntaxhighlight lang="fsharp"> let rec qsort = function []hd :: tl -> [] ~~\| hd :: tl ->~~ let less, greater = List.partition ((>=) hd) tl List.concat [qsort less; [hd]; qsort greater] \| _ -> [] ~~</lang>~~ </syntaxhighlight> =={{header\|Factor}}== <~~lang~~syntaxhighlight lang="factor">: qsort ( seq -- seq ) dup empty? [ unclip [ [ < ] curry partition [ qsort ] bi@ ] keep prefix append ] unless ;</~~lang~~syntaxhighlight> =={{header\|~~Fexl~~Fe}}== <syntaxhighlight lang="clojure"> ~~<lang Fexl>~~ ; utility for list joining ~~# (sort keep compare xs) sorts the list xs using the three-way comparison~~ (= join (fn (a b) ~~# function. It keeps duplicates if the keep flag is true, otherwise it~~ (if (is a nil) b (is b nil) a (do ~~# discards them and returns only the unique entries.~~ (let res a) (while (cdr a) (= a (cdr a))) (setcdr a b) res)))) (= quicksort (fn (lst) ~~\sort ==~~ (if (not (cdr lst)) lst (do ~~(\keep\compare\xs~~ xs(let ~~end~~pivot ~~\x\xs~~(car lst)) (let less nil) (let equal nil) (let greater nil) ; filter list for less than pivot, equal to pivot and greater than pivot (while lst (let x (car lst)) (if (< x pivot) (= less (cons x less)) (< pivot x) (= greater (cons x greater)) (= equal (cons x equal))) (= lst (cdr lst))) ; sort 'less' and 'greater' partitions ('equal' partition is always sorted) (= less (quicksort less)) (= greater (quicksort greater)) ; join partitions to one (join less (join equal greater)))))) (print '(4 65 0 ~~\lo~~2 =-31 ~~(filter~~99 ~~(\y~~2 ~~compare~~0 y83 x782 ~~T F F~~1) xs) (print (quicksort '(4 65 0 2 -31 99 2 0 83 782 1))) ~~\hi = (filter (\y compare y x F keep T) xs)~~ </syntaxhighlight> Outputs: <syntaxhighlight lang="clojure"> (4 65 0 2 -31 99 2 0 83 782 1) (-31 0 0 1 2 2 4 65 83 99 782) </syntaxhighlight> =={{header\|Fexl}}== ~~append (sort keep compare lo);~~ <syntaxhighlight lang="fexl"># (sort xs) is the ordered list of all elements in list xs. ~~item x;~~ # This version preserves duplicates. ~~sort keep compare hi~~ \sort== (\xs xs [] \x\xs append (sort; filter (gt x) xs); # all the items less than x cons x; append (filter (eq x) xs); # all the items equal to x sort; filter (lt x) xs # all the items greater than x ) ~~</lang>~~ # (unique xs) is the ordered list of unique elements in list xs. ~~=={{header\|Forth}}==~~ \unique== ~~<lang forth>defer lessthan ( a@ b@ -- ? ) ' < is lessthan~~ (\xs xs [] \x\xs append (unique; filter (gt x) xs); # all the items less than x cons x; # x itself unique; filter (lt x) xs # all the items greater than x ) </syntaxhighlight> =={{header\|Forth}}== ~~: mid ( l r -- mid ) over - 2/ -cell and + ;~~ <syntaxhighlight lang="forth">: mid ( l r -- mid ) over - 2/ -cell and + ; : exch ( addr1 addr2 -- ) dup @ >r over @ swap ! r> swap ! ; Line 1,078 ⟶ 5,388: 2dup mid @ >r ( r: pivot ) 2dup begin swap begin dup @ r@ ~~lessthan~~< while cell+ repeat swap begin r@ over @ ~~lessthan~~< while cell- repeat 2dup <= if 2dup exch >r cell+ r> cell- then 2dup > until r> drop ; Line 1,091 ⟶ 5,401: : sort ( array len -- ) dup 2 < if 2drop exit then 1- cells over + qsort ;</~~lang~~syntaxhighlight> =={{header\|Fortran}}== ~~{{Improve\|Fortran\|Apparently does not work under [[gfortran]] on [[Mac OS\|OSX Lion]].}} <!--needs confirming -- Erik Siers 2012-03-04 -->~~ {{Works with\|Fortran\|90 and later}} <syntaxhighlight lang="fortran"> recursive subroutine fsort(a) use inserts, only:insertion_sort !Not included in this posting implicit none ! ! PARAMETER definitions ! integer, parameter :: changesize = 64 ! ! Dummy arguments ! real, dimension(:) ,contiguous :: a intent (inout) a ! ! Local variables ! integer :: first = 1 integer :: i integer :: j integer :: last logical :: stay real :: t real :: x ! !Code ! last = size(a, 1) if( (last - first)<changesize )then call insertion_sort(a(first:last)) return end if j = shiftr((first + last), 1) + 1 ! x = a(j) i = first j = last stay = .true. do while ( stay ) do while ( a(i)<x ) i = i + 1 end do do while ( x<a(j) ) j = j - 1 end do if( j<i )then stay = .false. else t = a(i) ! Swap the values a(i) = a(j) a(j) = t i = i + 1 ! Adjust the pointers (PIVOT POINTS) j = j - 1 end if end do if( first<i - 1 )call fsort(a(first:i - 1)) ! We still have some left to do on the lower if( j + 1<last )call fsort(a(j + 1:last)) ! We still have some left to do on the upper return end subroutine fsort </syntaxhighlight> =={{header\|FunL}}== ~~<lang fortran>MODULE Qsort_Module~~ <syntaxhighlight lang="funl">def qsort( [] ) = [] ~~IMPLICIT NONE~~ qsort( p:xs ) = qsort( xs.filter((< p)) ) + [p] + qsort( xs.filter((>= p)) )</syntaxhighlight> ~~CONTAINS~~ Here is a more efficient version using the <code>partition</code> function. ~~RECURSIVE SUBROUTINE Qsort(a)~~ <syntaxhighlight lang="funl">def qsort( [] ) = [] ~~INTEGER, INTENT(IN OUT) :: a(:)~~ ~~INTEGER~~qsort( x::xs ) ~~split~~= val (ys, zs) = xs.partition( (< x) ) qsort( ys ) + (x : qsort( zs )) ~~IF(size(a) > 1) THEN~~ ~~CALL Partition(a, split)~~ println( qsort([4, 2, 1, 3, 0, 2]) ) ~~CALL Qsort(a(:split-1))~~ println( qsort(["Juan", "Daniel", "Miguel", "William", "Liam", "Ethan", "Jacob"]) )</syntaxhighlight> ~~CALL Qsort(a(split:))~~ ~~END IF~~ {{out}} ~~END SUBROUTINE Qsort~~ <pre> [0, 1, 2, 2, 3, 4] ~~SUBROUTINE Partition(a, marker)~~ [Daniel, Ethan, Jacob, Juan, Liam, Miguel, William] </pre> ~~INTEGER, INTENT(IN OUT) :: a(:)~~ ~~INTEGER, INTENT(OUT) :: marker~~ ~~INTEGER :: left, right, pivot, temp~~ ~~pivot = (a(1) + a(size(a))) / 2 ! Average of first and last elements to prevent quadratic~~ ~~left = 0 ! behavior with sorted or reverse sorted data~~ ~~right = size(a) + 1~~ ~~DO WHILE (left < right)~~ ~~right = right - 1~~ ~~DO WHILE (a(right) > pivot)~~ ~~right = right-1~~ ~~END DO~~ ~~left = left + 1~~ ~~DO WHILE (a(left) < pivot)~~ ~~left = left + 1~~ ~~END DO~~ ~~IF (left < right) THEN~~ ~~temp = a(left)~~ ~~a(left) = a(right)~~ ~~a(right) = temp~~ ~~END IF~~ ~~END DO~~ ~~IF (left == right) THEN~~ ~~marker = left + 1~~ ~~ELSE~~ ~~marker = left~~ ~~END IF~~ ~~END SUBROUTINE Partition~~ ~~END MODULE Qsort_Module~~ ~~PROGRAM Quicksort~~ ~~USE Qsort_Module~~ ~~IMPLICIT NONE~~ ~~INTEGER, PARAMETER :: n = 100~~ ~~INTEGER :: array(n)~~ ~~INTEGER :: i~~ ~~REAL :: x~~ ~~CALL RANDOM_SEED~~ ~~DO i = 1, n~~ ~~CALL RANDOM_NUMBER(x)~~ ~~array(i) = INT(x * 10000)~~ ~~END DO~~ ~~WRITE (, "(A)") "array is :-"~~ ~~WRITE (, "(10I5)") array~~ ~~CALL Qsort(array)~~ ~~WRITE (,)~~ ~~WRITE (, "(A)") "sorted array is :-"~~ ~~WRITE (,"(10I5)") array~~ ~~END PROGRAM Quicksort</lang>~~ ~~=={{header\|FPr}}==~~ ~~<lang FPr>qsort==nilp->id;~~ ~~((qsort°3)++1,qsort°4)~~ ~~°((not°nilp°2)->1,(tail°2),(1>1°2)->(((1°2),3),4,nil);3,((1°2),4),nil)~~ ~~°1,tail,(nil as _1),(nil as _1),nil~~ ~~</lang>~~ =={{header\|Go}}== Note that Go's <code>sort.Sort</code> function is a Quicksort so in practice it would be just be used. It's actually a combination of quick sort, heap sort, and insertion sort. It starts with a quick sort, after a depth of 2ceil(lg(n+1)) it switches to heap sort, or once a partition becomes small (less than eight items) it switches to insertion sort. Old school, following [http://comjnl.oxfordjournals.org/cgi/content/short/5/1/10 Hoare's 1962 paper]. Line 1,193 ⟶ 5,503: Finally, the choice of a recursive closure over passing slices to a recursive function is really just a very small optimization. Slices are cheap because they do not copy the underlying array, but there's still a tiny bit of overhead in constructing the slice object. Passing just the two numbers is in the interest of avoiding that overhead. <~~lang~~syntaxhighlight lang="go">package main import "fmt" Line 1,285 ⟶ 5,595: } pex(0, len(a)-1) }</~~lang~~syntaxhighlight> {{out}} ~~Output:~~ <pre> unsorted: [31 41 59 26 53 58 97 93 23 84] sorted! [23 26 31 41 53 58 59 84 93 97] </pre> More traditional version of quicksort. It work generically with any container that conforms to <code>sort.Interface</code>. <syntaxhighlight lang="go">package main import ( "fmt" "sort" "math/rand" ) func partition(a sort.Interface, first int, last int, pivotIndex int) int { a.Swap(first, pivotIndex) // move it to beginning left := first+1 right := last for left <= right { for left <= last && a.Less(left, first) { left++ } for right >= first && a.Less(first, right) { right-- } if left <= right { a.Swap(left, right) left++ right-- } } a.Swap(first, right) // swap into right place return right } func quicksortHelper(a sort.Interface, first int, last int) { if first >= last { return } pivotIndex := partition(a, first, last, rand.Intn(last - first + 1) + first) quicksortHelper(a, first, pivotIndex-1) quicksortHelper(a, pivotIndex+1, last) } func quicksort(a sort.Interface) { quicksortHelper(a, 0, a.Len()-1) } func main() { a := []int{1, 3, 5, 7, 9, 8, 6, 4, 2} fmt.Printf("Unsorted: %v\n", a) quicksort(sort.IntSlice(a)) fmt.Printf("Sorted: %v\n", a) b := []string{"Emil", "Peg", "Helen", "Juergen", "David", "Rick", "Barb", "Mike", "Tom"} fmt.Printf("Unsorted: %v\n", b) quicksort(sort.StringSlice(b)) fmt.Printf("Sorted: %v\n", b) }</syntaxhighlight> {{out}} <pre> Unsorted: [1 3 5 7 9 8 6 4 2] Sorted: [1 2 3 4 5 6 7 8 9] Unsorted: [Emil Peg Helen Juergen David Rick Barb Mike Tom] Sorted: [Barb David Emil Helen Juergen Mike Peg Rick Tom] </pre> Line 1,295 ⟶ 5,667: The famous two-liner, reflecting the underlying algorithm directly: <syntaxhighlight lang ="haskell">qsort [] = [] qsort (x:xs) = qsort [y \| y <- xs, y < x] ++ [x] ++ qsort [y \| y <- xs, y >= x]</~~lang~~syntaxhighlight> A more efficient version, doing only one comparison per element: <~~lang~~syntaxhighlight lang="haskell">import Data.List (partition) qsort :: Ord a => [a] -> [a] qsort [] = [] qsort (x:xs) = qsort ys ++ [x] :++ qsort zs where ~~(ys, zs) = partition (< x) xs</lang>~~ (ys, zs) = partition (< x) xs</syntaxhighlight> ~~=={{header\|IDL}}==~~ ~~IDL has a powerful optimized <tt>sort()</tt> built-in. The following is thus merely for demonstration.~~ ~~<lang idl>function qs, arr~~ ~~if (count = n_elements(arr)) lt 2 then return,arr~~ ~~pivot = total(arr) / count ; use the average for want of a better choice~~ ~~return,[qs(arr[where(arr le pivot)]),qs(arr[where(arr gt pivot)])]~~ ~~end</lang>~~ ~~Example:~~ ~~IDL> print,qs([3,17,-5,12,99])~~ ~~-5 3 12 17 99~~ =={{header\|Icon}} and {{header\|Unicon}}== <~~lang~~syntaxhighlight ~~Icon~~lang="icon">procedure main() #: demonstrate various ways to sort a list and string demosort(quicksort,[3, 14, 1, 5, 9, 2, 6, 3],"qwerty") end Line 1,361 ⟶ 5,723: suspend lower # 1st return pivot point suspend X # 2nd return modified X (in case immutable) end</~~lang~~syntaxhighlight> Implementation notes: Line 1,371 ⟶ 5,733: <br/>Note: This example relies on [[Sorting_algorithms/Bubble_sort#Icon\| the supporting procedures 'sortop', and 'demosort' in Bubble Sort]]. The full demosort exercises the named sort of a list with op = "numeric", "string", ">>" (lexically gt, descending),">" (numerically gt, descending), a custom comparator, and also a string. {{out}} Abbreviated ~~Abbreviated sample output:<pre>Sorting Demo using procedure quicksort~~ <pre>Sorting Demo using procedure quicksort on list : [ 3 14 1 5 9 2 6 3 ] with op = &null: [ 1 2 3 3 5 6 9 14 ] (0 ms) Line 1,377 ⟶ 5,740: on string : "qwerty" with op = &null: "eqrtwy" (0 ms)</pre> =={{header\|IDL}}== IDL has a powerful optimized <tt>sort()</tt> built-in. The following is thus merely for demonstration. <syntaxhighlight lang="idl">function qs, arr if (count = n_elements(arr)) lt 2 then return,arr pivot = total(arr) / count ; use the average for want of a better choice return,[qs(arr[where(arr le pivot)]),qs(arr[where(arr gt pivot)])] end</syntaxhighlight> Example: IDL> print,qs([3,17,-5,12,99]) -5 3 12 17 99 =={{header\|Idris}}== <syntaxhighlight lang="idris">quicksort : Ord elem => List elem -> List elem quicksort [] = [] quicksort (x :: xs) = let lesser = filter (< x) xs greater = filter(>= x) xs in (quicksort lesser) ++ [x] ++ (quicksort greater)</syntaxhighlight> Example: quicksort> quicksort [1, 3, 7, 2, 5, 4, 9, 6, 8, 0] [0, 1, 2, 3, 4, 5, 6, 7, 8, 9] : List Integer =={{header\|Io}}== <~~lang~~syntaxhighlight lang="io">List do( quickSort := method( if(size > 1) then( Line 1,396 ⟶ 5,785: lst := list(5, -1, -4, 2, 9) lst quickSort println # ==> list(-4, -1, 2, 5, 9) lst quickSortInPlace println # ==> list(-4, -1, 2, 5, 9)</~~lang~~syntaxhighlight> Another more low-level Quicksort implementation can be found in Io's [[http://github.com/stevedekorte/io/blob/master/samples/misc/qsort.io github ]] repository. =={{header\|Isabelle}}== <syntaxhighlight lang="isabelle">theory Quicksort imports Main begin fun quicksort :: "('a :: linorder) list ⇒ 'a list" where "quicksort [] = []" \| "quicksort (x#xs) = (quicksort [y←xs. y<x]) @ [x] @ (quicksort [y←xs. y>x])" lemma "quicksort [4::int, 2, 7, 1] = [1, 2, 4, 7]" by(code_simp) lemma set_first_second_partition: fixes x :: "'a :: linorder" shows "{y ∈ ys. y < x} ∪ {x} ∪ {y ∈ ys. x < y} = insert x ys" by fastforce lemma set_quicksort: "set (quicksort xs) = set xs" by(induction xs rule: quicksort.induct) (simp add: set_first_second_partition[simplified])+ theorem "sorted (quicksort xs)" proof(induction xs rule: quicksort.induct) case 1 show "sorted (quicksort [])" by simp next case (2 x xs) assume IH_less: "sorted (quicksort [y←xs. y<x])" assume IH_greater: "sorted (quicksort [y←xs. y>x])" have pivot_geq_first_partition: "∀z∈set (quicksort [y←xs. y<x]). z ≤ x" by (simp add: set_quicksort less_imp_le) have pivot_leq_second_partition: "∀z ∈ (set (quicksort [y←xs. y>x])). (x ≤ z)" by (simp add: set_quicksort less_imp_le) have first_partition_leq_second_partition: "∀p∈set (quicksort [y←xs. y<x]). ∀z ∈ (set (quicksort [y←xs. y>x])). (p ≤ z)" by (auto simp add: set_quicksort) from IH_less IH_greater pivot_geq_first_partition pivot_leq_second_partition first_partition_leq_second_partition show "sorted (quicksort (x # xs))" by(simp add: sorted_append) qed text‹ The specification on rosettacode says ▪ All elements less than the pivot must be in the first partition. ▪ All elements greater than the pivot must be in the second partition. Since this specification neither says "less than or equal" nor "greater or equal", this quicksort implementation removes duplicate elements. › lemma "quicksort [1::int, 1, 1, 2, 2, 3] = [1, 2, 3]" by(code_simp) text‹If we try the following, we automatically get a counterexample› lemma "length (quicksort xs) = length xs" ( Auto Quickcheck found a counterexample: xs = [a⇩1, a⇩1] Evaluated terms: length (quicksort xs) = 1 length xs = 2 ) oops end </syntaxhighlight> =={{header\|J}}== {{eff note\|J\|/:~}} <~~lang~~syntaxhighlight lang="j">sel=: 1 : 'xu # [' quicksort=: 3 : 0 Line 1,412 ⟶ 5,873: (quicksort y <sel e),(y =sel e),quicksort y >sel e end. )</~~lang~~syntaxhighlight> See the [[j:Essays/Quicksort\|Quicksort essay]] in the J Wiki Line 1,418 ⟶ 5,879: =={{header\|Java}}== === Imperative === {{works with\|Java\|1.5+}}<br> {{trans\|Python}} <~~lang~~syntaxhighlight lang="java5">public static <E extends Comparable<? super E>> List<E> quickSort(List<E> arr) { if (!arr.isEmpty()) { return arr; ~~E pivot = arr.get(0); //This pivot can change to get faster results~~ else { E pivot = arr.get(0); List<E> less = new LinkedList<E>(); List<E> pivotList = new LinkedList<E>(); List<E> more = new LinkedList<E>(); // Partition for (E i: arr) { if (i.compareTo(pivot) < 0) less.add(i); else if (i.compareTo(pivot) > 0) more.add(i); else pivotList.add(i); } // Recursively sort sublists less = quickSort(less); more = quickSort(more); // Concatenate results less.addAll(pivotList); less.addAll(more); return less; } } } ~~return arr;~~ </syntaxhighlight> === Functional === ~~}</lang>~~ {{works with\|Java\|1.8}} <syntaxhighlight lang="java5">public static <E extends Comparable<E>> List<E> sort(List<E> col) { if (col == null \|\| col.isEmpty()) return Collections.emptyList(); else { E pivot = col.get(0); Map<Integer, List<E>> grouped = col.stream() .collect(Collectors.groupingBy(pivot::compareTo)); return Stream.of(sort(grouped.get(1)), grouped.get(0), sort(grouped.get(-1))) .flatMap(Collection::stream).collect(Collectors.toList()); } }</syntaxhighlight> =={{header\|JavaScript}}== ~~<lang javascript>function sort(array, less) {~~ ===Imperative=== ~~function swap(i, j) { var t=array[i]; array[i]=array[j]; array[j]=t }~~ <syntaxhighlight lang="javascript">function sort(array, less) { function swap(i, j) { var t = array[i]; array[i] = array[j]; array[j] = t; } function quicksort(left, right) { if (left < right) { var pivot = array[left + Math.floor((right - left) / 2)], ~~var~~ ~~pivot~~ = ~~array[(left~~ +left_new ~~right)~~= ~~>> 1];~~left, ~~var~~ ~~left_new~~ = ~~left,~~ right_new = right; do { while (less(array[left_new], pivot)) { left_new ++= 1; } ~~while (less(pivot, array[right_new])~~ while (less(pivot, array[right_new~~--;~~])) { if ~~(left_new~~ right_new <-= ~~right_new)~~1; } ~~swap(left_new++, right_new--);~~ } ~~while~~ if (left_new <= right_new); { swap(left_new, right_new); left_new += 1; right_new -= 1; } } while (left_new <= right_new); quicksort(left, right_new); Line 1,480 ⟶ 5,970: } quicksort(0, array.length - 1); return array; }</~~lang~~syntaxhighlight> Example:<syntaxhighlight lang="javascript">var test_array = [10, 3, 11, 15, 19, 1]; ~~The functional programming way~~ var sorted_array = sort(test_array, function(a,b) { return a<b; });</syntaxhighlight> {{Out}}<syntaxhighlight lang="javascript">[ 1, 3, 10, 11, 15, 19 ]</syntaxhighlight> ~~<lang javascript>Array.prototype.quick_sort = function ()~~ { ~~if (this.length <= 1)~~ ~~return this;~~ ===Functional=== ~~var pivot = this[Math.round(this.length / 2)];~~ ====ES6==== ~~return this.filter(function (x) { return x < pivot }).quick_sort().concat(~~ ~~this.filter(function (x) { return x == pivot })).concat(~~ Using '''destructuring''' and '''satisfying immutability''' we can propose a single expresion solution (from https://github.com/ddcovery/expressive_sort) ~~this.filter(function (x) { return x > pivot }).quick_sort());~~ ~~}</lang>~~ <syntaxhighlight lang="javascript">const qsort = ([pivot, ...others]) => pivot === void 0 ? [] : [ ...qsort(others.filter(n => n < pivot)), pivot, ...qsort(others.filter(n => n >= pivot)) ]; qsort( [ 11.8, 14.1, 21.3, 8.5, 16.7, 5.7 ] )</syntaxhighlight> {{Out}} <pre>[ 5.7, 8.5, 11.8, 14.1, 16.7, 21.3 ] </pre> ====ES5==== Unlike what happens with ES6, there are no destructuring nor lambdas, but we can '''ensure immutability''' and propose a '''single expression''' solution with standard anonymous functions <syntaxhighlight lang="javascript"> function qsort( xs ){ return xs.length === 0 ? [] : [].concat( qsort( xs.slice(1).filter(function(x){ return x< xs[0] })), xs[0], qsort( xs.slice(1).filter(function(x){ return x>= xs[0] })) ) } qsort( [ 11.8, 14.1, 21.3, 8.5, 16.7, 5.7 ] ) </syntaxhighlight> {{Out}} <pre>[5.7, 8.5, 11.8, 14.1, 16.7, 21.3]</pre> =={{header\|Joy}}== <~~lang~~syntaxhighlight lang="joy"> DEFINE qsort == [small] # termination condition: 0 or 1 element Line 1,507 ⟶ 6,023: [enconcat] # insert the pivot after the recursion binrec. # recursion on the two lists </syntaxhighlight> ~~</lang>~~ =={{header\|jq}}== jq's built-in <tt>sort</tt> currently (version 1.4) uses the standard C qsort, a quicksort. <tt>sort</tt> can be used on any valid JSON array. Example:<syntaxhighlight lang="jq">[1, 1.1, [1,2], true, false, null, {"a":1}, null] \| sort</syntaxhighlight>{{Out}}<syntaxhighlight lang="jq">[null,null,false,true,1,1.1,[1,2],{"a":1}]</syntaxhighlight> Here is an implementation in jq of the pseudo-code (and comments :-) given at the head of this article:<syntaxhighlight lang="jq">def quicksort: if length < 2 then . # it is already sorted else .[0] as $pivot \| reduce .[] as $x # state: [less, equal, greater] ( [ [], [], [] ]; # three empty arrays: if $x < $pivot then .[0] += [$x] # add x to less elif $x == $pivot then .[1] += [$x] # add x to equal else .[2] += [$x] # add x to greater end ) \| (.[0] \| quicksort ) + .[1] + (.[2] \| quicksort ) end ; </syntaxhighlight>Fortunately, the example input used above produces the same output, and so both are omitted here. =={{header\|Julia}}== Built-in function for in-place sorting via quicksort (the [https://github.com/JuliaLang/julia/blob/2364748377f2a79c0485fdd5155ec2116c9f0d37/base/sort.jl#L259-L296 code from the standard library is quite readable]): <syntaxhighlight lang="julia">sort!(A, alg=QuickSort)</syntaxhighlight> A simple polymorphic implementation of an in-place recursive quicksort (based on the pseudocode above): <syntaxhighlight lang="julia">function quicksort!(A,i=1,j=length(A)) if j > i pivot = A[rand(i:j)] # random element of A left, right = i, j while left <= right while A[left] < pivot left += 1 end while A[right] > pivot right -= 1 end if left <= right A[left], A[right] = A[right], A[left] left += 1 right -= 1 end end quicksort!(A,i,right) quicksort!(A,left,j) end return A end</syntaxhighlight> A one-line (but rather inefficient) implementation based on the Haskell version, which operates out-of-place and allocates temporary arrays: <syntaxhighlight lang="julia">qsort(L) = isempty(L) ? L : vcat(qsort(filter(x -> x < L[1], L[2:end])), L[1:1], qsort(filter(x -> x >= L[1], L[2:end])))</syntaxhighlight> {{out}} <pre>julia> A = [84,77,20,60,47,20,18,97,41,49,31,39,73,68,65,52,1,92,15,9] julia> qsort(A) [1,9,15,18,20,20,31,39,41,47,49,52,60,65,68,73,77,84,92,97] julia> quicksort!(copy(A)) [1,9,15,18,20,20,31,39,41,47,49,52,60,65,68,73,77,84,92,97] julia> qsort(A) == quicksort!(copy(A)) == sort(A) == sort(A, alg=QuickSort) true</pre> =={{header\|K}}== <~~lang~~syntaxhighlight Klang="k">quicksort:{f:x@1?#x;:[0=#x;x;,/(_f x@&x<f;x@&x=f;_f x@&x>f)]}</~~lang~~syntaxhighlight> Example: <syntaxhighlight lang="k"> ~~<lang K>~~ quicksort 1 3 5 7 9 8 6 4 2 </syntaxhighlight> ~~</lang>~~ {{out}} ~~Output:~~ <pre> ~~<lang K>~~ 1 2 3 4 5 6 7 8 9 </~~lang~~pre> Explanation: <syntaxhighlight lang="k"> ~~<lang K>~~ _f() </syntaxhighlight> ~~</lang>~~ is the current function called recursively. <syntaxhighlight lang="k"> ~~<lang K>~~ :[....] </syntaxhighlight> ~~</lang>~~ generally means :[condition1;then1;condition2;then2;....;else]. Though Line 1,542 ⟶ 6,117: This construct <syntaxhighlight lang="k"> ~~<lang K>~~ f:x@1?#x </syntaxhighlight> ~~</lang>~~ assigns a random element in x (the argument) to f, as the pivot value. Line 1,550 ⟶ 6,125: And here is the full if/then/else clause: <syntaxhighlight lang="k"> ~~<lang K>~~ :[ 0=#x; / if length of x is zero Line 1,560 ⟶ 6,135: _f x@&x>f) / sort (recursively) elements greater than f ] </syntaxhighlight> ~~</lang>~~ Though - as with APL and J - for larger arrays it's much faster to Line 1,566 ⟶ 6,141: list sorted ascending, i.e. <syntaxhighlight lang="k"> ~~<lang K>~~ t@<t:1 3 5 7 9 8 6 4 2 </syntaxhighlight> ~~</lang>~~ =={{header\|Koka}}== Haskell-like solution <syntaxhighlight lang="koka">fun qsort( xs : list<int> ) : div list<int> { match(xs) { Cons(x,xx) -> { val ys = xx.filter fn(el) { el < x } val zs = xx.filter fn(el) { el >= x } qsort(ys) ++ [x] ++ qsort(zs) } Nil -> Nil } }</syntaxhighlight> or using standard <code>partition</code> function <syntaxhighlight lang="koka">fun qsort( xs : list<int> ) : div list<int> { match(xs) { Cons(x,xx) -> { val (ys, zs) = xx.partition fn(el) { el < x } qsort(ys) ++ [x] ++ qsort(zs) } Nil -> Nil } }</syntaxhighlight> Example: <syntaxhighlight lang="koka">fun main() { val arr = [24,63,77,26,84,64,56,80,85,17] println(arr.qsort.show) }</syntaxhighlight> {{out}} <pre>[17,24,26,56,63,64,77,80,84,85]</pre> =={{header\|Kotlin}}== A version that reflects the algorithm directly: <syntaxhighlight lang="scala">fun <E : Comparable<E>> List<E>.qsort(): List<E> = if (size < 2) this else filter { it < first() }.qsort() + filter { it == first() } + filter { it > first() }.qsort() </syntaxhighlight> A more efficient version that does only one comparison per element: <syntaxhighlight lang="scala">fun <E : Comparable<E>> List<E>.qsort(): List<E> = if (size < 2) this else { val (less, high) = subList(1, size).partition { it < first() } less.qsort() + first() + high.qsort() } </syntaxhighlight> =={{header\|Lambdatalk}}== <syntaxhighlight lang="lisp"> We create a binary tree from a random array, then we walk the canopy. 1) three functions for readability: {def BT.data {lambda {:t} {A.get 0 :t}}} -> BT.data {def BT.left {lambda {:t} {A.get 1 :t}}} -> BT.left {def BT.right {lambda {:t} {A.get 2 :t}}} -> BT.right 2) adding a leaf to the tree: {def BT.add {lambda {:x :t} {if {A.empty? :t} then {A.new :x {A.new} {A.new}} else {if {= :x {BT.data :t}} then :t else {if {< :x {BT.data :t}} then {A.new {BT.data :t} {BT.add :x {BT.left :t}} {BT.right :t}} else {A.new {BT.data :t} {BT.left :t} {BT.add :x {BT.right :t}} }}}}}} -> BT.add 3) creating the tree from an array of numbers: {def BT.create {def BT.create.rec {lambda {:l :t} {if {A.empty? :l} then :t else {BT.create.rec {A.rest :l} {BT.add {A.first :l} :t}} }}} {lambda {:l} {BT.create.rec :l {A.new}} }} -> BT.create 4) walking the canopy -> sorting in increasing order: {def BT.sort {lambda {:t} {if {A.empty? :t} then else {BT.sort {BT.left :t}} {BT.data :t} {BT.sort {BT.right :t}} }}} -> BT.sort Testing 1) generating random numbers: {def L {A.new {S.map {lambda {:n} {floor { {random} 100000}}} {S.serie 1 100}}}} -> L = [1850,7963,50540,92667,72892,47361,19018,40640,10126,80235,48407,51623,63597,71675,27814,63478,18985,88032,46585,85209, 74053,95005,27592,9575,22162,35904,70467,38527,89715,36594,54309,39950,89345,72224,7772,65756,68766,43942,52422,85144, 66010,38961,21647,53194,72166,33545,49037,23218,27969,83566,19382,53120,55291,77374,27502,66648,99637,37322,9815,432,90565, 37831,26503,99232,87024,65625,75155,55382,30120,58117,70031,13011,81375,10490,39786,1926,71311,4213,55183,2583,22075,90411, 92928,61120,94259,433,93332,88423,64119,40850,94318,27816,84818,90632,5094,36696,94705,50602,45818,61365] 2) creating the tree is the main work: {def T {BT.create {L}}} -> T = [1850,[432,],[433,],]]],[7963,[7772,[1926,],[4213,[2583,],]],[5094,],]]]],]],[50540,[47361,[19018,[10126,[9575,], [9815,],]]],[18985,[13011,[10490,],]],]],]]],[40640,[27814,[27592,[22162,[21647,[19382,],]],[22075,],]]],[23218,], [27502,[26503,],]],]]]],]],[35904,[33545,[27969,[27816,],]],[30120,],]]],]],[38527,[36594,],[37322,[36696,],]],[37831,],]]]], [39950,[38961,],[39786,],]]],]]]]],[46585,[43942,[40850,],]],[45818,],]]],]]]],[48407,],[49037,],]]]],[92667,[72892, [51623,[50602,],]],[63597,[63478,[54309,[52422,],[53194,[53120,],]],]]],[55291,[55183,],]],[55382,],[58117,],[61120,],[61365,],]]]]]]],]],[71675,[70467,[65756,[65625,[64119,],]],]],[68766,[66010,],[66648,],]]],[70031,],]]]],[71311,],]]], [72224,[72166,],]],]]]]],[80235,[74053,],[77374,[75155,],]],]]],[88032,[85209,[85144,[83566,[81375,],]],[84818,],]]],]], [87024,],]]],[89715,[89345,[88423,],]],]],[90565,[90411,],]],[90632,],]]]]]]],[95005,[92928,],[94259,[93332,],]],[94318,], [94705,],]]]]],[99637,[99232,],]],]]]]]]] 3) walking the canopy is fast: {BT.sort {T}} -> 432 433 1850 1926 2583 4213 5094 7772 7963 9575 9815 10126 10490 13011 18985 19018 19382 21647 22075 22162 23218 26503 27502 27592 27814 27816 27969 30120 33545 35904 36594 36696 37322 37831 38527 38961 39786 39950 40640 40850 43942 45818 46585 47361 48407 49037 50540 50602 51623 52422 53120 53194 54309 55183 55291 55382 58117 61120 61365 63478 63597 64119 65625 65756 66010 66648 68766 70031 70467 71311 71675 72166 72224 72892 74053 75155 77374 80235 81375 83566 84818 85144 85209 87024 88032 88423 89345 89715 90411 90565 90632 92667 92928 93332 94259 94318 94705 95005 99232 99637 4) walking with new leaves is fast: {BT.sort {BT.add -1 {T}}} -> -1 432 433 1850 1926 2583 4213 5094 7772 7963 9575 9815 10126 10490 13011 18985 19018 19382 21647 22075 22162 23218 26503 27502 27592 27814 27816 27969 30120 33545 35904 36594 36696 37322 37831 38527 38961 39786 39950 40640 40850 43942 45818 46585 47361 48407 49037 50540 50602 51623 52422 53120 53194 54309 55183 55291 55382 58117 61120 61365 63478 63597 64119 65625 65756 66010 66648 68766 70031 70467 71311 71675 72166 72224 72892 74053 75155 77374 80235 81375 83566 84818 85144 85209 87024 88032 88423 89345 89715 90411 90565 90632 92667 92928 93332 94259 94318 94705 95005 99232 99637 {BT.sort {BT.add 50000 {T}}} -> 432 433 1850 1926 2583 4213 5094 7772 7963 9575 9815 10126 10490 13011 18985 19018 19382 21647 22075 22162 23218 26503 27502 27592 27814 27816 27969 30120 33545 35904 36594 36696 37322 37831 38527 38961 39786 39950 40640 40850 43942 45818 46585 47361 48407 49037 50000 50540 50602 51623 52422 53120 53194 54309 55183 55291 55382 58117 61120 61365 63478 63597 64119 65625 65756 66010 66648 68766 70031 70467 71311 71675 72166 72224 72892 74053 75155 77374 80235 81375 83566 84818 85144 85209 87024 88032 88423 89345 89715 90411 90565 90632 92667 92928 93332 94259 94318 94705 95005 99232 99637 {BT.sort {BT.add 100000 {T}}} -> 432 433 1850 1926 2583 4213 5094 7772 7963 9575 9815 10126 10490 13011 18985 19018 19382 21647 22075 22162 23218 26503 27502 27592 27814 27816 27969 30120 33545 35904 36594 36696 37322 37831 38527 38961 39786 39950 40640 40850 43942 45818 46585 47361 48407 49037 50540 50602 51623 52422 53120 53194 54309 55183 55291 55382 58117 61120 61365 63478 63597 64119 65625 65756 66010 66648 68766 70031 70467 71311 71675 72166 72224 72892 74053 75155 77374 80235 81375 83566 84818 85144 85209 87024 88032 88423 89345 89715 90411 90565 90632 92667 92928 93332 94259 94318 94705 95005 99232 99637 100000 </syntaxhighlight> =={{header\|Lobster}}== <syntaxhighlight lang="lobster">include "std.lobster" def quicksort(xs, lt): if xs.length <= 1: xs else: pivot := xs[0] tail := xs.slice(1, -1) f1 := filter tail: lt(_, pivot) f2 := filter tail: !lt(_, pivot) append(append(quicksort(f1, lt), [ pivot ]), quicksort(f2, lt)) sorted := [ 3, 9, 5, 4, 1, 3, 9, 5, 4, 1 ].quicksort(): _a < _b print sorted</syntaxhighlight> =={{header\|Logo}}== <~~lang~~syntaxhighlight lang="logo">; quicksort (lists, functional) to small? :list Line 1,586 ⟶ 6,342: end show quicksort [1 3 5 7 9 8 6 4 2]</~~lang~~syntaxhighlight> <~~lang~~syntaxhighlight lang="logo">; quicksort (arrays, in-place) to incr :name Line 1,620 ⟶ 6,376: make "test {1 3 5 7 9 8 6 4 2} sort :test show :test</~~lang~~syntaxhighlight> =={{header\|Logtalk}}== <~~lang~~syntaxhighlight lang="logtalk">quicksort(List, Sorted) :- quicksort(List, [], Sorted). Line 1,639 ⟶ 6,395: ; Bigs = [X\| Rest], partition(Xs, Pivot, Smalls, Rest) ).</~~lang~~syntaxhighlight> =={{header\|Lua}}== NOTE: If you want to use quicksort in a Lua script, you don't need to implement it yourself. Just do: <pre>table.sort(tableName)</pre> ~~<lang lua>--in-place quicksort~~ ===in-place=== <syntaxhighlight lang="lua">--in-place quicksort function quicksort(t, start, endi) start, endi = start or 1, endi or #t --partition w.r.t. first element if(endi - start < 21) then return t end local pivot = start for i = start + 1, endi do if t[i] <= t[pivot] then ~~local~~if ~~temp~~i == t[pivot + 1] then t[pivot ],t[pivot+ 1] = t[pivot+1],t[pivot] ~~if(i == pivot + 1) then~~ ~~t[pivot] = temp~~ else t[pivot],t[pivot+1],t[i] = t[i],t[pivot],t[pivot+1] ~~t[i] = temp~~ end pivot = pivot + 1 Line 1,666 ⟶ 6,421: --example print(unpack(quicksort{5, 2, 7, 3, 4, 7, 1}))</~~lang~~syntaxhighlight> ===non in-place=== <syntaxhighlight lang="lua">function quicksort(t) if #t<2 then return t end local pivot=t[1] local a,b,c={},{},{} for _,v in ipairs(t) do if v<pivot then a[#a+1]=v elseif v>pivot then c[#c+1]=v else b[#b+1]=v end end a=quicksort(a) c=quicksort(c) for _,v in ipairs(b) do a[#a+1]=v end for _,v in ipairs(c) do a[#a+1]=v end return a end</syntaxhighlight> =={{header\|Lucid}}== [http://i.csc.uvic.ca/home/hei/lup/06.html] <~~lang~~syntaxhighlight lang="lucid">qsort(a) = if eof(first a) then a else follow(qsort(b0),qsort(b1)) fi where p = first a < a; Line 1,679 ⟶ 6,452: xdone = iseod x fby xdone or iseod x; end; end</~~lang~~syntaxhighlight> =={{header\|M2000 Interpreter}}== ===Recursive calling Functions=== <syntaxhighlight lang="m2000 interpreter"> Module Checkit1 { Group Quick { Private: Function partition { Read &A(), p, r x = A(r) i = p-1 For j=p to r-1 { If .LE(A(j), x) Then { i++ Swap A(i),A(j) } } Swap A(i+1),A(r) = i+1 } Public: LE=Lambda->Number<=Number Function quicksort { Read &A(), p, r If p < r Then { q = .partition(&A(), p, r) Call .quicksort(&A(), p, q - 1) Call .quicksort(&A(), q + 1, r) } } } Dim A(10)<<Random(50, 100) Print A() Call Quick.quicksort(&A(), 0, Len(A())-1) Print A() } Checkit1 </syntaxhighlight> ===Recursive calling Subs=== Variables p, r, q removed from quicksort function. we use stack for values. Also Partition push to stack now. Works for string arrays too. <syntaxhighlight lang="m2000 interpreter"> Module Checkit2 { Class Quick { Private: partition=lambda-> { Read &A(), p, r : i = p-1 : x=A(r) For j=p to r-1 {If .LE(A(j), x) Then i++:Swap A(i),A(j) } : Swap A(i+1), A(r) : Push i+1 } Public: LE=Lambda->Number<=Number Module ForStrings { .partition<=lambda-> { Read &A$(), p, r : i = p-1 : x$=A$(r) For j=p to r-1 {If A$(j)<= x$ Then i++:Swap A$(i),A$(j) } : Swap A$(i+1), A$(r) : Push i+1 } } Function quicksort (ref$) { myQuick() sub myQuick() If Stackitem() >= stackitem(2) Then drop 2 : Exit Sub Over 2, 2 : Call .partition(ref$) : Over : Shiftback 3, 2 myQuick(number, number - 1) myQuick( number + 1, number) End Sub } } Quick=Quick() Dim A(10) A(0):=57, 83, 74, 98, 51, 73, 85, 76, 65, 92 Print A() Call Quick.quicksort(&A(), 0, Len(A())-1) Print A() Quick=Quick() Quick.ForStrings Dim A$() A$()=("one","two", "three","four", "five") Print A$() Call Quick.quicksort(&A$(), 0, Len(A$())-1) Print A$() } Checkit2 </syntaxhighlight> ===Non Recursive=== Partition function return two values (where we want q, and use it as q-1 an q+1 now Partition() return final q-1 and q+1_ Example include numeric array, array of arrays (we provide a lambda for comparison) and string array. <syntaxhighlight lang="m2000 interpreter"> Module Checkit3 { Class Quick { Private: partition=lambda-> { Read &A(), p, r : i = p-1 : x=A(r) For j=p to r-1 {If .LE(A(j), x) Then i++:Swap A(i),A(j) } : Swap A(i+1), A(r) : Push i+2, i } Public: LE=Lambda->Number<=Number Module ForStrings { .partition<=lambda-> { Read &A$(), p, r : i = p-1 : x$=A$(r) For j=p to r-1 {If A$(j)<= x$ Then i++:Swap A$(i),A$(j) } : Swap A$(i+1), A$(r) : Push i+2, i } } Function quicksort { Read ref$ { loop : If Stackitem() >= Stackitem(2) Then Drop 2 : if empty then {Break} else continue over 2,2 : call .partition(ref$) :shift 3 } } } Quick=Quick() Dim A(10)<<Random(50, 100) Print A() Call Quick.quicksort(&A(), 0, Len(A())-1) Print A() Quick=Quick() Function join$(a$()) { n=each(a$(), 1, -2) k$="" while n { overwrite k$, ".", n^:=array$(n) } =k$ } Stack New { Data "1.3.6.1.4.1.11.2.17.19.3.4.0.4" , "1.3.6.1.4.1.11.2.17.19.3.4.0.1", "1.3.6.1.4.1.11150.3.4.0.1" Data "1.3.6.1.4.1.11.2.17.19.3.4.0.10", "1.3.6.1.4.1.11.2.17.5.2.0.79", "1.3.6.1.4.1.11150.3.4.0" Dim Base 0, arr(Stack.Size) Link arr() to arr$() i=0 : While not Empty {arr$(i)=piece$(letter$+".", ".") : i++ } } \\ change comparison function Quick.LE=lambda (a, b)->{ Link a, b to a$(), b$() def i=-1 do { i++ } until a$(i)="" or b$(i)="" or a$(i)<>b$(i) if b$(i)="" then =a$(i)="":exit if a$(i)="" then =true:exit =val(a$(i))<=val(b$(i)) } Call Quick.quicksort(&arr(), 0, Len(arr())-1) For i=0 to len(arr())-1 { Print join$(arr(i)) } \\ Fresh load Quick=Quick() Quick.ForStrings Dim A$() A$()=("one","two", "three","four", "five") Print A$() Call Quick.quicksort(&A$(), 0, Len(A$())-1) Print A$() } Checkit3 </syntaxhighlight> =={{header\|M4}}== <~~lang~~syntaxhighlight M4lang="m4">dnl return the first element of a list when called in the funny way seen below define(`arg1', `$1')dnl dnl Line 1,709 ⟶ 6,643: `sep(arg1$1,(shift$1),`()',`()')')')dnl dnl quicksort((3,1,4,1,5,9))</~~lang~~syntaxhighlight> {{out}} ~~Output:~~ <pre> (1,1,3,4,5,9) </pre> =={{header\|~~Mathematica~~Maclisp}}== <syntaxhighlight lang="lisp"> ;; While not strictly required, it simplifies the ;; implementation considerably to use filter. MACLisp ;; Doesn't have one out of the box, so we bring our own (DEFUN FILTER (F LIST) (COND ((EQ LIST NIL) NIL) ((FUNCALL F (CAR LIST)) (CONS (CAR LIST) (FILTER F (CDR LIST)))) (T (FILTER F (CDR LIST))))) ;; And then, quicksort. ~~<lang Mathematica>QuickSort[x_List] := Module[{pivot},~~ (DEFUN QUICKSORT (LIST) (COND ((OR (EQ LIST ()) (EQ (CDR LIST) ())) LIST) (T (LET ((PIVOT (CAR LIST)) (REST (CDR LIST))) (APPEND (QUICKSORT (FILTER #'(LAMBDA (X) (<= X PIVOT)) REST)) (LIST PIVOT) (QUICKSORT (FILTER #'(LAMBDA (X) (> X PIVOT)) REST))))))) </syntaxhighlight> =={{header\|Maple}}== <syntaxhighlight lang="maple">swap := proc(arr, a, b) local temp := arr[a]: arr[a] := arr[b]: arr[b] := temp: end proc: quicksort := proc(arr, low, high) local pi: if (low < high) then pi := qpart(arr,low,high): quicksort(arr, low, pi-1): quicksort(arr, pi+1, high): end if: end proc: qpart := proc(arr, low, high) local i,j,pivot; pivot := arr[high]: i := low-1: for j from low to high-1 by 1 do if (arr[j] <= pivot) then i++: swap(arr, i, j): end if; end do; swap(arr, i+1, high): return (i+1): end proc: a:=Array([12,4,2,1,0]); quicksort(a,1,5); a;</syntaxhighlight> {{Out\|Output}} <pre>[0, 1, 2, 4, 12]</pre> =={{header\|Mathematica}}/{{header\|Wolfram Language}}== <syntaxhighlight lang="mathematica">QuickSort[x_List] := Module[{pivot}, If[Length@x <= 1, Return[x]]; pivot = RandomChoice@x; Flatten@{QuickSort[Cases[x, j_ /; j < pivot]], Cases[x, j_ /; j == pivot], QuickSort[Cases[x, j_ /; j > pivot]]} ]</~~lang~~syntaxhighlight> <syntaxhighlight lang="mathematica">qsort[{}] = {}; qsort[{x_, xs___}] := Join[qsort@Select[{xs}, # <= x &], {x}, qsort@Select[{xs}, # > x &]];</syntaxhighlight> ~~<lang Mathematica>qsort[{}] = {};~~ <syntaxhighlight lang="mathematica">QuickSort[{}] := {} ~~qsort[{x_, xs___}] := Join[qsort@Select[{xs}, # <= x &], {x}, qsort@Select[{xs}, # > x &]];]</lang>~~ QuickSort[list: {__}] := With[{pivot=RandomChoice[list]}, Join[ <\|1->{}, -1->{}\|>, GroupBy[list,Order[#,pivot]&] ] // Catenate[ {QuickSort@#[1], #[0], QuickSort@#[-1]} ]& ]</syntaxhighlight> =={{header\|MATLAB}}== Line 1,732 ⟶ 6,730: This should be placed in a file named ''quickSort.m''. <~~lang~~syntaxhighlight ~~Matlab~~lang="matlab">function sortedArray = quickSort(array) if numel(array) <= 1 %If the array has 1 element then it can't be sorted Line 1,752 ⟶ 6,750: sortedArray = [quickSort(less) pivot quickSort(greater)]; end</~~lang~~syntaxhighlight> A slightly more vectorized version of the above code that removes the need for the ''less'' and ''greater'' arrays: <~~lang~~syntaxhighlight ~~Matlab~~lang="matlab">function sortedArray = quickSort(array) if numel(array) <= 1 %If the array has 1 element then it can't be sorted Line 1,767 ⟶ 6,765: sortedArray = [quickSort( array(array <= pivot) ) pivot quickSort( array(array > pivot) )]; end</~~lang~~syntaxhighlight> Sample usage: <~~lang~~syntaxhighlight ~~MATLAB~~lang="matlab">quickSort([4,3,7,-2,9,1]) ans = -2 1 3 4 7 9</~~lang~~syntaxhighlight> =={{header\|MAXScript}}== <~~lang~~syntaxhighlight lang="maxscript">fn quickSort arr = ( less = #() Line 1,804 ⟶ 6,802: ) a = #(4, 89, -3, 42, 5, 0, 2, 889) a = quickSort a</~~lang~~syntaxhighlight> =={{header\|Mercury}}== === A quicksort that works on linked lists === {{works with\|Mercury\|22.01.1}} <syntaxhighlight lang="mercury">%%%------------------------------------------------------------------- :- module quicksort_task_for_lists. :- interface. :- import_module io. :- pred main(io, io). :- mode main(di, uo) is det. :- implementation. :- import_module int. :- import_module list. %%%------------------------------------------------------------------- %%% %%% Partitioning a list into three: %%% %%% Left elements less than the pivot %%% Middle elements equal to the pivot %%% Right elements greater than the pivot %%% %%% The implementation is tail-recursive. %%% :- pred partition(comparison_func(T), T, list(T), list(T), list(T), list(T)). :- mode partition(in, in, in, out, out, out) is det. partition(Compare, Pivot, Lst, Left, Middle, Right) :- partition(Compare, Pivot, Lst, [], Left, [], Middle, [], Right). :- pred partition(comparison_func(T), T, list(T), list(T), list(T), list(T), list(T), list(T), list(T)). :- mode partition(in, in, in, in, out, in, out, in, out) is det. partition(_, _, [], Left0, Left, Middle0, Middle, Right0, Right) :- Left = Left0, Middle = Middle0, Right = Right0. partition(Compare, Pivot, [Head \| Tail], Left0, Left, Middle0, Middle, Right0, Right) :- Compare(Head, Pivot) = Cmp, (if (Cmp = (<)) then partition(Compare, Pivot, Tail, [Head \| Left0], Left, Middle0, Middle, Right0, Right) else if (Cmp = (=)) then partition(Compare, Pivot, Tail, Left0, Left, [Head \| Middle0], Middle, Right0, Right) else partition(Compare, Pivot, Tail, Left0, Left, Middle0, Middle, [Head \| Right0], Right)). %%%------------------------------------------------------------------- %%% %%% Quicksort using the first element as pivot. %%% %%% This is not the world's best choice of pivot, but it is the %%% easiest one to get from a linked list. %%% %%% This implementation is not tail-recursive--as most quicksort %%% implementations also are not. (However, do an online search on %%% "quicksort fortran 77" and you will find some "tail-recursive" %%% implementations, with the tail recursions expressed as gotos.) %%% :- func quicksort(comparison_func(T), list(T)) = list(T). quicksort(_, []) = []. quicksort(Compare, [Pivot \| Tail]) = Sorted_Lst :- partition(Compare, Pivot, Tail, Left, Middle, Right), quicksort(Compare, Left) = Sorted_Left, quicksort(Compare, Right) = Sorted_Right, Sorted_Left ++ [Pivot \| Middle] ++ Sorted_Right = Sorted_Lst. %%%------------------------------------------------------------------- :- func example_numbers = list(int). example_numbers = [1, 3, 9, 5, 8, 6, 5, 1, 7, 9, 8, 6, 4, 2]. :- func int_compare(int, int) = comparison_result. int_compare(I, J) = Cmp :- if (I < J) then (Cmp = (<)) else if (I = J) then (Cmp = (=)) else (Cmp = (>)). main(!IO) :- quicksort(int_compare, example_numbers) = Sorted_Numbers, print("unsorted: ", !IO), print_line(example_numbers, !IO), print("sorted: ", !IO), print_line(Sorted_Numbers, !IO). %%%------------------------------------------------------------------- %%% local variables: %%% mode: mercury %%% prolog-indent-width: 2 %%% end:</syntaxhighlight> {{out}} <pre>$ mmc quicksort_task_for_lists.m && ./quicksort_task_for_lists unsorted: [1, 3, 9, 5, 8, 6, 5, 1, 7, 9, 8, 6, 4, 2] sorted: [1, 1, 2, 3, 4, 5, 5, 6, 6, 7, 8, 8, 9, 9]</pre> === A quicksort that works on arrays === {{works with\|Mercury\|22.01.1}} The in-place partitioning algorithm here is similar to but not quite the same as that of the task pseudocode. I wrote it by referring to some Fortran code I wrote several months ago for a quickselect. (That quickselect had a random pivot, however.) <syntaxhighlight lang="mercury">%%%------------------------------------------------------------------- :- module quicksort_task_for_arrays. :- interface. :- import_module io. :- pred main(io, io). :- mode main(di, uo) is det. :- implementation. :- import_module array. :- import_module int. :- import_module list. %%%------------------------------------------------------------------- %%% %%% Partitioning a subarray into two halves: one with elements less %%% than or equal to a pivot, the other with elements greater than or %%% equal to a pivot. %%% %%% The implementation is tail-recursive. %%% :- pred partition(pred(T, T), T, int, int, array(T), array(T), int). :- mode partition(pred(in, in) is semidet, in, in, in, array_di, array_uo, out). partition(Less_than, Pivot, I_first, I_last, Arr0, Arr, I_pivot) :- I = I_first - 1, J = I_last + 1, partition_loop(Less_than, Pivot, I, J, Arr0, Arr, I_pivot). :- pred partition_loop(pred(T, T), T, int, int, array(T), array(T), int). :- mode partition_loop(pred(in, in) is semidet, in, in, in, array_di, array_uo, out). partition_loop(Less_than, Pivot, I, J, Arr0, Arr, Pivot_index) :- if (I = J) then (Arr = Arr0, Pivot_index = I) else (I1 = I + 1, I2 = search_right(Less_than, Pivot, I1, J, Arr0), (if (I2 = J) then (Arr = Arr0, Pivot_index = J) else (J1 = J - 1, J2 = search_left(Less_than, Pivot, I2, J1, Arr0), swap(I2, J2, Arr0, Arr1), partition_loop(Less_than, Pivot, I2, J2, Arr1, Arr, Pivot_index)))). :- func search_right(pred(T, T), T, int, int, array(T)) = int. :- mode search_right(pred(in, in) is semidet, in, in, in, in) = out is det. search_right(Less_than, Pivot, I, J, Arr0) = K :- if (I = J) then (I = K) else if Less_than(Pivot, Arr0^elem(I)) then (I = K) else (search_right(Less_than, Pivot, I + 1, J, Arr0) = K). :- func search_left(pred(T, T), T, int, int, array(T)) = int. :- mode search_left(pred(in, in) is semidet, in, in, in, in) = out is det. search_left(Less_than, Pivot, I, J, Arr0) = K :- if (I = J) then (J = K) else if Less_than(Arr0^elem(J), Pivot) then (J = K) else (search_left(Less_than, Pivot, I, J - 1, Arr0) = K). %%%------------------------------------------------------------------- %%% %%% Quicksort with median of three as pivot. %%% %%% Like most quicksort implementations, this one is not %%% tail-recursive. %%% %% quicksort/3 sorts an entire array. :- pred quicksort(pred(T, T), array(T), array(T)). :- mode quicksort(pred(in, in) is semidet, array_di, array_uo) is det. quicksort(Less_than, Arr0, Arr) :- bounds(Arr0, I_first, I_last), quicksort(Less_than, I_first, I_last, Arr0, Arr). %% quicksort/5 sorts a subarray. :- pred quicksort(pred(T, T), int, int, array(T), array(T)). :- mode quicksort(pred(in, in) is semidet, in, in, array_di, array_uo) is det. quicksort(Less_than, I_first, I_last, Arr0, Arr) :- if (I_last - I_first >= 2) then (median_of_three(Less_than, I_first, I_last, Arr0, Arr1, Pivot), %% Partition only from I_first to I_last - 1. partition(Less_than, Pivot, I_first, I_last - 1, Arr1, Arr2, K), %% Now everything that is less than the pivot is to the %% left of K. %% Put the pivot at K, moving the element that had been there %% to the end. If K = I_last, then this element is actually %% garbage and will be overwritten with the pivot, which turns %% out to be the greatest element. Otherwise, the moved %% element is not less than the pivot and so the partitioning %% is preserved. Arr2^elem(K) = Elem_to_move, (Arr2^elem(I_last) := Elem_to_move) = Arr3, (Arr3^elem(K) := Pivot) = Arr4, %% Sort the subarray on either side of the pivot. quicksort(Less_than, I_first, K - 1, Arr4, Arr5), quicksort(Less_than, K + 1, I_last, Arr5, Arr)) else if (I_last - I_first = 1) % Two elements. then (Elem_first = Arr0^elem(I_first), Elem_last = Arr0^elem(I_last), (if Less_than(Elem_first, Elem_last) then (Arr = Arr0) else ((Arr0^elem(I_first) := Elem_last) = Arr1, (Arr1^elem(I_last) := Elem_first) = Arr))) else (Arr = Arr0). % Zero or one element. %% median_of_three/6 both chooses a pivot and rearranges the array %% elements so one may partition them from I_first to I_last - 1, %% leaving the pivot element out of the array. :- pred median_of_three(pred(T, T), int, int, array(T), array(T), T). :- mode median_of_three(pred(in, in) is semidet, in, in, array_di, array_uo, out) is det. median_of_three(Less_than, I_first, I_last, Arr0, Arr, Pivot) :- I_middle = I_first + ((I_last - I_first) // 2), Elem_first = Arr0^elem(I_first), Elem_middle = Arr0^elem(I_middle), Elem_last = Arr0^elem(I_last), (if pred_xor(Less_than, Less_than, Elem_middle, Elem_first, Elem_last, Elem_first) then (Pivot = Elem_first, (if Less_than(Elem_middle, Elem_last) then (Arr1 = (Arr0^elem(I_first) := Elem_middle), Arr = (Arr1^elem(I_middle) := Elem_last)) else (Arr = (Arr0^elem(I_first) := Elem_last)))) else if pred_xor(Less_than, Less_than, Elem_middle, Elem_first, Elem_middle, Elem_last) then (Pivot = Elem_middle, (if Less_than(Elem_first, Elem_last) then (Arr = (Arr0^elem(I_middle) := Elem_last)) else (Arr1 = (Arr0^elem(I_first) := Elem_last), Arr = (Arr1^elem(I_middle) := Elem_first)))) else (Pivot = Elem_last, (if Less_than(Elem_first, Elem_middle) then (Arr = Arr0) else (Arr1 = (Arr0^elem(I_first) := Elem_middle), Arr = (Arr1^elem(I_middle) := Elem_first))))). :- pred pred_xor(pred(T, T), pred(T, T), T, T, T, T). :- mode pred_xor(pred(in, in) is semidet, pred(in, in) is semidet, in, in, in, in) is semidet. pred_xor(P, Q, W, X, Y, Z) :- if P(W, X) then (not Q(Y, Z)) else Q(Y, Z). %%%------------------------------------------------------------------- :- func example_numbers = list(int). example_numbers = [1, 3, 9, 5, 8, 6, 5, 0, 1, 7, 9, 8, 6, 4, 2, -28, 30, 31, 1, 3, 9, 5, 8, 6, 5, 1, 6, 4, 2, -28, 30, -50, 500, -1234, 1234, 12]. main(!IO) :- (array.from_list(example_numbers, Arr0)), print_line("", !IO), print_line(Arr0, !IO), print_line("", !IO), print_line(" \|", !IO), print_line(" V", !IO), print_line("", !IO), quicksort(<, Arr0, Arr1), print_line(Arr1, !IO), print_line("", !IO). %%%------------------------------------------------------------------- %%% local variables: %%% mode: mercury %%% prolog-indent-width: 2 %%% end:</syntaxhighlight> {{out}} <pre>$ mmc quicksort_task_for_arrays.m && ./quicksort_task_for_arrays array([1, 3, 9, 5, 8, 6, 5, 0, 1, 7, 9, 8, 6, 4, 2, -28, 30, 31, 1, 3, 9, 5, 8, 6, 5, 1, 6, 4, 2, -28, 30, -50, 500, -1234, 1234, 12]) \| V array([-1234, -50, -28, -28, 0, 1, 1, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 7, 8, 8, 8, 9, 9, 9, 12, 30, 30, 31, 500, 1234]) </pre> =={{header\|MiniScript}}== Quick implementation for Miniscript, simply goes through the list reference and swaps the positions <syntaxhighlight lang="miniscript">Partition = function(a, low, high) pivot = a[low] leftwall = low for i in range(low + 1, high) if a[i] < pivot then leftwall = leftwall + 1 temp = a[leftwall] a[leftwall] = a[i] a[i] = temp end if end for temp = a[leftwall] a[leftwall] = pivot a[low] = temp return leftwall end function QuickSort = function(a, low=null, high=null) if not low then low = 0 if not high then high = a.len - 1 if low < high then pivot_location = Partition(a, low, high) QuickSort a, low, pivot_location - 1 QuickSort a, pivot_location + 1, high end if return a end function print QuickSort([3, 5, 2, 4, 1]) </syntaxhighlight> {{out}} <pre>[1, 2, 3, 4, 5]</pre> =={{header\|Miranda}}== <syntaxhighlight lang="miranda">main :: [sys_message] main = [Stdout ("Before: " ++ show testlist ++ "\n"), Stdout ("After: " ++ show (quicksort testlist) ++ "\n")] where testlist = [4,65,2,-31,0,99,2,83,782,1] quicksort [] = [] quicksort [x] = [x] quicksort xs = (quicksort less) ++ equal ++ (quicksort more) where pivot = hd xs less = [x \| x<-xs; x<pivot] equal = [x \| x<-xs; x=pivot] more = [x \| x<-xs; x>pivot]</syntaxhighlight> {{out}} <pre>Before: [4,65,2,-31,0,99,2,83,782,1] After: [-31,0,1,2,2,4,65,83,99,782]</pre> =={{header\|Modula-2}}== Line 1,816 ⟶ 7,188: The ISO standard for the "Generic Modula-2" language extension provides genericity without the chink, but most compilers have not implemented this extension. <~~lang~~syntaxhighlight ~~Modula2~~lang="modula2">(#####################) DEFINITION MODULE QSORT; (#####################) Line 1,827 ⟶ 7,199: Compare:CmpFuncPtrs); END QSORT. </~~lang~~syntaxhighlight> The implementation module is not visible to clients, so it may be changed without worry so long as it still implements the definition. Line 1,833 ⟶ 7,205: Sedgewick suggests that faster sorting will be achieved if you drop back to an insertion sort once the partitions get small. <~~lang~~syntaxhighlight ~~Modula2~~lang="modula2">(##########################) IMPLEMENTATION MODULE QSORT; (##########################) Line 1,960 ⟶ 7,332: END QSORT. </syntaxhighlight> ~~</lang>~~ =={{header\|Modula-3}}== This code is taken from libm3, which is basically Modula-3's "standard library". Note that this code uses Insertion sort when the array is less than 9 elements long. <~~lang~~syntaxhighlight lang="modula3">GENERIC INTERFACE ArraySort(Elem); PROCEDURE Sort(VAR a: ARRAY OF Elem.T; cmp := Elem.Compare); END ArraySort.</~~lang~~syntaxhighlight> <~~lang~~syntaxhighlight lang="modula3">GENERIC MODULE ArraySort (Elem); PROCEDURE Sort (VAR a: ARRAY OF Elem.T; cmp := Elem.Compare) = Line 2,057 ⟶ 7,429: BEGIN END ArraySort.</~~lang~~syntaxhighlight> To use this generic code to sort an array of text, we create two files called TextSort.i3 and TextSort.m3, respectively. <~~lang~~syntaxhighlight lang="modula3">INTERFACE TextSort = ArraySort(Text) END TextSort.</~~lang~~syntaxhighlight> <~~lang~~syntaxhighlight lang="modula3">MODULE TextSort = ArraySort(Text) END TextSort.</~~lang~~syntaxhighlight> Then, as an example: <~~lang~~syntaxhighlight lang="modula3">MODULE Main; IMPORT IO, TextSort; Line 2,077 ⟶ 7,449: IO.Put(arr[i] & "\n"); END; END Main.</~~lang~~syntaxhighlight> =={{header\|Mond}}== Implements the simple quicksort algorithm. <syntaxhighlight lang="mond">fun quicksort( arr, cmp ) { if( arr.length() < 2 ) return arr; if( !cmp ) cmp = ( a, b ) -> a - b; var a = [ ], b = [ ]; var pivot = arr[0]; var len = arr.length(); for( var i = 1; i < len; ++i ) { var item = arr[i]; if( cmp( item, pivot ) < cmp( pivot, item ) ) a.add( item ); else b.add( item ); } a = quicksort( a, cmp ); b = quicksort( b, cmp ); a.add( pivot ); foreach( var item in b ) a.add( item ); return a; }</syntaxhighlight> ;Usage <syntaxhighlight lang="mond">var array = [ 532, 16, 153, 3, 63.60, 925, 0.214 ]; var sorted = quicksort( array ); printLn( sorted );</syntaxhighlight> {{out}} <pre>[ 0.214, 3, 16, 63.6, 153, 532, 925 ]</pre> =={{header\|MUMPS}}== Shows quicksort on a 16-element array. <syntaxhighlight lang="mumps"> main new collection,size set size=16 set collection=size for i=0:1:size-1 set collection(i)=$random(size) write "Collection to sort:",!! zwrite collection ; This will only work on Intersystem's flavor of MUMPS do quicksort(.collection,0,collection-1) write:$$isSorted(.collection) !,"Collection is sorted:",!! zwrite collection ; This will only work on Intersystem's flavor of MUMPS q quicksort(array,low,high) if low<high do . set pivot=$$partition(.array,low,high) . do quicksort(.array,low,pivot-1) . do quicksort(.array,pivot+1,high) q partition(A,p,r) set pivot=A(r) set i=p-1 for j=p:1:r-1 do . i A(j)<=pivot do . . set i=i+1 . . set helper=A(j) . . set A(j)=A(i) . . set A(i)=helper set helper=A(r) set A(r)=A(i+1) set A(i+1)=helper quit i+1 isSorted(array) set sorted=1 for i=0:1:array-2 do quit:sorted=0 . for j=i+1:1:array-1 do quit:sorted=0 . . set:array(i)>array(j) sorted=0 quit sorted </syntaxhighlight> ;Usage <syntaxhighlight lang="mumps"> do main()</syntaxhighlight> {{out}} <pre> Collection to sort: collection=16 collection(0)=4 collection(1)=0 collection(2)=6 collection(3)=14 collection(4)=4 collection(5)=0 collection(6)=10 collection(7)=5 collection(8)=11 collection(9)=4 collection(10)=12 collection(11)=9 collection(12)=13 collection(13)=4 collection(14)=14 collection(15)=0 Collection is sorted: collection=16 collection(0)=0 collection(1)=0 collection(2)=0 collection(3)=4 collection(4)=4 collection(5)=4 collection(6)=4 collection(7)=5 collection(8)=6 collection(9)=9 collection(10)=10 collection(11)=11 collection(12)=12 collection(13)=13 collection(14)=14 collection(15)=14 </pre> =={{header\|Nanoquery}}== {{trans\|Python}} <syntaxhighlight lang="nanoquery">def quickSort(arr) less = {} pivotList = {} more = {} if len(arr) <= 1 return arr else pivot = arr[0] for i in arr if i < pivot less.append(i) else if i > pivot more.append(i) else pivotList.append(i) end end less = quickSort(less) more = quickSort(more) return less + pivotList + more end end</syntaxhighlight> =={{header\|Nemerle}}== {{trans\|Haskell}} A little less clean and concise than Haskell, but essentially the same. <~~lang~~syntaxhighlight ~~Nemerle~~lang="nemerle">using System; using System.Console; using Nemerle.Collections.NList; Line 2,104 ⟶ 7,648: WriteLine(Qsort(several)); } }</~~lang~~syntaxhighlight> =={{header\|NetRexx}}== This sample implements both the '''simple''' and '''in place''' algorithms as described in the task's description: <~~lang~~syntaxhighlight ~~NetRexx~~lang="netrexx">/* NetRexx / options replace format comments java crossref savelog symbols binary Line 2,208 ⟶ 7,752: return ixStore </syntaxhighlight> ~~</lang>~~ {{out}} ~~;Output~~ <pre> UK London Line 2,241 ⟶ 7,785: =={{header\|Nial}}== <~~lang~~syntaxhighlight lang="nial">quicksort is fork [ >= [1 first,tally], pass, link [ Line 2,248 ⟶ 7,792: quicksort sublist [ > [pass,first], pass ] ] ]</~~lang~~syntaxhighlight> Using it. <~~lang~~syntaxhighlight lang="nial">\|quicksort [5, 8, 7, 4, 3] =3 4 5 7 8</~~lang~~syntaxhighlight> =={{header\|~~Nimrod~~Nim}}== ~~<lang python>proc QuickSort(list: seq[int]): seq[int] =~~ ~~if len(list) == 0:~~ ~~return @[]~~ ~~var pivot = list[0]~~ ~~var left: seq[int] = @[]~~ ~~var right: seq[int] = @[]~~ ~~for i in low(list)+1..high(list):~~ ~~if list[i] <= pivot:~~ ~~left.add(list[i])~~ ~~elif list[i] > pivot:~~ ~~right.add(list[i])~~ ~~result = QuickSort(left)~~ ~~result.add(pivot)~~ ~~result.add(QuickSort(right))</lang>~~ ==={{header\|Procedural (in place) algorithm }} === ~~Usage:~~ <syntaxhighlight lang="nim">proc quickSortImpl[T](a: var openarray[T], start, stop: int) = ~~<lang python>var sorted: seq[int] = QuickSort(@[5,2,1,6,2,3,1,2,123,21,54,6,1])~~ if stop - start > 0: ~~for i in items(sorted):~~ let pivot = a[start] ~~echo(i)</lang>~~ var left = start var right = stop while left <= right: while cmp(a[left], pivot) < 0: inc(left) while cmp(a[right], pivot) > 0: dec(right) if left <= right: swap(a[left], a[right]) inc(left) dec(right) quickSortImpl(a, start, right) quickSortImpl(a, left, stop) proc quickSort[T](a: var openarray[T]) = quickSortImpl(a, 0, a.len - 1) var a = @[4, 65, 2, -31, 0, 99, 2, 83, 782] a.quickSort() echo a</syntaxhighlight> ==={{header\|Functional (inmmutability) algorithm }} === <syntaxhighlight lang="nim">import sequtils,sugar func sorted[T](xs:seq[T]): seq[T] = if xs.len==0: @[] else: concat( xs[1..^1].filter(x=>x<xs[0]).sorted, @[xs[0]], xs[1..^1].filter(x=>x>=xs[0]).sorted ) @[4, 65, 2, -31, 0, 99, 2, 83, 782].sorted.echo</syntaxhighlight> {{out}} <pre>@[-31, 0, 2, 2, 4, 65, 83, 99, 782]</pre> =={{header\|Nix}}== <syntaxhighlight lang="nix"> let qs = l: if l == [] then [] else with builtins; let x = head l; xs = tail l; low = filter (a: a < x) xs; high = filter (a: a >= x) xs; in qs low ++ [x] ++ qs high; in qs [4 65 2 (-31) 0 99 83 782] </syntaxhighlight> {{out}} <pre>[ -31 0 2 4 65 83 99 782 ]</pre> =={{header\|Oberon-2}}== {{trans\|Pascal}} <syntaxhighlight lang="oberon2">MODULE QS; IMPORT Out; TYPE TItem = INTEGER; CONST N = 10; VAR I:LONGINT; A:ARRAY N OF INTEGER; PROCEDURE Init(VAR A:ARRAY OF TItem); BEGIN A[0] := 4; A[1] := 65; A[2] := 2; A[3] := -31; A[4] := 0; A[5] := 99; A[6] := 2; A[7] := 83; A[8] := 782; A[9] := 1; END Init; PROCEDURE QuickSort(VAR A:ARRAY OF TItem; Left,Right:LONGINT); VAR I,J:LONGINT; Pivot,Temp:TItem; BEGIN I := Left; J := Right; Pivot := A[(Left + Right) DIV 2]; REPEAT WHILE Pivot > A[I] DO INC(I) END; WHILE Pivot < A[J] DO DEC(J) END; IF I <= J THEN Temp := A[I]; A[I] := A[J]; A[J] := Temp; INC(I); DEC(J); END; UNTIL I > J; IF Left < J THEN QuickSort(A, Left, J) END; IF I < Right THEN QuickSort(A, I, Right) END; END QuickSort; BEGIN Init(A); FOR I := 0 TO LEN(A)-1 DO Out.Int(A[I], 0); Out.Char(' '); END; Out.Ln; QuickSort(A, 0, LEN(A)-1); FOR I := 0 TO LEN(A)-1 DO Out.Int(A[I], 0); Out.Char(' '); END; Out.Ln; END QS. </syntaxhighlight> =={{header\|Objeck}}== <~~lang~~syntaxhighlight lang="objeck"> class QuickSort { function : Main(args : String[]) ~ Nil { Line 2,327 ⟶ 7,966: } } </syntaxhighlight> ~~</lang>~~ =={{header\|Objective -C}}== The [http://weblog.bignerdranch.com/398-objective-c-literals-part-1/ latest XCode compiler] is assumed with [http://en.wikipedia.org/wiki/Automatic_Reference_Counting ARC] enabled. <~~lang~~syntaxhighlight lang="objc">void quicksortInPlace(NSMutableArray array, ~~const long~~NSInteger first, ~~const long~~NSInteger last, NSComparator comparator) { if (first >= last) return; ~~NSValue~~id pivot = array[(first + last) / 2]; ~~long~~NSInteger left = first; ~~long~~NSInteger right = last; while (left <= right) { while ([comparator(array[left], ~~isLessThan:~~pivot]) == NSOrderedAscending) left++; while ([comparator(array[right], ~~isGreaterThan:~~pivot]) == NSOrderedDescending) right--; if (left <= right) [array exchangeObjectAtIndex:left++ withObjectAtIndex:right--]; } quicksortInPlace(array, first, right, comparator); quicksortInPlace(array, left, last, comparator); } NSArray quicksort(NSArray unsorted, NSComparator comparator) { NSMutableArray a = [NSMutableArray arrayWithArray:unsorted]; quicksortInPlace(a, 0, a.count - 1, comparator); return a; } Line 2,358 ⟶ 7,997: NSArray a = @[ @1, @3, @5, @7, @9, @8, @6, @4, @2 ]; NSLog(@"Unsorted: %@", a); NSLog(@"Sorted: %@", quicksort(a, ^(id x, id y) { return [x compare:y]; })); NSArray b = @[ @"Emil", @"Peg", @"Helen", @"Juergen", @"David", @"Rick", @"Barb", @"Mike", @"Tom" ]; NSLog(@"Unsorted: %@", b); NSLog(@"Sorted: %@", quicksort(b, ^(id x, id y) { return [x compare:y]; })); } return 0; }</~~lang~~syntaxhighlight> {{out}} <pre>Unsorted: ( Line 2,412 ⟶ 8,051: =={{header\|OCaml}}== ~~<lang ocaml>let rec quicksort gt = function~~ ===Declarative and purely functional=== <syntaxhighlight lang="ocaml">let rec quicksort gt = function \| [] -> [] \| x::xs -> Line 2,419 ⟶ 8,061: let _ = quicksort (>) [4; 65; 2; -31; 0; 99; 83; 782; 1]</~~lang~~syntaxhighlight> The list based implementation is elegant and perspicuous, but inefficient in time (because <code>partition</code> and <code>@</code> are linear) and in space (since it creates numerous new lists along the way). ===Imperative and in place=== Using aliased array slices from the [https://c-cube.github.io/ocaml-containers/2.6/containers/CCArray_slice/index.html Containers library]. <syntaxhighlight lang="ocaml"> module Slice = CCArray_slice let quicksort : int Array.t -> unit = fun arr -> let rec quicksort' : int Slice.t -> unit = fun slice -> let len = Slice.length slice in if len > 1 then begin let pivot = Slice.get slice (len / 2) and i = ref 0 and j = ref (len - 1) in while !i < !j do while Slice.get slice !i < pivot do incr i done; while Slice.get slice !j > pivot do decr j done; if !i < !j then begin let i_val = Slice.get slice !i in Slice.set slice !i (Slice.get slice !j); Slice.set slice !j i_val; incr i; decr j; end done; quicksort' (Slice.sub slice 0 !i); quicksort' (Slice.sub slice !i (len - !i)); end in (* Take the array into an aliased array slice ) Slice.full arr \|> quicksort' </syntaxhighlight> =={{header\|Octave}}== {{trans\|MATLAB}} (The MATLAB version works as is in Octave, provided that the code is put in a file named <tt>quicksort.m</tt>, and everything below the <tt>return</tt> must be typed in the prompt of course) <~~lang~~syntaxhighlight lang="octave">function f=quicksort(v) % v must be a column vector f = v; n=length(v); if(n > 1) Line 2,435 ⟶ 8,116: N=30; v=rand(N,1); tic,u=quicksort(v); toc u</~~lang~~syntaxhighlight> =={{header\|Oforth}}== Oforth built-in sort uses quick sort algorithm (see lang/collect/ListBuffer.of for implementation) : <syntaxhighlight lang="oforth">[ 5, 8, 2, 3, 4, 1 ] sort</syntaxhighlight> =={{header\|Ol}}== <syntaxhighlight lang="scheme"> (define (quicksort l ??) (if (null? l) '() (append (quicksort (filter (lambda (x) (?? (car l) x)) (cdr l)) ??) (list (car l)) (quicksort (filter (lambda (x) (not (?? (car l) x))) (cdr l)) ??)))) (print (quicksort (list 1 3 5 9 8 6 4 3 2) >)) (print (quicksort (iota 100) >)) (print (quicksort (iota 100) <)) </syntaxhighlight> {{Out}} <pre> (1 2 3 3 4 5 6 8 9) (0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99) (99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0) </pre> =={{header\|ooRexx}}== {{trans\|Python}} <syntaxhighlight lang="oorexx"> a = .array~Of(4, 65, 2, -31, 0, 99, 83, 782, 1) ~~<lang ooRexx>~~ say 'before:' a~toString( ,', ') ~~a = .array~Of(4, 65, 2, -31, 0, 99, 83, 782, 1)~~ a = quickSort(a) say ' after:' a~toString( ,', ') exit Line 2,465 ⟶ 8,175: more = quickSort(more) return less~~appendAll(pivotList)~~appendAll(more) end</~~lang~~syntaxhighlight> {{out}} <pre>before: 4, 65, 2, -31, 0, 99, 83, 782, 1 after: -31, 0, 1, 2, 4, 65, 83, 99, 782 </pre> =={{header\|Oz}}== <~~lang~~syntaxhighlight lang="oz">declare fun {QuickSort Xs} case Xs of nil then nil Line 2,480 ⟶ 8,193: end in {Show {QuickSort [3 1 4 1 5 9 2 6 5]}}</~~lang~~syntaxhighlight> =={{header\|PARI/GP}}== <~~lang~~syntaxhighlight lang="parigp">quickSort(v)={ if(#v<2, return(v)); my(less=List(),more=List(),same=List(),pivot); Line 2,497 ⟶ 8,210: median(v)={ vecsort(v)[#v>>1] };</~~lang~~syntaxhighlight> =={{header\|Pascal}}== {{works with\|FPC}} ~~<lang pascal>~~ <syntaxhighlight lang="pascal"> ~~{ X is array of LongInt }~~ program QSortDemo; ~~Procedure QuickSort ( Left, Right : LongInt );~~ ~~Var~~ {$mode objfpc}{$h+}{$b-} ~~i, j : LongInt;~~ ~~tmp, pivot : LongInt; { tmp & pivot are the same type as the elements of array }~~ procedure QuickSort(var A: array of Integer); ~~Begin~~ procedure QSort(L, R: Integer); ~~i:=Left;~~ var ~~j:=Right;~~ I, J, Tmp, Pivot: Integer; ~~pivot := X[(Left + Right) shr 1]; // pivot := X[(Left + Rigth) div 2]~~ ~~Repeat~~begin ~~While~~if ~~pivot~~R >- ~~X[i]~~L Do< ~~i:=i+~~1 then exit; ~~While~~I ~~pivot~~:= <L; ~~X[j]~~J ~~Do j~~:=~~j-1~~ R; {$push}{$q-}{$r-}Pivot := A[(L + R) shr 1];{$pop} ~~If i<j Then Begin~~ ~~tmp:=X[i];~~repeat Xwhile A[~~i]:=X[j~~I] < Pivot do Inc(I); Xwhile A[jJ]~~:=tmp~~ > Pivot do Dec(J); j:if I <=~~j-1;~~ J then begin i Tmp :=~~i+1~~ A[I]; ~~End~~ A[I] := A[J]; A[J] := Tmp; ~~Until i>j;~~ Inc(I); Dec(J); ~~If Left<j Then QuickSort(Left,j);~~ end; ~~If i<Right Then QuickSort(i,Right);~~ until I > J; ~~End;~~ QSort(L, J); ~~</lang>~~ QSort(I, R); end; begin QSort(0, High(A)); end; procedure PrintArray(const A: array of Integer); var I: Integer; begin Write('['); for I := 0 to High(A) - 1 do Write(A[I], ', '); WriteLn(A[High(A)], ']'); end; var a: array[-7..6] of Integer = (-34, -20, 30, 13, 36, -10, 5, -25, 9, 19, 35, -50, 29, 11); begin QuickSort(a); PrintArray(a); end. </syntaxhighlight> {{out}} <pre> [-50, -34, -25, -20, -10, 5, 9, 11, 13, 19, 29, 30, 35, 36] </pre> =={{header\|Perl}}== <~~lang~~syntaxhighlight lang="perl"> sub quick_sort { myreturn @a_ =if @_ < 2; ~~return~~my @a$p if= splice @a_, <int rand @_, 21; quick_sort(grep $_ < $p, @_), $p, quick_sort(grep $_ >= $p, @_); ~~my $p = pop @a;~~ ~~quick_sort(grep $_ < $p, @a), $p, quick_sort(grep $_ >= $p, @a);~~ } Line 2,538 ⟶ 8,277: @a = quick_sort @a; print "@a\n"; </syntaxhighlight> ~~</lang>~~ =={{header\|~~Perl 6~~Phix}}== <!--<syntaxhighlight lang="phix">(phixonline)--> ~~<lang perl6># Empty list sorts to the empty list~~ <span style="color: #008080;">with</span> <span style="color: #008080;">javascript_semantics</span> ~~multi quicksort([]) { () }~~ <span style="color: #008080;">function</span> <span style="color: #000000;">quick_sort</span><span style="color: #0000FF;">(</span><span style="color: #004080;">sequence</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">)</span> ~~# Otherwise, extract first item as pivot...~~ <span style="color: #000080;font-style:italic;">-- ~~multi quicksort([$pivot, @rest]) {~~ -- put x into ascending order using recursive quick sort ~~# Partition.~~ --</span> ~~my @before := @rest.grep(* before $pivot);~~ <span style="color: #004080;">integer</span> <span style="color: #000000;">n</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">length</span><span style="color: #0000FF;">(</span><span style="color: #000000;">x</span><span style="color: #0000FF;">)</span> ~~my @after := @rest.grep(* !before $pivot);~~ <span style="color: #008080;">if</span> <span style="color: #000000;">n</span><span style="color: #0000FF;"><</span><span style="color: #000000;">2</span> <span style="color: #008080;">then</span> <span style="color: #008080;">return</span> <span style="color: #000000;">x</span> <span style="color: #000080;font-style:italic;">-- already sorted (trivial case)</span> ~~# Sort the partitions.~~ <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> ~~(quicksort(@before), $pivot, quicksort(@after))~~ ~~}</lang>~~ <span style="color: #004080;">integer</span> <span style="color: #000000;">mid</span> <span style="color: #0000FF;">=</span> <span style="color: #7060A8;">floor</span><span style="color: #0000FF;">((</span><span style="color: #000000;">n</span><span style="color: #0000FF;">+</span><span style="color: #000000;">1</span><span style="color: #0000FF;">)/</span><span style="color: #000000;">2</span><span style="color: #0000FF;">),</span> ~~Note that <code>@before</code> and <code>@after</code> are bound to lazy lists, so the partitions can (at least in theory) be sorted in parallel.~~ <span style="color: #000000;">last</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">1</span> <span style="color: #004080;">object</span> <span style="color: #000000;">midval</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">mid</span><span style="color: #0000FF;">]</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">mid</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">1</span><span style="color: #0000FF;">]</span> <span style="color: #008080;">for</span> <span style="color: #000000;">i</span><span style="color: #0000FF;">=</span><span style="color: #000000;">2</span> <span style="color: #008080;">to</span> <span style="color: #000000;">n</span> <span style="color: #008080;">do</span> <span style="color: #004080;">object</span> <span style="color: #000000;">xi</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">i</span><span style="color: #0000FF;">]</span> <span style="color: #008080;">if</span> <span style="color: #000000;">xi</span><span style="color: #0000FF;"><</span><span style="color: #000000;">midval</span> <span style="color: #008080;">then</span> <span style="color: #000000;">last</span> <span style="color: #0000FF;">+=</span> <span style="color: #000000;">1</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">i</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">last</span><span style="color: #0000FF;">]</span> <span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">last</span><span style="color: #0000FF;">]</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">xi</span> <span style="color: #008080;">end</span> <span style="color: #008080;">if</span> <span style="color: #008080;">end</span> <span style="color: #008080;">for</span> <span style="color: #008080;">return</span> <span style="color: #000000;">quick_sort</span><span style="color: #0000FF;">(</span><span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">2</span><span style="color: #0000FF;">..</span><span style="color: #000000;">last</span><span style="color: #0000FF;">])</span> <span style="color: #0000FF;">&</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">midval</span><span style="color: #0000FF;">}</span> <span style="color: #0000FF;">&</span> <span style="color: #000000;">quick_sort</span><span style="color: #0000FF;">(</span><span style="color: #000000;">x</span><span style="color: #0000FF;">[</span><span style="color: #000000;">last</span><span style="color: #0000FF;">+</span><span style="color: #000000;">1</span><span style="color: #0000FF;">..</span><span style="color: #000000;">n</span><span style="color: #0000FF;">])</span> <span style="color: #008080;">end</span> <span style="color: #008080;">function</span> <span style="color: #0000FF;">?</span><span style="color: #000000;">quick_sort</span><span style="color: #0000FF;">({</span><span style="color: #000000;">5</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"oranges"</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"and"</span><span style="color: #0000FF;">,</span><span style="color: #000000;">3</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"apples"</span><span style="color: #0000FF;">})</span> <!--</syntaxhighlight>--> {{out}} <pre> {3,5,"and","apples","oranges"} </pre> =={{header\|PHP}}== <~~lang~~syntaxhighlight lang="php">function quicksort($arr){ $~~loe~~lte = $gt = array(); if(count($arr) < 2){ return $arr; Line 2,565 ⟶ 8,325: foreach($arr as $val){ if($val <= $pivot){ $~~loe~~lte[] = $val; }~~elseif~~ ~~($val~~else ~~> $pivot)~~{ $gt[] = $val; } } return array_merge(quicksort($~~loe~~lte),array($pivot_key=>$pivot),quicksort($gt)); } $arr = array(1, 3, 5, 7, 9, 8, 6, 4, 2); $arr = quicksort($arr); echo implode(',',$arr);</~~lang~~syntaxhighlight> <pre>1,2,3,4,5,6,7,8,9</pre> <syntaxhighlight lang="php"> function quickSort(array $array) { // base case if (empty($array)) { return $array; } $head = array_shift($array); $tail = $array; $lesser = array_filter($tail, function ($item) use ($head) { return $item <= $head; }); $bigger = array_filter($tail, function ($item) use ($head) { return $item > $head; }); return array_merge(quickSort($lesser), [$head], quickSort($bigger)); } $testCase = [1, 4, 8, 2, 8, 0, 2, 8]; $result = quickSort($testCase); echo sprintf("[%s] ==> [%s]\n", implode(', ', $testCase), implode(', ', $result)); </syntaxhighlight> <pre>[1, 4, 8, 2, 8, 0, 2, 8] ==> [0, 1, 2, 2, 4, 8, 8, 8]</pre> =={{header\|Picat}}== ===Function=== <syntaxhighlight lang="picat">qsort([]) = []. qsort([H\|T]) = qsort([E : E in T, E =< H]) ++ [H] ++ qsort([E : E in T, E > H]).</syntaxhighlight> ===Recursion=== {{trans\|Prolog}} <syntaxhighlight lang="picat">qsort( [], [] ). qsort( [H\|U], S ) :- splitBy(H, U, L, R), qsort(L, SL), qsort(R, SR), append(SL, [H\|SR], S). % splitBy( H, U, LS, RS ) % True if LS = { L in U \| L <= H }; RS = { R in U \| R > H } splitBy( _, [], [], []). splitBy( H, [U\|T], [U\|LS], RS ) :- U =< H, splitBy(H, T, LS, RS). splitBy( H, [U\|T], LS, [U\|RS] ) :- U > H, splitBy(H, T, LS, RS).</syntaxhighlight> =={{header\|PicoLisp}}== <~~lang~~syntaxhighlight lang="lisp">(de quicksort (L) (if (cdr L) (let Pivot (car L) Line 2,585 ⟶ 8,389: (filter '((A) (= A Pivot)) L ) (quicksort (filter '((A) (> A Pivot)) (cdr L)))) ) L) )</~~lang~~syntaxhighlight> =={{header\|PL/I}}== <~~lang~~syntaxhighlight lang="pli">DCL (T(20)) FIXED BIN(31); /* scratch space of length N / QUICKSORT: PROCEDURE (A,AMIN,AMAX,N) RECURSIVE ; Line 2,636 ⟶ 8,440: END MINMAX; CALL MINMAX(A,AMIN,AMAX,N); CALL QUICKSORT(A,AMIN,AMAX,N);</~~lang~~syntaxhighlight> =={{header\|PowerShell}}== ~~<lang PowerShell>Function SortThree( [Array] $data )~~ ===First solution=== <syntaxhighlight lang="powershell">Function SortThree( [Array] $data ) { if( $data[ 0 ] -gt $data[ 1 ] ) Line 2,690 ⟶ 8,496: QuickSort 'e','c','a','b','d' QuickSort 0.5,0.3,0.1,0.2,0.4 $l = 100; QuickSort ( 1..$l \| ForEach-Object { $Rand = New-Object Random }{ $Rand.Next( 0, $l - 1 ) } )</~~lang~~syntaxhighlight> ===Another solution=== <syntaxhighlight lang="powershell"> function quicksort($array) { $less, $equal, $greater = @(), @(), @() if( $array.Count -gt 1 ) { $pivot = $array[0] foreach( $x in $array) { if($x -lt $pivot) { $less += @($x) } elseif ($x -eq $pivot) { $equal += @($x)} else { $greater += @($x) } } $array = (@(quicksort $less) + @($equal) + @(quicksort $greater)) } $array } $array = @(60, 21, 19, 36, 63, 8, 100, 80, 3, 87, 11) "$(quicksort $array)" </syntaxhighlight> <pre>The output is: 3 8 11 19 21 36 60 63 80 87 100</pre> ===Yet another solution=== <syntaxhighlight lang="powershell"> function quicksort($in) { $n = $in.count switch ($n) { 0 {} 1 { $in[0] } 2 { if ($in[0] -lt $in[1]) {$in[0], $in[1]} else {$in[1], $in[0]} } default { $pivot = $in \| get-random $lt = $in \| ? {$_ -lt $pivot} $eq = $in \| ? {$_ -eq $pivot} $gt = $in \| ? {$_ -gt $pivot} @(quicksort $lt) + @($eq) + @(quicksort $gt) } } } </syntaxhighlight> =={{header\|Prolog}}== <~~lang~~syntaxhighlight lang="prolog">qsort( [], [] ). qsort( [H\|U], S ) :- splitBy(H, U, L, R), qsort(L, SL), qsort(R, SR), append(SL, [H\|SR], S). Line 2,701 ⟶ 8,548: splitBy( H, [U\|T], [U\|LS], RS ) :- U =< H, splitBy(H, T, LS, RS). splitBy( H, [U\|T], LS, [U\|RS] ) :- U > H, splitBy(H, T, LS, RS). </syntaxhighlight> ~~</lang>~~ =={{header\|~~PureBasic~~Python}}== <syntaxhighlight lang="python">def quick_sort(sequence): ~~<lang PureBasic>Procedure qSort(Array a(1), firstIndex, lastIndex)~~ lesser = [] ~~Protected low, high, pivotValue~~ equal = [] ~~low~~ greater = ~~firstIndex~~[] if len(sequence) <= 1: ~~high = lastIndex~~ return sequence ~~pivotValue = a((firstIndex + lastIndex) / 2)~~ pivot = sequence[0] for element in sequence: ~~Repeat~~ if element < pivot: lesser.append(element) ~~While a(low) < pivotValue~~ ~~low~~ + 1elif element > pivot: greater.append(element) ~~Wend~~ else: equal.append(element) ~~While a(high) > pivotValue~~ lesser = quick_sort(lesser) ~~high - 1~~ greater = quick_sort(greater) ~~Wend~~ return lesser + equal + greater ~~If low <= high~~ ~~Swap a(low), a(high)~~ ~~low + 1~~ ~~high - 1~~ ~~EndIf~~ ~~Until low > high~~ ~~If firstIndex < high~~ ~~qSort(a(), firstIndex, high)~~ ~~EndIf~~ ~~If low < lastIndex~~ ~~qSort(a(), low, lastIndex)~~ ~~EndIf~~ ~~EndProcedure~~ ~~Procedure quickSort(Array a(1))~~ ~~qSort(a(),0,ArraySize(a()))~~ ~~EndProcedure</lang>~~ ~~=={{header\|Python}}==~~ ~~<lang python>def quickSort(arr):~~ ~~less = []~~ ~~pivotList = []~~ ~~more = []~~ ~~if len(arr) <= 1:~~ ~~return arr~~ ~~else:~~ ~~pivot = arr[0]~~ ~~for i in arr:~~ ~~if i < pivot:~~ ~~less.append(i)~~ ~~elif i > pivot:~~ ~~more.append(i)~~ ~~else:~~ ~~pivotList.append(i)~~ ~~less = quickSort(less)~~ ~~more = quickSort(more)~~ ~~return less + pivotList + more~~ a = [4, 65, 2, -31, 0, 99, 83, 782, 1] a = ~~quickSort~~quick_sort(a)~~</lang>~~ </syntaxhighlight> In a Haskell fashion -- <~~lang~~syntaxhighlight lang="python">def qsort(L): return (qsort([y for y in L[1:] if y < L[0]]) + [L[:10]] + qsort([y for y in L[1:] if y >= L[0]])) if len(L) > 1 else L</~~lang~~syntaxhighlight> More readable, but still using list comprehensions: <~~lang~~syntaxhighlight lang="python">def qsort(list): if not list: return [] else: pivot = list[0] less = [x for x in list [1:] if x < pivot] more = [x for x in list[1:] if x >= pivot] return qsort(less) + [pivot] + qsort(more)</~~lang~~syntaxhighlight> More correctly in some tests: <syntaxhighlight lang="python">from random import def qSort(a): if len(a) <= 1: return a else: q = choice(a) return qSort([elem for elem in a if elem < q]) + [q] * a.count(q) + qSort([elem for elem in a if elem > q])</syntaxhighlight> <syntaxhighlight lang="python">def quickSort(a): if len(a) <= 1: return a else: less = [] more = [] pivot = choice(a) for i in a: if i < pivot: less.append(i) if i > pivot: more.append(i) less = quickSort(less) more = quickSort(more) return less + [pivot] * a.count(pivot) + more</syntaxhighlight> Returning a new list: <syntaxhighlight lang="python">def qsort(array): if len(array) < 2: return array head, tail = array less = qsort([i for i in tail if i < head]) more = qsort([i for i in tail if i >= head]) return less + [head] + more</syntaxhighlight> Sorting a list in place: <syntaxhighlight lang="python">def quicksort(array): _quicksort(array, 0, len(array) - 1) def _quicksort(array, start, stop): if stop - start > 0: pivot, left, right = array[start], start, stop while left <= right: while array[left] < pivot: left += 1 while array[right] > pivot: right -= 1 if left <= right: array[left], array[right] = array[right], array[left] left += 1 right -= 1 _quicksort(array, start, right) _quicksort(array, left, stop)</syntaxhighlight> Functional Style (no for or while loops, constants only): <syntaxhighlight lang="python"> def quicksort(unsorted_list): if len(unsorted_list) == 0: return () pivot = unsorted_list[0] less = filter(lambda x: x < pivot, unsorted_list) same = filter(lambda x: x == pivot, unsorted_list) more = filter(lambda x: x > pivot, unsorted_list) return quicksort(less) + same + quicksort(more) </syntaxhighlight> =={{header\|Qi}}== <~~lang~~syntaxhighlight Qilang="qi">(define keep _ [] -> [] Pred [A\|Rest] -> [A \| (keep Pred Rest)] where (Pred A) Line 2,794 ⟶ 8,674: (quicksort [6 8 5 9 3 2 2 1 4 7]) </syntaxhighlight> ~~</lang>~~ =={{header\|Quackery}}== Sort a nest of numbers. <syntaxhighlight lang="quackery">[ stack ] is less ( --> s ) [ stack ] is same ( --> s ) [ stack ] is more ( --> s ) [ - -1 1 clamp 1+ ] is <=> ( n n --> n ) [ tuck take join swap put ] is append ( x s --> ) [ dup size 2 < if done [] less put [] same put [] more put behead swap witheach [ 2dup swap <=> [ table less same more ] append ] same append less take recurse same take join more take recurse join ] is quicksort ( [ --> [ ) [] 10 times [ i^ join ] 3 of dup echo cr quicksort echo cr</syntaxhighlight> '''Output:''' <pre>[ 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 ] [ 0 0 0 1 1 1 2 2 2 3 3 3 4 4 4 5 5 5 6 6 6 7 7 7 8 8 8 9 9 9 ]</pre> =={{header\|R}}== {{trans\|Octave}} <~~lang~~syntaxhighlight Rlang="r">qsort <- function(v) { if ( length(v) > 1 ) { Line 2,809 ⟶ 8,725: vs <- runif(N) system.time(u <- qsort(vs)) print(u)</~~lang~~syntaxhighlight> =={{header\|Racket}}== <~~lang~~syntaxhighlight ~~Racket~~lang="racket">#lang racket (define (quicksort ~~a-list~~< ~~(compare <)~~l) (match ~~a-list~~l ['() '(~~list~~)] [(~~list)~~cons x xs) (let-values ([(xs-gte xs-lt) (partition (curry < x) xs)]) ~~((cons x xs)~~ (append (quicksort ~~(filter (lambda (element) (compare element x))~~< xs-lt) ~~compare)~~ (list x) ~~(quicksort~~ ~~(filter~~ (~~lambda~~quicksort ~~(element) (not (compare element x)))~~< xs~~) compare~~-gte)))]))</~~lang~~syntaxhighlight> Examples <~~lang~~syntaxhighlight ~~Racket~~lang="racket"> (quicksort < '(8 7 53 6 4 35 2)) ;returns '(2 3 4 5 6 7 8) (quicksort string<? '("~~Quicksort~~Mergesort" "~~Mergesort~~Quicksort" "Bubblesort") ~~string<?~~) ;returns '("Bubblesort" "Mergesort" "Quicksort")</~~lang~~syntaxhighlight> =={{header\|~~REXX~~Raku}}== <syntaxhighlight lang="raku" line> ~~===version 1===~~ #\| Recursive, single-thread, random pivot, single-pass, quicksort implementation ~~<lang rexx>/REXX program sorts a stemmed array using the quicksort method. /~~ multi quicksort(\a where a.elems < 2) { a } ~~call gen@ /generate the array elements. /~~ multi quicksort(\a, \pivot = a.pick) { ~~call show@ 'before sort' /show before array elements./~~ my %prt{Order} is default([]) = a.classify: cmp pivot; ~~call quickSort highItem /here come da judge, here come../~~ \|samewith(%prt{Less}), \|%prt{Same}, \|samewith(%prt{More}) ~~call show@ ' after sort' /show after array elements./~~ } ~~exit /stick a fork in it, we're done./~~ </syntaxhighlight> ~~/──────────────────────────────────QUICKSORT subroutine────────────────/~~ ~~quickSort: procedure expose @. /access the caller's local var. /~~ ~~a.1=1; b.1=arg(1); $=1~~ ===concurrent implementation=== ~~do while $\==0; l=a.$; t=b.$; $=$-1~~ The partitions can be sorted in parallel. ~~if t<2 then iterate~~ ~~h=l+t-1~~ ~~?=l+t%2~~ ~~if @.h<@.l then if @.?<@.h then do; p=@.h; @.h=@.l; end~~ ~~else if @.?>@.l then p=@.l~~ ~~else do; p=@.?; @.?=@.l; end~~ ~~else if @.?<@.l then p=@.l~~ ~~else if @.?>@.h then do; p=@.h; @.h=@.l; end~~ ~~else do; p=@.?; @.?=@.l; end~~ ~~j=l+1~~ ~~k=h~~ ~~do forever~~ ~~do j=j while j<=k & @.j<=p; end /a tinie-tiny loop/~~ ~~do k=k by -1 while j <k & @.k>=p; end /another tiny loop/~~ ~~if j>=k then leave~~ ~~_=@.j; @.j=@.k; @.k=_~~ ~~end /forever/~~ <syntaxhighlight lang="raku" line> ~~k=j-1; @.l=@.k; @.k=p~~ #\| Recursive, parallel, random pivot, single-pass, quicksort implementation ~~$=$+1~~ multi quicksort-parallel-naive(\a where a.elems < 2) { a } ~~if j<=? then do; a.$=j; b.$=h-j+1; $=$+1; a.$=l; b.$=k-l; end~~ multi quicksort-parallel-naive(\a, \pivot = a.pick) { ~~else do; a.$=l; b.$=k-l; $=$+1; a.$=j; b.$=h-j+1; end~~ my %prt{Order} is default([]) = a.classify: * cmp pivot; ~~end /while $\==0/~~ my Promise $less = start { samewith(%prt{Less}) } my $more = samewith(%prt{More}); await $less andthen \|$less.result, \|%prt{Same}, \|$more; } </syntaxhighlight> Let's tune the parallel execution by applying a minimum batch size in order to spawn a new thread. ~~return~~ ~~/──────────────────────────────────GEN@ subroutine─────────────────────/~~ ~~gen@: @.=''; maxL=0 /assign default value. /~~ ~~@.1 =" Rivers that form part of a state's (USA) border "~~ ~~@.2 ='='~~ ~~@.3 ="Chattahoochee River: Alabama, Georgia"~~ ~~@.4 ="Colorado River: Arizona, Nevada, California, Baja California (Mexico)"~~ ~~@.5 ="St. Francis River: Arkansas, Missouri"~~ ~~@.6 ="Poteau River: Arkansas, Oklahoma"~~ ~~@.7 ="Byram River: Connecticut, New York"~~ ~~@.8 ="Pawcatuck River: Connecticut, Rhode Island"~~ ~~@.9 ="Perdido River: Florida, Alabama"~~ ~~@.10="St. Marys River: Florida, Georgia"~~ ~~@.11="Chattooga River: Georgia, South Carolina"~~ ~~@.12="Tugaloo River: Georgia, South Carolina"~~ ~~@.13="Snake River: Idaho, Washington, Oregon"~~ ~~@.14="Wabash River: Illinois, Indiana"~~ ~~@.15="Ohio River: Illinois, Indiana, Ohio, Kentucky, West Virginia"~~ ~~@.16="Des Moines River: Iowa, Missouri"~~ ~~@.17="Tennessee River: Kentucky, Tennessee, Mississippi, Alabama"~~ ~~@.18="Big Sandy River: Kentucky, West Virginia"~~ ~~@.19="Tug Fork River: Kentucky, West Virginia, Virginia"~~ ~~@.20="Monument Creek: Maine, New Brunswick (Canda)"~~ ~~@.21="St. Croix River: Maine, New Brunswick (Canda)"~~ ~~@.22="Piscataqua River: Maine, New Hampshire"~~ ~~@.23="St. Francis River: Maine, Quebec (Canada)"~~ ~~@.24="St. John River: Maine, Quebec (Canada)"~~ ~~@.25="Pocomoke River: Maryland, Virginia"~~ ~~@.26="Potomac River: Maryland, Virginia, city of Washington (District of Columbia), West Virginia"~~ ~~@.27="Montreal River: Michigan (upper peninsula ), Wisconsin"~~ ~~@.28="Detroit River: Michigan, Ontario (Canada)"~~ ~~@.29="St. Clair River: Michigan, Ontario (Canada)"~~ ~~@.30="St. Marys River: Michigan, Ontario (Canada)"~~ ~~@.31="Brule River: Michigan, Wisconsin"~~ ~~@.32="Menominee River: Michigan, Wisconsin"~~ ~~@.33="Pigeon River: Minnesota, Ontario (Canada)"~~ ~~@.34="Rainy River: Minnesota, Ontario (Canada)"~~ ~~@.35="St. Croix River: Minnesota, Wisconsin"~~ ~~@.36="St. Louis River: Minnesota, Wisconsin"~~ ~~@.37="Mississippi River: Minnesota, Wisconsin, Iowa, Illinois, Missouri, Kentucky, Tennesse, Arkansas, Mississippi, Louisiana"~~ ~~@.38="Pearl River: Mississippi, Louisiana"~~ ~~@.39="Halls Stream: New Hampshire, Canada"~~ ~~@.40="Salmon Falls River: New Hampshire, Maine"~~ ~~@.41="Connecticut River: New Hampshire, Vermont"~~ ~~@.42="Hudson River (lower part only): New Jersey, New York"~~ ~~@.43="Arthur Kill: New Jersey, New York (tidal strait)"~~ ~~@.44="Kill Van Kull: New Jersey, New York (tidal strait)"~~ ~~@.45="Rio Grande: New Mexico, Texas, Tamaulipas (Mexico), Nuevo Leon (Mexico), Coahuila De Zaragoza (Mexico), Chihuahua (Mexico)"~~ ~~@.46="Niagara River: New York, Ontario (Canada)"~~ ~~@.47="St. Lawrence River: New York, Ontario (Canada)"~~ ~~@.48="Delaware River: New York, Pennsylvania, New Jersey, Delaware"~~ ~~@.49="Catawba River: North Carolina, South Carolina"~~ ~~@.50="Red River of the North: North Dakota, Minnesota"~~ ~~@.51="Great Miami River (mouth only): Ohio, Indiana"~~ ~~@.52="Arkansas River: Oklahoma, Arkansas"~~ ~~@.53="Palmer River: Rhode Island, Massachusetts"~~ ~~@.54="Runnins River: Rhode Island, Massachusetts"~~ ~~@.55="Savannah River: South Carolina, Georgia"~~ ~~@.56="Big Sioux River: South Dakota, Iowa"~~ ~~@.57="Bois de Sioux River: South Dakota, Minnesota, North Dakota"~~ ~~@.58="Missouri River: South Dakota, Nebraska, Iowa, Missouri, Kansas"~~ ~~@.59="Sabine River: Texas, Louisiana"~~ ~~@.60="Red River (Mississippi watershed): Texas, Oklahoma, Arkansas"~~ ~~@.61="Poultney River: Vermont, New York"~~ ~~@.62="Blackwater River: Virginia, North Carolina"~~ ~~@.63="Columbia River: Washington, Oregon"~~ <syntaxhighlight lang="raku" line> ~~do highItem=1 while @.highItem\=='' /find how many entries, and also/~~ #\| Recursive, parallel, batch tuned, single-pass, quicksort implementation ~~maxL=max(maxL,length(@.highItem)) /* find the maximum width entry./~~ sub quicksort-parallel(@a, $batch = 29) { ~~end~~ return @a if @a.elems < 2; # separate unsorted input into Order Less, Same and More compared to a random $pivot ~~highItem=highItem-1 /adjust highItem slightly. /~~ my $pivot = @a.pick; ~~@.1=centre(@.1,maxL,'-') /adjust the header information. /~~ my %prt{Order} is default([]) = @a.classify( cmp $pivot ); ~~@.2=copies(@.2,maxL) /adjust the header separator. /~~ ~~return~~ # decide if we sort the Less partition on a new thread ~~/──────────────────────────────────SHOW@ subroutine────────────────────/~~ my $less = %prt{Less}.elems >= $batch ~~show@: widthH=length(highItem) /maximum width of any line. /~~ ?? start { samewith(%prt{Less}, $batch) } !! samewith(%prt{Less}, $batch); # meanwhile use current thread for sorting the More partition my $more = samewith(%prt{More}, $batch); # if we went parallel, we need to await the result await $less andthen $less = $less.result if $less ~~ Promise; # concat all sorted partitions into a list and return \|$less, \|%prt{Same}, \|$more; } </syntaxhighlight> ===testing=== Let's run some tests. <syntaxhighlight lang="raku" line> say "x" x 10 ~ " Testing " ~ "x" x 10; use Test; my @functions-under-test = &quicksort, &quicksort-parallel-naive, &quicksort-parallel; my @testcases = () => (), <a>.List => <a>.List, <a a> => <a a>, ("b", "a", 3) => (3, "a", "b"), <h b a c d f e g> => <a b c d e f g h>, <a 🎮 3 z 4 🐧> => <a 🎮 3 z 4 🐧>.sort ; plan @testcases.elems * @functions-under-test.elems; for @functions-under-test -> &fun { say &fun.name; is-deeply &fun(.key), .value, .key ~ " => " ~ .value for @testcases; } done-testing; </syntaxhighlight> <pre> xxxxxxxxxx Testing xxxxxxxxxx 1..18 quicksort ok 1 - => ok 2 - a => a ok 3 - a a => a a ok 4 - b a 3 => 3 a b ok 5 - h b a c d f e g => a b c d e f g h ok 6 - a 🎮 3 z 4 🐧 => 3 4 a z 🎮 🐧 quicksort-parallel-naive ok 7 - => ok 8 - a => a ok 9 - a a => a a ok 10 - b a 3 => 3 a b ok 11 - h b a c d f e g => a b c d e f g h ok 12 - a 🎮 3 z 4 🐧 => 3 4 a z 🎮 🐧 quicksort-parallel ok 13 - => ok 14 - a => a ok 15 - a a => a a ok 16 - b a 3 => 3 a b ok 17 - h b a c d f e g => a b c d e f g h ok 18 - a 🎮 3 z 4 🐧 => 3 4 a z 🎮 🐧</pre> ===benchmarking=== and some benchmarking <syntaxhighlight lang="raku" line> say "x" x 11 ~ " Benchmarking " ~ "x" x 11; use Benchmark; my $runs = 5; my $elems = 10 * Kernel.cpu-cores * 210; my @unsorted of Str = ('a'..'z').roll(8).join xx $elems; my UInt $l-batch = 213; my UInt $m-batch = 211; my UInt $s-batch = 29; my UInt $t-batch = 2*7; say "elements: $elems, runs: $runs, cpu-cores: {Kernel.cpu-cores}, large/medium/small/tiny-batch: $l-batch/$m-batch/$s-batch/$t-batch"; my %results = timethese $runs, { single-thread => { quicksort(@unsorted) }, parallel-naive => { quicksort-parallel-naive(@unsorted) }, parallel-tiny-batch => { quicksort-parallel(@unsorted, $t-batch) }, parallel-small-batch => { quicksort-parallel(@unsorted, $s-batch) }, parallel-medium-batch => { quicksort-parallel(@unsorted, $m-batch) }, parallel-large-batch => { quicksort-parallel(@unsorted, $l-batch) }, }, :statistics; my @metrics = <mean median sd>; my $msg-row = "%.4f\t" x @metrics.elems ~ '%s'; say @metrics.join("\t"); for %results.kv -> $name, %m { say sprintf($msg-row, %m{@metrics}, $name); } </syntaxhighlight> <pre> xxxxxxxxxxx Benchmarking xxxxxxxxxxx elements: 40960, runs: 5, cpu-cores: 4, large/medium/small/tiny-batch: 8192/2048/512/128 mean median sd 2.9503 2.8907 0.2071 parallel-small-batch 3.2054 3.1727 0.2078 parallel-tiny-batch 5.6524 5.0980 1.2628 parallel-naive 3.4717 3.3353 0.3622 parallel-medium-batch 4.6275 4.7793 0.4930 parallel-large-batch 6.5401 6.2832 0.5585 single-thread </pre> =={{header\|Red}}== <syntaxhighlight lang="red"> Red [] ;;------------------------------- ;; we have to use function not func here, otherwise we'd have to define all "vars" as local... qsort: function [list][ ;;------------------------------- if 1 >= length? list [ return list ] left: copy [] right: copy [] eq: copy [] ;; "equal" pivot: list/2 ;; simply choose second element as pivot element foreach ele list [ case [ ele < pivot [ append left ele ] ele > pivot [ append right ele ] true [append eq ele ] ] ] ;; this is the last expression of the function, so coding "return" here is not necessary reduce [qsort left eq qsort right] ] ;; lets test the function with an array of 100k integers, range 1..1000 list: [] loop 100000 [append list random 1000] t0: now/time/precise ;; start timestamp qsort list ;; the return value (block) contains the sorted list, original list has not changed print ["time1: " now/time/precise - t0] ;; about 1.1 sec on my machine t0: now/time/precise sort list ;; just for fun time the builtin function also ( also implementation of quicksort ) print ["time2: " now/time/precise - t0] </syntaxhighlight> =={{header\|REXX}}== ===version 1=== This REXX version doesn't use or modify the program stack. It is over   '''400%'''   times faster then the 2<sup>nd</sup> REXX version   (using the exact same random numbers). ~~do j=1 for highItem /show each array item./~~ ~~say 'element' right(j,widthH) arg(1)':' @.j~~ ~~end~~ <syntaxhighlight lang="rexx">/REXX program sorts a stemmed array using the quicksort algorithm. / ~~say copies('█',maxL+widthH+22) /show a separator line. /~~ call gen@ /generate the elements for the array. / ~~return</lang>~~ call show@ 'before sort' /show the before array elements. / ~~'''output'''~~ call qSort # /invoke the quicksort subroutine. / ~~<pre style="height:40ex;overflow:scroll">~~ call show@ ' after sort' /show the after array elements. / ~~element 1 before sort: ------------------------------------------------ Rivers that form part of a state's (USA) border -------------------------------------------------~~ exit /stick a fork in it, we're all done. / /──────────────────────────────────────────────────────────────────────────────────────/ inOrder: parse arg n; do j=1 for n-1; k= j+1; if @.j>@.k then return 0; end; return 1 /──────────────────────────────────────────────────────────────────────────────────────/ qSort: procedure expose @.; a.1=1; parse arg b.1; $= 1 /access @.; get @. size; pivot./ if inOrder(b.1) then return /Array already in order? Return/ do while $\==0; L= a.$; t= b.$; $= $ - 1; if t<2 then iterate H= L + t - 1; ?= L + t % 2 if @.H<@.L then if @.?<@.H then do; p= @.H; @.H= @.L; end else if @.?>@.L then p= @.L else do; p= @.?; @.?= @.L; end else if @.?<@.L then p=@.L else if @.?>@.H then do; p= @.H; @.H= @.L; end else do; p= @.?; @.?= @.L; end j= L+1; k= h do forever do j=j while j<=k & @.j<=p; end /a teeny─tiny loop./ do k=k by -1 while j< k & @.k>=p; end /another " " / if j>=k then leave /segment finished? / _= @.j; @.j= @.k; @.k= _ /swap J&K elements./ end /forever/ $= $ + 1 k= j - 1; @.L= @.k; @.k= p if j<=? then do; a.$= j; b.$= H-j+1; $= $+1; a.$= L; b.$= k-L; end else do; a.$= L; b.$= k-L; $= $+1; a.$= j; b.$= H-j+1; end end /while $¬==0/ return /──────────────────────────────────────────────────────────────────────────────────────/ show@: w= length(#); do j=1 for #; say 'element' right(j,w) arg(1)":" @.j; end say copies('▒', maxL + w + 22) /display a separator (between outputs)/ return /──────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────/ gen@: @.=; maxL=0 /assign a default value for the array./ @.1 = " Rivers that form part of a (USA) state's border " /this value is adjusted later to include a prefix & suffix./ @.2 = '=' /this value is expanded later. / @.3 = "Perdido River Alabama, Florida" @.4 = "Chattahoochee River Alabama, Georgia" @.5 = "Tennessee River Alabama, Kentucky, Mississippi, Tennessee" @.6 = "Colorado River Arizona, California, Nevada, Baja California (Mexico)" @.7 = "Mississippi River Arkansas, Illinois, Iowa, Kentucky, Minnesota, Mississippi, Missouri, Tennessee, Louisiana, Wisconsin" @.8 = "St. Francis River Arkansas, Missouri" @.9 = "Poteau River Arkansas, Oklahoma" @.10 = "Arkansas River Arkansas, Oklahoma" @.11 = "Red River (Mississippi watershed) Arkansas, Oklahoma, Texas" @.12 = "Byram River Connecticut, New York" @.13 = "Pawcatuck River Connecticut, Rhode Island and Providence Plantations" @.14 = "Delaware River Delaware, New Jersey, New York, Pennsylvania" @.15 = "Potomac River District of Columbia, Maryland, Virginia, West Virginia" @.16 = "St. Marys River Florida, Georgia" @.17 = "Chattooga River Georgia, South Carolina" @.18 = "Tugaloo River Georgia, South Carolina" @.19 = "Savannah River Georgia, South Carolina" @.20 = "Snake River Idaho, Oregon, Washington" @.21 = "Wabash River Illinois, Indiana" @.22 = "Ohio River Illinois, Indiana, Kentucky, Ohio, West Virginia" @.23 = "Great Miami River (mouth only) Indiana, Ohio" @.24 = "Des Moines River Iowa, Missouri" @.25 = "Big Sioux River Iowa, South Dakota" @.26 = "Missouri River Kansas, Iowa, Missouri, Nebraska, South Dakota" @.27 = "Tug Fork River Kentucky, Virginia, West Virginia" @.28 = "Big Sandy River Kentucky, West Virginia" @.29 = "Pearl River Louisiana, Mississippi" @.30 = "Sabine River Louisiana, Texas" @.31 = "Monument Creek Maine, New Brunswick (Canada)" @.32 = "St. Croix River Maine, New Brunswick (Canada)" @.33 = "Piscataqua River Maine, New Hampshire" @.34 = "St. Francis River Maine, Quebec (Canada)" @.35 = "St. John River Maine, Quebec (Canada)" @.36 = "Pocomoke River Maryland, Virginia" @.37 = "Palmer River Massachusetts, Rhode Island and Providence Plantations" @.38 = "Runnins River Massachusetts, Rhode Island and Providence Plantations" @.39 = "Montreal River Michigan (upper peninsula), Wisconsin" @.40 = "Detroit River Michigan, Ontario (Canada)" @.41 = "St. Clair River Michigan, Ontario (Canada)" @.42 = "St. Marys River Michigan, Ontario (Canada)" @.43 = "Brule River Michigan, Wisconsin" @.44 = "Menominee River Michigan, Wisconsin" @.45 = "Red River of the North Minnesota, North Dakota" @.46 = "Bois de Sioux River Minnesota, North Dakota, South Dakota" @.47 = "Pigeon River Minnesota, Ontario (Canada)" @.48 = "Rainy River Minnesota, Ontario (Canada)" @.49 = "St. Croix River Minnesota, Wisconsin" @.50 = "St. Louis River Minnesota, Wisconsin" @.51 = "Halls Stream New Hampshire, Canada" @.52 = "Salmon Falls River New Hampshire, Maine" @.53 = "Connecticut River New Hampshire, Vermont" @.54 = "Arthur Kill New Jersey, New York (tidal strait)" @.55 = "Kill Van Kull New Jersey, New York (tidal strait)" @.56 = "Hudson River (lower part only) New Jersey, New York" @.57 = "Rio Grande New Mexico, Texas, Tamaulipas (Mexico), Nuevo Leon (Mexico), Coahuila de Zaragoza (Mexico), Chihuahua (Mexico)" @.58 = "Niagara River New York, Ontario (Canada)" @.59 = "St. Lawrence River New York, Ontario (Canada)" @.60 = "Poultney River New York, Vermont" @.61 = "Catawba River North Carolina, South Carolina" @.62 = "Blackwater River North Carolina, Virginia" @.63 = "Columbia River Oregon, Washington" do #=1 until @.#=='' /find how many entries in array, and / maxL=max(maxL, length(@.#)) / also find the maximum width entry./ end /#/; #= #-1 /adjust the highest element number. / @.1= center(@.1, maxL, '-') / " " header information. / @.2= copies(@.2, maxL) / " " " separator. / return</syntaxhighlight> {{out\|output\|text=  when using the internal default input:}} <pre style="height:60ex"> element 1 before sort: ------------------------------------------------ Rivers that form part of a (USA) state's border ------------------------------------------------- element 2 before sort: ================================================================================================================================================== element 3 before sort: ~~Chattahoochee~~Perdido River: Alabama, ~~Georgia~~Florida element 4 before sort: ~~Colorado~~Chattahoochee River: ~~Arizona~~Alabama, ~~Nevada, California, Baja California (Mexico)~~Georgia element 5 before sort: ~~St. Francis~~Tennessee River: ~~Arkansas~~ Alabama, Kentucky, Mississippi, ~~Missouri~~Tennessee element 6 before sort: ~~Poteau~~Colorado River: Arizona, ~~Arkansas~~California, ~~Oklahoma~~Nevada, Baja California (Mexico) element 7 before sort: ~~Byram~~Mississippi River: Arkansas, Illinois, Iowa, Kentucky, Minnesota, ~~Connecticut~~Mississippi, ~~New~~Missouri, Tennessee, Louisiana, ~~York~~Wisconsin element 8 before sort: ~~Pawcatuck~~St. Francis River: ~~Connecticut~~Arkansas, ~~Rhode Island~~Missouri element 9 before sort: ~~Perdido~~Poteau River: ~~Florida~~ Arkansas, ~~Alabama~~Oklahoma element 10 before sort: ~~St. Marys~~Arkansas River: ~~Florida~~ Arkansas, ~~Georgia~~Oklahoma element 11 before sort: ~~Chattooga~~Red River: (Mississippi watershed) Arkansas, ~~Georgia~~Oklahoma, ~~South Carolina~~Texas element 12 before sort: ~~Tugaloo~~Byram River: ~~Georgia~~ Connecticut, ~~South~~New ~~Carolina~~York element 13 before sort: ~~Snake~~Pawcatuck River: Connecticut, Rhode Island ~~Idaho,~~and ~~Washington,~~Providence ~~Oregon~~Plantations element 14 before sort: ~~Wabash~~Delaware River: Delaware, New Jersey, New ~~Illinois~~York, ~~Indiana~~Pennsylvania element 15 before sort: ~~Ohio~~Potomac River: District of ~~Illinois~~Columbia, ~~Indiana~~Maryland, ~~Ohio, Kentucky~~Virginia, West Virginia element 16 before sort: ~~Des~~St. ~~Moines~~Marys River: ~~Iowa~~ Florida, ~~Missouri~~Georgia element 17 before sort: ~~Tennessee~~Chattooga River: ~~Kentucky,~~ ~~Tennessee~~Georgia, ~~Mississippi,~~South ~~Alabama~~Carolina element 18 before sort: ~~Big Sandy~~Tugaloo River: ~~Kentucky~~ Georgia, ~~West~~South ~~Virginia~~Carolina element 19 before sort: ~~Tug Fork~~Savannah River: ~~Kentucky~~ Georgia, ~~West Virginia,~~South ~~Virginia~~Carolina element 20 before sort: ~~Monument~~Snake ~~Creek:~~River ~~Maine,~~ ~~New~~ ~~Brunswick~~ ~~(Canda)~~ Idaho, Oregon, Washington element 21 before sort: ~~St. Croix~~Wabash River: ~~Maine,~~ ~~New~~ ~~Brunswick~~ ~~(Canda)~~ Illinois, Indiana element 22 before sort: ~~Piscataqua~~Ohio River: ~~Maine~~ Illinois, Indiana, Kentucky, Ohio, ~~New~~West ~~Hampshire~~Virginia element 23 before sort: ~~St.~~Great ~~Francis~~Miami River: (mouth only) ~~Maine~~Indiana, ~~Quebec (Canada)~~Ohio element 24 before sort: ~~St.~~Des ~~John~~Moines River: ~~Maine~~Iowa, ~~Quebec (Canada)~~Missouri element 25 before sort: ~~Pocomoke~~Big Sioux River: ~~Maryland~~Iowa, ~~Virginia~~South Dakota element 26 before sort: ~~Potomac~~Missouri River: ~~Maryland~~Kansas, ~~Virginia~~Iowa, ~~city of Washington (District of~~Missouri, ~~Columbia)~~Nebraska, ~~West~~South ~~Virginia~~Dakota element 27 before sort: ~~Montreal~~Tug Fork River: ~~Michigan~~ ~~(upper~~Kentucky, ~~peninsula )~~Virginia, ~~Wisconsin~~West Virginia element 28 before sort: ~~Detroit~~Big ~~River:~~Sandy River ~~Michigan~~Kentucky, ~~Ontario~~West ~~(Canada)~~Virginia element 29 before sort: ~~St. Clair~~Pearl River: ~~Michigan,~~ ~~Ontario~~ ~~(Canada)~~ Louisiana, Mississippi element 30 before sort: ~~St. Marys~~Sabine River: ~~Michigan,~~ ~~Ontario~~ ~~(Canada)~~ Louisiana, Texas element 31 before sort: ~~Brule~~Monument ~~River:~~Creek Maine, New ~~Michigan,~~Brunswick ~~Wisconsin~~(Canada) element 32 before sort: ~~Menominee~~St. Croix River: ~~Michigan~~ Maine, ~~Wisconsin~~New Brunswick (Canada) element 33 before sort: ~~Pigeon~~Piscataqua River: ~~Minnesota~~Maine, ~~Ontario~~New ~~(Canada)~~Hampshire element 34 before sort: ~~Rainy~~St. Francis River: ~~Minnesota~~Maine, ~~Ontario~~Quebec (Canada) element 35 before sort: St. ~~Croix~~John River: ~~Minnesota~~ Maine, ~~Wisconsin~~Quebec (Canada) element 36 before sort: ~~St. Louis~~Pocomoke River: ~~Minnesota~~ Maryland, ~~Wisconsin~~Virginia element 37 before sort: ~~Mississippi~~Palmer River: ~~Minnesota,~~ ~~Wisconsin,~~ ~~Iowa,~~ ~~Illinois,~~ ~~Missouri,~~ ~~Kentucky,~~ ~~Tennesse~~Massachusetts, ~~Arkansas,~~Rhode ~~Mississippi,~~Island and Providence ~~Louisiana~~Plantations element 38 before sort: ~~Pearl~~Runnins River: ~~Mississippi~~Massachusetts, ~~Louisiana~~Rhode Island and Providence Plantations element 39 before sort: ~~Halls~~Montreal ~~Stream:~~River Michigan ~~New~~(upper ~~Hampshire~~peninsula), ~~Canada~~Wisconsin element 40 before sort: ~~Salmon Falls~~Detroit River: ~~New~~ ~~Hampshire~~ Michigan, ~~Maine~~Ontario (Canada) element 41 before sort: ~~Connecticut~~St. Clair River: ~~New~~ ~~Hampshire~~ Michigan, ~~Vermont~~Ontario (Canada) element 42 before sort: ~~Hudson~~St. Marys River ~~(lower~~ ~~part~~ ~~only):~~ ~~New~~ ~~Jersey~~ Michigan, ~~New~~Ontario ~~York~~(Canada) element 43 before sort: ~~Arthur~~Brule ~~Kill:~~River ~~New~~ ~~Jersey~~Michigan, ~~New York (tidal strait)~~Wisconsin element 44 before sort: ~~Kill~~Menominee ~~Van~~River ~~Kull:~~ ~~New Jersey~~Michigan, ~~New York (tidal strait)~~Wisconsin element 45 before sort: ~~Rio~~Red ~~Grande:~~River of the North ~~New Mexico, Texas, Tamaulipas (Mexico), Nuevo Leon (Mexico), Coahuila De Zaragoza (Mexico)~~Minnesota, ~~Chihuahua~~North ~~(Mexico)~~Dakota element 46 before sort: ~~Niagara River:~~ Bois de Sioux River Minnesota, ~~New~~North ~~York~~Dakota, ~~Ontario~~South ~~(Canada)~~Dakota element 47 before sort: ~~St. Lawrence~~Pigeon River: ~~New~~ ~~York~~ Minnesota, Ontario (Canada) element 48 before sort: ~~Delaware~~Rainy River: ~~New~~ ~~York,~~ ~~Pennsylvania,~~ ~~New~~ ~~Jersey~~Minnesota, ~~Delaware~~Ontario (Canada) element 49 before sort: ~~Catawba~~St. Croix River: ~~North Carolina~~Minnesota, ~~South Carolina~~Wisconsin element 50 before sort: ~~Red~~St. Louis River of ~~the~~ ~~North:~~ ~~North~~ ~~Dakota,~~ Minnesota, Wisconsin element 51 before sort: ~~Great~~Halls ~~Miami~~Stream ~~River~~ ~~(mouth~~ ~~only):~~ ~~Ohio~~ New Hampshire, ~~Indiana~~Canada element 52 before sort: ~~Arkansas~~Salmon Falls River: New ~~Oklahoma~~Hampshire, ~~Arkansas~~Maine element 53 before sort: ~~Palmer~~Connecticut River: New ~~Rhode Island~~Hampshire, ~~Massachusetts~~Vermont element 54 before sort: ~~Runnins~~Arthur ~~River:~~Kill ~~Rhode~~ ~~Island~~ New Jersey, ~~Massachusetts~~New York (tidal strait) element 55 before sort: ~~Savannah~~Kill ~~River:~~Van Kull ~~South~~ ~~Carolina~~ New Jersey, ~~Georgia~~New York (tidal strait) element 56 before sort: ~~Big Sioux~~Hudson River: (lower part only) New Jersey, New ~~South Dakota, Iowa~~York element 57 before sort: ~~Bois~~Rio deGrande ~~Sioux~~ ~~River:~~ ~~South~~ ~~Dakota~~ New Mexico, ~~Minnesota~~Texas, Tamaulipas (Mexico), Nuevo Leon (Mexico), Coahuila de Zaragoza (Mexico), ~~North~~Chihuahua ~~Dakota~~(Mexico) element 58 before sort: ~~Missouri~~Niagara River: ~~South~~ ~~Dakota,~~ ~~Nebraska,~~New ~~Iowa~~York, ~~Missouri,~~Ontario ~~Kansas~~(Canada) element 59 before sort: ~~Sabine~~St. Lawrence River: New York, Ontario ~~Texas, Louisiana~~(Canada) element 60 before sort: ~~Red~~Poultney River ~~(Mississippi~~ ~~watershed):~~ ~~Texas,~~ ~~Oklahoma~~ New York, ~~Arkansas~~Vermont element 61 before sort: ~~Poultney~~Catawba River: ~~Vermont~~ North Carolina, ~~New~~South ~~York~~Carolina element 62 before sort: Blackwater River: ~~Virginia,~~ North Carolina, Virginia element 63 before sort: Columbia River: ~~Washington,~~ Oregon, Washington ▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒ ██████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████ element 1 after sort: ------------------------------------------------ Rivers that form part of a ~~state's~~ (USA) state's border ------------------------------------------------- element 2 after sort: ================================================================================================================================================== element 3 after sort: Arkansas River: ~~Oklahoma,~~ Arkansas, Oklahoma element 4 after sort: Arthur Kill: New Jersey, New York (tidal strait) element 5 after sort: Big Sandy River: Kentucky, West Virginia element 6 after sort: Big Sioux River: ~~South~~ ~~Dakota~~Iowa, ~~Iowa~~South Dakota element 7 after sort: Blackwater River: ~~Virginia,~~ North Carolina, Virginia element 8 after sort: Bois de Sioux River: ~~South Dakota,~~ Minnesota, North Dakota, South Dakota element 9 after sort: Brule River: Michigan, Wisconsin element 10 after sort: Byram River: Connecticut, New York element 11 after sort: Catawba River: North Carolina, South Carolina element 12 after sort: Chattahoochee River: Alabama, Georgia element 13 after sort: Chattooga River: Georgia, South Carolina element 14 after sort: Colorado River: Arizona, ~~Nevada~~California, ~~California~~Nevada, Baja California (Mexico) element 15 after sort: Columbia River: ~~Washington,~~ Oregon, Washington element 16 after sort: Connecticut River: New Hampshire, Vermont element 17 after sort: Delaware River: ~~New~~ ~~York~~Delaware, ~~Pennsylvania~~New Jersey, New ~~Jersey~~York, ~~Delaware~~Pennsylvania element 18 after sort: Des Moines River: Iowa, Missouri element 19 after sort: Detroit River: Michigan, Ontario (Canada) element 20 after sort: Great Miami River (mouth only): ~~Ohio,~~ Indiana, Ohio element 21 after sort: Halls Stream: New Hampshire, Canada element 22 after sort: Hudson River (lower part only): New Jersey, New York element 23 after sort: Kill Van Kull: New Jersey, New York (tidal strait) element 24 after sort: Menominee River: Michigan, Wisconsin element 25 after sort: Mississippi River: ~~Minnesota~~ Arkansas, ~~Wisconsin~~Illinois, Iowa, ~~Illinois~~Kentucky, ~~Missouri~~Minnesota, ~~Kentucky~~Mississippi, ~~Tennesse~~Missouri, ~~Arkansas~~Tennessee, ~~Mississippi~~Louisiana, ~~Louisiana~~Wisconsin element 26 after sort: Missouri River: ~~South~~ ~~Dakota, Nebraska~~Kansas, Iowa, Missouri, ~~Kansas~~Nebraska, South Dakota element 27 after sort: Montreal River: Michigan (upper peninsula ), Wisconsin element 28 after sort: Monument Creek: Maine, New Brunswick (~~Canda~~Canada) element 29 after sort: Niagara River: New York, Ontario (Canada) element 30 after sort: Ohio River: Illinois, Indiana, ~~Ohio~~Kentucky, ~~Kentucky~~Ohio, West Virginia element 31 after sort: Palmer River: Massachusetts, Rhode Island, ~~Massachusetts~~and Providence Plantations element 32 after sort: Pawcatuck River: Connecticut, Rhode Island and Providence Plantations element 33 after sort: Pearl River: ~~Mississippi,~~ Louisiana, Mississippi element 34 after sort: Perdido River: ~~Florida,~~ Alabama, Florida element 35 after sort: Pigeon River: Minnesota, Ontario (Canada) element 36 after sort: Piscataqua River: Maine, New Hampshire element 37 after sort: Pocomoke River: Maryland, Virginia element 38 after sort: Poteau River: Arkansas, Oklahoma element 39 after sort: Potomac River: ~~Maryland,~~ ~~Virginia, city~~District of ~~Washington~~Columbia, ~~(District~~Maryland, ~~of Columbia)~~Virginia, West Virginia element 40 after sort: Poultney River: ~~Vermont,~~ New York, Vermont element 41 after sort: Rainy River: Minnesota, Ontario (Canada) element 42 after sort: Red River (Mississippi watershed): ~~Texas~~ Arkansas, Oklahoma, ~~Arkansas~~Texas element 43 after sort: Red River of the North: ~~North~~ ~~Dakota~~Minnesota, ~~Minnesota~~North Dakota element 44 after sort: Rio Grande: New Mexico, Texas, Tamaulipas (Mexico), Nuevo Leon (Mexico), Coahuila Dede Zaragoza (Mexico), Chihuahua (Mexico) element 45 after sort: Runnins River: Massachusetts, Rhode Island, ~~Massachusetts~~and Providence Plantations element 46 after sort: Sabine River: ~~Texas,~~ Louisiana, Texas element 47 after sort: Salmon Falls River: New Hampshire, Maine element 48 after sort: Savannah River: ~~South~~ ~~Carolina~~Georgia, ~~Georgia~~South Carolina element 49 after sort: Snake River: Idaho, ~~Washington~~Oregon, ~~Oregon~~Washington element 50 after sort: St. Clair River: Michigan, Ontario (Canada) element 51 after sort: St. Croix River: Maine, New Brunswick (~~Canda~~Canada) element 52 after sort: St. Croix River: Minnesota, Wisconsin element 53 after sort: St. Francis River: Arkansas, Missouri element 54 after sort: St. Francis River: Maine, Quebec (Canada) element 55 after sort: St. John River: Maine, Quebec (Canada) element 56 after sort: St. Lawrence River: New York, Ontario (Canada) element 57 after sort: St. Louis River: Minnesota, Wisconsin element 58 after sort: St. Marys River: Florida, Georgia element 59 after sort: St. Marys River: Michigan, Ontario (Canada) element 60 after sort: Tennessee River: ~~Kentucky~~ Alabama, ~~Tennessee~~Kentucky, Mississippi, ~~Alabama~~Tennessee element 61 after sort: Tug Fork River: Kentucky, ~~West~~ Virginia, West Virginia element 62 after sort: Tugaloo River: Georgia, South Carolina element 63 after sort: Wabash River: Illinois, Indiana ▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒▒ ██████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████████ </pre> Line 3,085 ⟶ 9,174: {{trans\|Python}}The Python code translates very well to [[ooRexx]] but here is a way to implement it in classic REXX as well. This REXX version doesn't handle numbers with leading/trailing/embedded blanks, or textual values that have blanks (or whitespace) in them. ~~<lang Rexx> a = '4 65 2 -31 0 99 83 782 1'~~ <syntaxhighlight lang="rexx"> /REXX/ a = '4 65 2 -31 0 99 83 782 1' do i = 1 to words(a) queue word(a, i) Line 3,170 ⟶ 9,262: queue more.i end return</~~lang~~syntaxhighlight> =={{header\|~~Ruby~~Refal}}== <syntaxhighlight lang="refal">$ENTRY Go { , 7 6 5 9 8 4 3 1 2 0: e.Arr = <Prout e.Arr> <Prout <Sort e.Arr>>; }; Sort { ~~<lang ruby>class Array~~ = ; s.N = s.N; s.Pivot e.X = <Sort <Filter s.Pivot '-' e.X>> <Filter s.Pivot '=' e.X> s.Pivot <Sort <Filter s.Pivot '+' e.X>>; }; Filter { s.N s.Comp = ; s.N s.Comp s.I e.List, <Compare s.I s.N>: { s.Comp = s.I <Filter s.N s.Comp e.List>; s.X = <Filter s.N s.Comp e.List>; }; };</syntaxhighlight> {{out}} <pre>7 6 5 9 8 4 3 1 2 0 0 1 2 3 4 5 6 7 8 9</pre> =={{header\|Ring}}== <syntaxhighlight lang="ring"> # Project : Sorting algorithms/Quicksort test = [4, 65, 2, -31, 0, 99, 2, 83, 782, 1] see "before sort:" + nl showarray(test) quicksort(test, 1, 10) see "after sort:" + nl showarray(test) func quicksort(a, s, n) if n < 2 return ok t = s + n - 1 l = s r = t p = a[floor((l + r) / 2)] while l <= r while a[l] < p l = l + 1 end while a[r] > p r = r - 1 end if l <= r temp = a[l] a[l] = a[r] a[r] = temp l = l + 1 r = r - 1 ok end if s < r quicksort(a, s, r - s + 1) ok if l < t quicksort(a, l, t - l + 1 ) ok func showarray(vect) svect = "" for n = 1 to len(vect) svect = svect + vect[n] + " " next svect = left(svect, len(svect) - 1) see svect + nl </syntaxhighlight> Output: <pre> before sort: 4 65 2 -31 0 99 2 83 782 1 after sort: -31 0 1 2 2 4 65 83 99 782 </pre> =={{header\|RPL}}== {{works with\|HP\|48}} ≪ DUP SIZE → size ≪ '''IF''' size 1 > '''THEN''' DUP size 2 / CEIL GET { } DUP DUP → pivot less equal greater ≪ 1 size '''FOR''' j DUP j GET pivot '''CASE''' DUP2 < '''THEN''' DROP 'less' STO+ '''END''' DUP2 == '''THEN''' DROP 'equal' STO+ '''END''' DROP 'greater' STO+ '''END''' '''NEXT''' DROP less <span style="color:blue">QSORT</span> greater <span style="color:blue">QSORT</span> equal SWAP + + ≫ '''END''' ≫ ≫ '<span style="color:blue">QSORT</span>' STO =={{header\|Ruby}}== <syntaxhighlight lang="ruby">class Array def quick_sort return self if length <= 1 pivot = self[~~length / 2~~0] ~~find_all~~less, greatereq = self[1..-1].partition { \|ix\| ix < pivot }~~.quick_sort +~~ less.quick_sort + [pivot] + greatereq.quick_sort ~~find_all { \|i\| i == pivot } +~~ ~~find_all { \|i\| i > pivot }.quick_sort~~ end end</~~lang~~syntaxhighlight> or <~~lang~~syntaxhighlight lang="ruby">class Array def quick_sort return self if length <= 1 pivot = ~~self[0]~~sample ~~less, greatereq~~group = ~~self[1..-1].partition~~ group_by{ \|x\| x <=> pivot } ~~less~~group.~~quick_sort~~default += [] group[-1].quick_sort + group[0] + group[1].quick_sort ~~[pivot] +~~ ~~greatereq.quick_sort~~ end end</~~lang~~syntaxhighlight> or functionally ~~=={{header\|Run BASIC}}==~~ <syntaxhighlight lang="ruby">class Array ~~<lang runbasic>' -------------------------------~~ def quick_sort ~~' quick sort~~ h, t = self ~~' -------------------------------~~ h ? t.partition { \|e\| e < h }.inject { \|l, r\| l.quick_sort + [h] + r.quick_sort } : [] ~~size = 50~~ end ~~dim s(size) ' array to sort~~ end</syntaxhighlight> ~~for i = 1 to size ' fill it with some random numbers~~ ~~s(i) = rnd(0) * 100~~ ~~next i~~ =={{header\|Rust}}== ~~lft = 1~~ <syntaxhighlight lang="rust">fn main() { ~~rht = size~~ println!("Sort numbers in descending order"); let mut numbers = [4, 65, 2, -31, 0, 99, 2, 83, 782, 1]; println!("Before: {:?}", numbers); quick_sort(&mut numbers, &\|x,y\| x > y); ~~[qSort]~~ println!("After: {:?}\n", numbers); ~~lftHold = lft~~ ~~rhtHold = rht~~ ~~pivot = s(lft)~~ ~~while lft < rht~~ ~~while (s(rht) >= pivot) and (lft < rht) : rht = rht - 1 :wend~~ ~~if lft <> rht then~~ ~~s(lft) = s(rht)~~ ~~lft = lft + 1~~ ~~end if~~ ~~while (s(lft) <= pivot) and (lft < rht) : lft = lft + 1 :wend~~ ~~if lft <> rht then~~ ~~s(rht) = s(lft)~~ ~~rht = rht - 1~~ ~~end if~~ ~~wend~~ println!("Sort strings alphabetically"); ~~s(lft) = pivot~~ let mut strings = ["beach", "hotel", "airplane", "car", "house", "art"]; ~~pivot = lft~~ println!("Before: {:?}", strings); ~~lft = lftHold~~ ~~rht = rhtHold~~ ~~if lft < pivot then~~ ~~rht = pivot - 1~~ ~~goto [qSort]~~ ~~end if~~ ~~if rht > pivot then~~ ~~lft = pivot + 1~~ ~~goto [qSort]~~ ~~end if~~ quick_sort(&mut strings, &\|x,y\| x < y); ~~for i = 1 to size~~ println!("After: {:?}\n", strings); ~~print i;"-->";s(i)~~ ~~next i</lang>~~ println!("Sort strings by length"); println!("Before: {:?}", strings); quick_sort(&mut strings, &\|x,y\| x.len() < y.len()); println!("After: {:?}", strings); } fn quick_sort<T,F>(v: &mut [T], f: &F) where F: Fn(&T,&T) -> bool { let len = v.len(); if len >= 2 { let pivot_index = partition(v, f); quick_sort(&mut v[0..pivot_index], f); quick_sort(&mut v[pivot_index + 1..len], f); } } fn partition<T,F>(v: &mut [T], f: &F) -> usize where F: Fn(&T,&T) -> bool { let len = v.len(); let pivot_index = len / 2; let last_index = len - 1; v.swap(pivot_index, last_index); let mut store_index = 0; for i in 0..last_index { if f(&v[i], &v[last_index]) { v.swap(i, store_index); store_index += 1; } } v.swap(store_index, len - 1); store_index }</syntaxhighlight> {{out}} <pre>Sort numbers in descending order Before: [4, 65, 2, -31, 0, 99, 2, 83, 782, 1] After: [782, 99, 83, 65, 4, 2, 2, 1, 0, -31] Sort strings alphabetically Before: ["beach", "hotel", "airplane", "car", "house", "art"] After: ["airplane", "art", "beach", "car", "hotel", "house"] Sort strings by length Before: ["airplane", "art", "beach", "car", "hotel", "house"] After: ["car", "art", "house", "hotel", "beach", "airplane"]</pre> Or, using functional style (slower than the imperative style but faster than functional style in other languages): <syntaxhighlight lang="rust">fn main() { let numbers = [4, 65, 2, -31, 0, 99, 2, 83, 782, 1]; println!("{:?}\n", quick_sort(numbers.iter())); } fn quick_sort<T, E>(mut v: T) -> Vec<E> where T: Iterator<Item = E>, E: PartialOrd, { match v.next() { None => Vec::new(), Some(pivot) => { let (lower, higher): (Vec<_>, Vec<_>) = v.partition(\|it\| it < &pivot); let lower = quick_sort(lower.into_iter()); let higher = quick_sort(higher.into_iter()); lower.into_iter() .chain(core::iter::once(pivot)) .chain(higher.into_iter()) .collect() } } } </syntaxhighlight> By the way this implementation needs only O(n) memory because the partition(...) call already "consumes" v. This means that the memory of v will be freed here, before the recursive calls to quick_sort(...). If we tried to use v later, we would get a compilation error. =={{header\|SASL}}== Copied from SASL manual, Appendix II, solution (2)(b) <syntaxhighlight lang="sasl">DEF \|\| this rather nice solution is due to Silvio Meira sort () = () sort (a : x) = sort {b <- x; b <= a } ++ a : sort { b <- x; b>a} ?</syntaxhighlight> =={{header\|Sather}}== <~~lang~~syntaxhighlight lang="sather">class SORT{T < $IS_LT{T}} is private afilter(a:ARRAY{T}, cmp:ROUT{T,T}:BOOL, p:T):ARRAY{T} is Line 3,267 ⟶ 9,524: a := res; end; end;</~~lang~~syntaxhighlight> <~~lang~~syntaxhighlight lang="sather">class MAIN is main is a:ARRAY{INT} := \|10, 9, 8, 7, 6, -10, 5, 4, 656, -11\|; Line 3,276 ⟶ 9,533: #OUT + a + "\n" + b.sort + "\n"; end; end;</~~lang~~syntaxhighlight> The ARRAY class has a builtin sorting method, which is quicksort (but under certain condition an insertion sort is used instead), exactly <code>quicksort_range</code>; this implementation is original. =={{header\|Scala}}== ~~I'll~~What ~~show~~follows is a progression on genericity here. First, a quick sort of a list of integers: <~~lang~~syntaxhighlight lang="scala"> def ~~quicksortInt~~sort(~~coll~~xs: List[Int]): List[Int] = xs match { case Nil => Nil ~~if (coll.isEmpty) {~~ case head :: tail => ~~coll~~ val (less, notLess) = tail.partition(_ < head) // Arbitrarily partition list in two ~~} else {~~ sort(less) ++ (head :: sort(notLess)) // Sort each half ~~val (smaller, bigger) = coll.tail partition (_ < coll.head)~~ }</syntaxhighlight> ~~quicksortInt(smaller) ::: coll.head :: quicksortInt(bigger)~~ ~~}</lang>~~ Next, a quick sort of a list of some type T, given a lessThan function: <~~lang~~syntaxhighlight lang="scala"> def ~~quicksortFunc~~sort[T](~~coll~~xs: List[T], lessThan: (T, T) => Boolean): List[T] = xs match { case Nil => Nil ~~if (coll.isEmpty) {~~ ~~coll~~case x :: xx => val (lo, hi) = xx.partition(lessThan(_, x)) ~~} else {~~ ~~val~~ sort(~~smaller~~lo, ~~bigger~~lessThan) =++ ~~coll.tail~~(x ~~partition~~:: sort(~~lessThan(_~~hi, ~~coll.head~~lessThan)) }</syntaxhighlight> ~~quicksortFunc(smaller, lessThan) ::: coll.head :: quicksortFunc(bigger, lessThan)~~ ~~}</lang>~~ To take advantage of known orderings, a quick sort of a list of some type T, for which exists an implicit (or explicit) ~~Ordered~~Ordering[T]: <~~lang~~syntaxhighlight lang="scala"> def ~~quicksortOrd~~sort[T](xs: ~~<% Ordered~~List[T]])(~~coll~~implicit ord: ~~List~~Ordering[T]): List[T] = xs match { case Nil => Nil ~~if (coll.isEmpty) {~~ ~~coll~~case x :: xx => val (lo, hi) = xx.partition(ord.lt(_, x)) ~~} else {~~ sort[T](lo) ++ (x :: sort[T](hi)) ~~val (smaller, bigger) = coll.tail partition (_ < coll.head)~~ }</syntaxhighlight> ~~quicksortOrd(smaller) ::: coll.head :: quicksortOrd(bigger)~~ ~~}</lang>~~ That last one could have worked with Ordering, but Ordering is Java, and doesn't have the less than operator. Ordered is Scala-specific, and provides it. <syntaxhighlight lang="scala"> def sort[T <: Ordered[T]](xs: List[T]): List[T] = xs match { ~~What hasn't changed in all these examples is that I'm ordering a list. It is possible~~ case Nil => Nil case x :: xx => val (lo, hi) = xx.partition(_ < x) sort(lo) ++ (x :: sort(hi)) }</syntaxhighlight> What hasn't changed in all these examples is ordering a list. It is possible to write a generic quicksort in Scala, which will order any kind of collection. To do so, however, requires that the type of the collection, itself, be made a parameter to the function. Let's see it below, and then remark upon it: <syntaxhighlight lang="scala"> def sort[T, C[T] <: scala.collection.TraversableLike[T, C[T]]] ~~<lang scala>def quicksort~~ (xs: C[T]) ~~[T, CC[X] <: Seq[X] with SeqLike[X, CC[X]]] // My type parameters~~ (implicit ord: scala.math.Ordering[T], ~~(coll: CC[T]) // My explicit parameter~~ ~~(implicit~~ o: T ~~=> Ordered[T],~~ cbf: scala.collection.generic.CanBuildFrom[CCC[T], T, CCC[T]]): //C[T] ~~My implicit~~= ~~parameters~~{ // Some collection types can't pattern match ~~: CC[T] = // My return type~~ if (~~coll~~xs.isEmpty) { ~~coll~~ xs } else { val (~~smaller~~lo, ~~bigger~~hi) = ~~coll~~xs.tail .partition (ord.lt(_, ~~< coll~~xs.head)) val b = cbf() ~~quicksort(smaller) ++ (coll.head +: quicksort(bigger))~~ b.sizeHint(xs.size) ~~}</lang>~~ b ++= sort(lo) b += xs.head b ++= sort(hi) b.result() } }</syntaxhighlight> ~~That will only work starting with Scala 2.8.~~ The type of our collection is "CCC[T]", and, by providing CCC[XT] as a type parameter to TraversableLike, we ensure CCC[T] is capable of ~~returing~~returning instances of type CCC[T]. Traversable is the base type of all collections, and TraversableLike is a trait which contains the implementation of most Traversable methods. We need another parameter, though, which is a factory capable of building a CCC[T] collection. That is being passed implicitly, so callers to this method do not need to provide them, as the collection they are using should already provide one as such ~~implicit~~implicitly. Because we need that ~~implicit~~implicitly, then we need to ask for the "T => ~~Ordered~~Ordering[T]" as well, as the "T <%: Ordered[T]" which provides it cannot be used in conjunction with implicit parameters. The body of the function is ~~pretty much~~from the ~~same~~list ofvariant, ~~the~~since ~~body~~many ~~for~~of the ~~list variant, but~~Traversable collection types don't support pattern matching, "+:" or "::". ~~using "++" instead of list-specific methods "::" and ":::", and using "coll.companion"~~ ~~to build a collection out of one element.~~ ~~We can also use pattern matching here - the first version of quicksortInt would look like that:~~ ~~<lang scala>def quicksortInt(list: List[Int]): List[Int] = list match {~~ ~~case head :: tail =>~~ ~~val (smaller, bigger) = tail partition (_ < head)~~ ~~quicksortInt(smaller) ::: head :: quicksortInt(bigger)~~ ~~case list => list~~ ~~}</lang>~~ =={{header\|Scheme}}== === List quicksort === ~~<lang scheme>(define (split-by l p k)~~ <syntaxhighlight lang="scheme">(define (split-by l p k) (let loop ((low '()) (high '()) Line 3,382 ⟶ 9,643: (quicksort high gt?)))))) (quicksort '(1 3 5 7 9 8 6 4 2) >)</~~lang~~syntaxhighlight> With srfi-1: <~~lang~~syntaxhighlight lang="scheme">(define (quicksort l gt?) (if (null? l) '() Line 3,393 ⟶ 9,654: (quicksort '(1 3 5 7 9 8 6 4 2) >) </syntaxhighlight> ~~</lang>~~ === Vector quicksort (in place) === {{works with\|Chibi Scheme}} {{works with\|Gauche Scheme}} {{works with\|CHICKEN Scheme\|5.3.0}} For CHICKEN:{{libheader\|r7rs}} <syntaxhighlight lang="scheme">;;;------------------------------------------------------------------- ;;; ;;; Quicksort in R7RS Scheme, working in-place on vectors (that is, ;;; arrays). I closely follow the "better quicksort algorithm" ;;; pseudocode, and thus the code is more "procedural" than ;;; "functional". ;;; ;;; I use a random pivot. If you can generate a random number quickly, ;;; this is a good method, but for this demonstration I have taken a ;;; fast linear congruential generator and made it brutally slow. It's ;;; just a demonstration. :) ;;; (import (scheme base)) (import (scheme case-lambda)) (import (scheme write)) ;;;------------------------------------------------------------------- ;;; ;;; Add "while" loops to the language. ;;; (define-syntax while (syntax-rules () ((_ pred? body ...) (let loop () (when pred? (begin body ...) (loop)))))) ;;;------------------------------------------------------------------- ;;; ;;; In-place quicksort. ;;; (define vector-quicksort! (case-lambda ;; Use a default pivot selector. ((<? vec) ;; Random pivot. (vector-quicksort! (lambda (vec i-first i-last) (vector-ref vec (randint i-first i-last))) <? vec)) ;; Specify a pivot selector. ((pivot-select <? vec) ;; ;; The recursion: ;; (let quicksort! ((i-first 0) (i-last (- (vector-length vec) 1))) (let ((n (- i-last i-first -1))) (when (> n 1) (let* ((pivot (pivot-select vec i-first i-last))) (let ((left i-first) (right i-last)) (while (<= left right) (while (< (vector-ref vec left) pivot) (set! left (+ left 1))) (while (> (vector-ref vec right) pivot) (set! right (- right 1))) (when (<= left right) (let ((lft (vector-ref vec left)) (rgt (vector-ref vec right))) (vector-set! vec left rgt) (vector-set! vec right lft) (set! left (+ left 1)) (set! right (- right 1))))) (quicksort! i-first right) (quicksort! left i-last))))))))) ;;;------------------------------------------------------------------- ;;; ;;; A simple linear congruential generator, attributed by ;;; https://en.wikipedia.org/w/index.php?title=Linear_congruential_generator&oldid=1083800601 ;;; to glibc and GCC. No attempt has been made to optimize this code. ;;; (define seed 1) (define two*31 (expt 2 31)) (define (random-integer) (let ((s0 seed) (s1 (truncate-remainder (+ (* 1103515245 s0) 12345) two31))) (set! seed s1) s0)) (define randint (case-lambda ((n) (truncate-remainder (random-integer) n)) ((i-first i-last) (+ i-first (randint (- i-last i-first -1)))))) ;;;------------------------------------------------------------------- ;;; ;;; A demonstration of in-place vector quicksort. ;;; (define vec1 (vector-copy #(60 53 100 72 19 67 14 31 4 1 5 9 2 6 5 3 5 8 28 9 95 22 67 55 20 41 42 29 20 74 39))) (vector-quicksort! < vec1) (write vec1) (newline) ;;;-------------------------------------------------------------------</syntaxhighlight> {{out}} <pre>$ gosh vector-quicksort.scm #(1 2 3 4 5 5 5 6 8 9 9 14 19 20 20 22 28 29 31 39 41 42 53 55 60 67 67 72 74 95 100)</pre> =={{header\|Seed7}}== <~~lang~~syntaxhighlight lang="seed7">const proc: quickSort (inout array elemType: arr, in integer: left, in integer: right) is func local var elemType: compare_elem is elemType.value; Line 3,430 ⟶ 9,810: begin quickSort(arr, 1, length(arr)); end func;</~~lang~~syntaxhighlight> Original source: [http://seed7.sourceforge.net/algorith/sorting.htm#quickSort] =={{header\|SETL}}== In-place sort (looks much the same as the C version) <~~lang~~syntaxhighlight ~~SETL~~lang="setl">a := [2,5,8,7,0,9,1,3,6,4]; qsort(a); print(a); Line 3,456 ⟶ 9,836: proc swap(rw x, rw y); [y,x] := [x,y]; end proc;</~~lang~~syntaxhighlight> Copying sort using comprehensions: <~~lang~~syntaxhighlight ~~SETL~~lang="setl">a := [2,5,8,7,0,9,1,3,6,4]; print(qsort(a)); Line 3,471 ⟶ 9,851: end if; return a; end proc;</~~lang~~syntaxhighlight> =={{header\|Sidef}}== <syntaxhighlight lang="ruby">func quicksort (a) { a.len < 2 && return(a); var p = a.pop_rand; # to avoid the worst cases __FUNC__(a.grep{ .< p}) + [p] + __FUNC__(a.grep{ .>= p}); }</syntaxhighlight> =={{header\|Simula}}== <syntaxhighlight lang="simula">PROCEDURE QUICKSORT(A); REAL ARRAY A; BEGIN PROCEDURE QS(A, FIRST, LAST); REAL ARRAY A; INTEGER FIRST, LAST; BEGIN INTEGER LEFT, RIGHT; LEFT := FIRST; RIGHT := LAST; IF RIGHT - LEFT + 1 > 1 THEN BEGIN REAL PIVOT; PIVOT := A((LEFT + RIGHT) // 2); WHILE LEFT <= RIGHT DO BEGIN WHILE A(LEFT) < PIVOT DO LEFT := LEFT + 1; WHILE A(RIGHT) > PIVOT DO RIGHT := RIGHT - 1; IF LEFT <= RIGHT THEN BEGIN REAL SWAP; SWAP := A(LEFT); A(LEFT) := A(RIGHT); A(RIGHT) := SWAP; LEFT := LEFT + 1; RIGHT := RIGHT - 1; END; END; QS(A, FIRST, RIGHT); QS(A, LEFT, LAST); END; END QS; QS(A, LOWERBOUND(A, 1), UPPERBOUND(A, 1)); END QUICKSORT; </syntaxhighlight> =={{header\|Standard ML}}== <~~lang~~syntaxhighlight lang="sml">fun quicksort [] = [] \| quicksort (x::xs) = let Line 3,480 ⟶ 9,900: in quicksort left @ [x] @ quicksort right end~~</lang>~~ </syntaxhighlight> ------------------------------------------------------------ Solution 2: Without using List.partition <syntaxhighlight lang="sml"> fun par_helper([], x, l, r) = (l, r) \| par_helper(h::t, x, l, r) = if h <= x then par_helper(t, x, l @ [h], r) else par_helper(t, x, l, r @ [h]); fun par(l, x) = par_helper(l, x, [], []); fun quicksort [] = [] \| quicksort (h::t) = let val (left, right) = par(t, h) in quicksort left @ [h] @ quicksort right end;</syntaxhighlight> =={{header\|Swift}}== <syntaxhighlight lang="swift">func quicksort<T where T : Comparable>(inout elements: [T], range: Range<Int>) { if (range.endIndex - range.startIndex > 1) { let pivotIndex = partition(&elements, range) quicksort(&elements, range.startIndex ..< pivotIndex) quicksort(&elements, pivotIndex+1 ..< range.endIndex) } } func quicksort<T where T : Comparable>(inout elements: [T]) { quicksort(&elements, indices(elements)) }</syntaxhighlight> =={{header\|Symsyn}}== <syntaxhighlight lang="symsyn"> x : 23 : 15 : 99 : 146 : 3 : 66 : 71 : 5 : 23 : 73 : 19 quicksort param l r l i r j ((l+r) shr 1) k x.k pivot repeat if pivot > x.i + cmp + i goif endif if pivot < x.j + cmp - j goif endif if i <= j swap x.i x.j - j + i endif if i <= j go repeat endif if l < j save l r i j call quicksort l j restore l r i j endif if i < r save l r i j call quicksort i r restore l r i j endif return start ' original values : ' $r call showvalues call quicksort 0 10 ' sorted values : ' $r call showvalues stop showvalues $s i if i <= 10 "$s ' ' x.i ' '" $s + i goif endif " $r $s " [] return </syntaxhighlight> =={{header\|Tailspin}}== Simple recursive quicksort: <syntaxhighlight lang="tailspin"> templates quicksort @: []; $ -> # when <[](2..)> do def pivot: $(1); [ [ $(2..last)... -> \( when <..$pivot> do $ ! otherwise ..\|@quicksort: $; \)] -> quicksort..., $pivot, $@ -> quicksort... ] ! otherwise $ ! end quicksort [4,5,3,8,1,2,6,7,9,8,5] -> quicksort -> !OUT::write </syntaxhighlight> In place: <syntaxhighlight lang="tailspin"> templates quicksort templates partial def first: $(1); def last: $(2); def pivot: $@quicksort($first); @: $(1) + 1; $(2) -> # when <..~$@> do def limit: $; @quicksort($first): $@quicksort($limit); @quicksort($limit): $pivot; [ $first, $limit - 1 ] ! [ $limit + 1, $last ] ! when <?($@quicksort($) <$pivot~..>)> do $ - 1 -> # when <?($@quicksort($@) <..$pivot>)> do @: $@ + 1; $ -> # otherwise def temp: $@quicksort($@); @quicksort($@): $@quicksort($); @quicksort($): $temp; @: $@ + 1; $ - 1 -> # end partial @: $; [1, $@::length] -> # $@ ! when <?($(1) <..~$(2)>)> do $ -> partial -> # end quicksort [4,5,3,8,1,2,6,7,9,8,5] -> quicksort -> !OUT::write </syntaxhighlight> =={{header\|Tcl}}== <~~lang~~syntaxhighlight lang="tcl">package require Tcl 8.5 proc quicksort {m} { Line 3,497 ⟶ 10,091: } puts [quicksort {8 6 4 2 1 3 5 7 9}] ;# => 1 2 3 4 5 6 7 8 9</~~lang~~syntaxhighlight> =={{header\|TypeScript}}== <syntaxhighlight lang="text"> / Generic quicksort function using typescript generics. Follows quicksort as done in CLRS. / export type Comparator<T> = (o1: T, o2: T) => number; export function quickSort<T>(array: T[], compare: Comparator<T>) { if (array.length <= 1 \|\| array == null) { return; } sort(array, compare, 0, array.length - 1); } function sort<T>( array: T[], compare: Comparator<T>, low: number, high: number) { if (low < high) { const partIndex = partition(array, compare, low, high); sort(array, compare, low, partIndex - 1); sort(array, compare, partIndex + 1, high); } } function partition<T>( array: T[], compare: Comparator<T>, low: number, high: number): number { const pivot: T = array[high]; let i: number = low - 1; for (let j = low; j <= high - 1; j++) { if (compare(array[j], pivot) == -1) { i = i + 1; swap(array, i, j) } } if (compare(array[high], array[i + 1]) == -1) { swap(array, i + 1, high); } return i + 1; } function swap<T>(array: T[], i: number, j: number) { const newJ: T = array[i]; array[i] = array[j]; array[j] = newJ; } export function testQuickSort(): void { function numberComparator(o1: number, o2: number): number { if (o1 < o2) { return -1; } else if (o1 == o2) { return 0; } return 1; } let tests: number[][] = [ [], [1], [2, 1], [-1, 2, -3], [3, 16, 8, -5, 6, 4], [1, 2, 3, 4, 5, 6], [1, 2, 3, 4, 5] ]; for (let testArray of tests) { quickSort(testArray, numberComparator); console.log(testArray); } } </syntaxhighlight> =={{header\|UnixPipes}}== {{works with\|Zsh}} <~~lang~~syntaxhighlight lang="bash">split() { (while read n ; do test $1 -gt $n && echo $n > $2 \|\| echo $n > $3 Line 3,517 ⟶ 10,179: } cat to.sort \| qsort</~~lang~~syntaxhighlight> =={{header\|Ursala}}== Line 3,529 ⟶ 10,191: natural numbers. <~~lang~~syntaxhighlight ~~Ursala~~lang="ursala">#import nat quicksort "p" = ~&itB^?a\~&a ^\|WrlT/~& "p"\|^\~& "p"?hthPX/~&th ~&h Line 3,535 ⟶ 10,197: #cast %nL example = quicksort(nleq) <694,1377,367,506,3712,381,1704,1580,475,1872></~~lang~~syntaxhighlight> {{out}} ~~output:~~ <pre> <367,381,475,506,694,1377,1580,1704,1872,3712> Line 3,543 ⟶ 10,205: =={{header\|V}}== <~~lang~~syntaxhighlight lang="v">[qsort [joinparts [p [l1] [l2] : [l1 p l2]] view]. [split_on_first uncons [>] split]. Line 3,549 ⟶ 10,211: [] [split_on_first [l1 l2 : [l1 qsort l2 qsort joinparts]] view i] ifte].</~~lang~~syntaxhighlight> The way of joy (using binrec) <~~lang~~syntaxhighlight lang="v">[qsort [small?] [] [uncons [>] split] [[p [l] [g] : [l p g]] view] binrec].</~~lang~~syntaxhighlight> {{omit from\|GUISS}} =={{header\|~~VBA~~V (Vlang)}}== <syntaxhighlight lang="v (vlang)">fn partition(mut arr []int, low int, high int) int { ~~This is the "simple" quicksort, using temporary arrays.~~ pivot := arr[high] mut i := (low - 1) for j in low .. high { if arr[j] < pivot { i++ temp := arr[i] arr[i] = arr[j] arr[j] = temp } } temp := arr[i + 1] arr[i + 1] = arr[high] arr[high] = temp return i + 1 } fn quick_sort(mut arr []int, low int, high int) { ~~<lang VBA>~~ if low < high { ~~Public Sub Quick(a() As Variant, last As Integer)~~ pi := partition(mut arr, low, high) ~~' quicksort a Variant array (1-based, numbers or strings)~~ quick_sort(mut arr, low, pi - 1) ~~Dim aLess() As Variant~~ quick_sort(mut arr, pi + 1, high) ~~Dim aEq() As Variant~~ } ~~Dim aGreater() As Variant~~ } ~~Dim pivot As Variant~~ ~~Dim naLess As Integer~~ ~~Dim naEq As Integer~~ ~~Dim naGreater As Integer~~ fn main() { ~~If last > 1 Then~~ mut arr := [4, 65, 2, -31, 0, 99, 2, 83, 782, 1] ~~'choose pivot in the middle of the array~~ n := arr.len - 1 ~~pivot = a(Int((last + 1) / 2))~~ println('Input: ' + arr.str()) ~~'construct arrays~~ quick_sort(mut arr, 0, n) ~~naLess = 0~~ println('Output: ' + arr.str()) ~~naEq = 0~~ }</syntaxhighlight> ~~naGreater = 0~~ {{out}} ~~For Each el In a()~~ <pre>Input: [4, 65, 2, -31, 0, 99, 2, 83, 782, 1] ~~If el > pivot Then~~ Output: [-31, 0, 1, 2, 2, 4, 65, 83, 99, 782]</pre> ~~naGreater = naGreater + 1~~ ~~ReDim Preserve aGreater(1 To naGreater)~~ ~~aGreater(naGreater) = el~~ ~~ElseIf el < pivot Then~~ ~~naLess = naLess + 1~~ ~~ReDim Preserve aLess(1 To naLess)~~ ~~aLess(naLess) = el~~ ~~Else~~ ~~naEq = naEq + 1~~ ~~ReDim Preserve aEq(1 To naEq)~~ ~~aEq(naEq) = el~~ ~~End If~~ ~~Next~~ ~~'sort arrays "less" and "greater"~~ ~~Quick aLess(), naLess~~ ~~Quick aGreater(), naGreater~~ ~~'concatenate~~ ~~P = 1~~ ~~For i = 1 To naLess~~ ~~a(P) = aLess(i): P = P + 1~~ ~~Next~~ ~~For i = 1 To naEq~~ ~~a(P) = aEq(i): P = P + 1~~ ~~Next~~ ~~For i = 1 To naGreater~~ ~~a(P) = aGreater(i): P = P + 1~~ ~~Next~~ ~~End If~~ ~~End Sub~~ =={{header\|Wart}}== ~~Public Sub QuicksortTest()~~ <syntaxhighlight lang="python">def (qsort (pivot ... ns)) ~~Dim a(1 To 26) As Variant~~ (+ (qsort+keep (fn(_) (_ < pivot)) ns) list.pivot (qsort+keep (fn(_) (_ > pivot)) ns)) def (qsort x) :case x=nil ~~'populate a with numbers in descending order, then sort~~ nil</syntaxhighlight> ~~For i = 1 To 26: a(i) = 26 - i: Next~~ ~~Quick a(), 26~~ ~~For i = 1 To 26: Debug.Print a(i);: Next~~ ~~Debug.Print~~ ~~'now populate a with strings in descending order, then sort~~ ~~For i = 1 To 26: a(i) = Chr$(Asc("z") + 1 - i) & "-stuff": Next~~ ~~Quick a(), 26~~ ~~For i = 1 To 26: Debug.Print a(i); " ";: Next~~ ~~Debug.Print~~ ~~End Sub~~ =={{header\|Wren}}== ~~</lang>~~ {{libheader\|Wren-sort}} <syntaxhighlight lang="wren">import "./sort" for Sort var array = [ ~~Output:~~ [4, 65, 2, -31, 0, 99, 2, 83, 782, 1], [7, 5, 2, 6, 1, 4, 2, 6, 3], ["echo", "lima", "charlie", "whiskey", "golf", "papa", "alfa", "india", "foxtrot", "kilo"] ] for (a in array) { System.print("Before: %(a)") Sort.quick(a) System.print("After : %(a)") System.print() }</syntaxhighlight> {{out}} <pre> Before: [4, 65, 2, -31, 0, 99, 2, 83, 782, 1] ~~quicksorttest~~ After : [-31, 0, 1, 2, 2, 4, 65, 83, 99, 782] ~~0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25~~ a-stuff b-stuff c-stuff d-stuff e-stuff f-stuff g-stuff h-stuff i-stuff j-stuff k-stuff l-stuff m-stuff n-stuff o-stuff p-stuff q-stuff r-stuff s-stuff t-stuff u-stuff v-stuff w-stuff x-stuff y-stuff z-stuff ~~</pre>~~ Before: [7, 5, 2, 6, 1, 4, 2, 6, 3] ~~Note: the "quicksort in place"~~ After : [1, 2, 2, 3, 4, 5, 6, 6, 7] Before: [echo, lima, charlie, whiskey, golf, papa, alfa, india, foxtrot, kilo] After : [alfa, charlie, echo, foxtrot, golf, india, kilo, lima, papa, whiskey] </pre> =={{header\|XPL0}}== <~~lang~~syntaxhighlight ~~XPL0~~lang="xpl0">include c:\cxpl\codes; \intrinsic 'code' declarations string 0; \use zero-terminated strings Line 3,673 ⟶ 10,330: QSort(Str, StrLen(Str), 1); Text(0, Str); CrLf(0); ]</~~lang~~syntaxhighlight> {{out}} Line 3,679 ⟶ 10,336: .Pabcdeefghiiijklmnoooqrstuuvwxyz </pre> =={{header\|Z80 Assembly}}== sjasmplus syntax <syntaxhighlight lang="z80">;-------------------------------------------------------------------------------------------------------------------- ; Quicksort, inputs (__sdcccall(1) calling convention): ; HL = uint16_t* A (pointer to beginning of array) ; DE = uint16_t len (number of word elements in array) ; modifies: AF, A'F', BC, DE, HL ; WARNING: array can't be aligned to start/end of 64ki address space, like HL == 0x0000, or having last value at 0xFFFE ; WARNING: stack space required is on average about 6log(len) (depending on the data, in extreme case it may be more) quicksort_a: ; convert arguments to HL=A.begin(), DE=A.end() and continue with quicksort_a_impl ex de,hl add hl,hl add hl,de ex de,hl ; \| ; fallthrough into implementation ; \| ; v ;-------------------------------------------------------------------------------------------------------------------- ; Quicksort implementation, inputs: ; HL = uint16_t A.begin() (pointer to beginning of array) ; DE = uint16_t* A.end() (pointer beyond array) ; modifies: AF, A'F', BC, HL (DE is preserved) quicksort_a_impl: ; array must be located within 0x0002..0xFFFD ld c,l ld b,h ; BC = A.begin() ; if (len < 2) return; -> if (end <= begin+2) return; inc hl inc hl or a sbc hl,de ; HL = -(2len-2), len = (2-HL)/2 ret nc ; case: begin+2 >= end <=> (len < 2) push de ; preserve A.end() for recursion push bc ; preserve A.begin() for recursion ; uint16_t pivot = A[len / 2]; rr h rr l dec hl res 0,l add hl,de ld a,(hl) inc hl ld l,(hl) ld h,b ld b,l ld l,c ld c,a ; HL = A.begin(), DE = A.end(), BC = pivot ; flip HL/DE meaning, it makes simpler the recursive tail and (A[j] > pivot) test ex de,hl ; DE = A.begin(), HL = A.end(), BC = pivot dec de ; but keep "from" address (related to A[i]) at -1 as "default" state ; for (i = 0, j = len - 1; ; i++, j--) { ; DE = (A+i-1).hi, HL = A+j+1 .find_next_swap: ; while (A[j] > pivot) j--; .find_j: dec hl ld a,b sub (hl) dec hl ; HL = A+j (finally) jr c,.find_j ; if cf=1, A[j].hi > pivot.hi jr nz,.j_found ; if zf=0, A[j].hi < pivot.hi ld a,c ; if (A[j].hi == pivot.hi) then A[j].lo vs pivot.lo is checked sub (hl) jr c,.find_j .j_found: ; while (A[i] < pivot) i++; .find_i: inc de ld a,(de) inc de ; DE = (A+i).hi (ahead +0.5 for swap) sub c ld a,(de) sbc a,b jr c,.find_i ; cf=1 -> A[i] < pivot ; if (i >= j) break; // DE = (A+i).hi, HL = A+j, BC=pivot sbc hl,de ; cf=0 since `jr c,.find_i` jr c,.swaps_done add hl,de ; DE = (A+i).hi, HL = A+j ; swap(A[i], A[j]); inc hl ld a,(de) ldd ex af,af ld a,(de) ldi ex af,af ld (hl),a ; Swap(A[i].hi, A[j].hi) done dec hl ex af,af ld (hl),a ; Swap(A[i].lo, A[j].lo) done inc bc inc bc ; pivot value restored (was -=2 by ldd+ldi) ; --j; HL = A+j is A+j+1 for next loop (ready) ; ++i; DE = (A+i).hi is (A+i-1).hi for next loop (ready) jp .find_next_swap .swaps_done: ; i >= j, all elements were already swapped WRT pivot, call recursively for the two sub-parts dec de ; DE = A+i ; quicksort_c(A, i); pop hl ; HL = A call quicksort_a_impl ; quicksort_c(A + i, len - i); ex de,hl ; HL = A+i pop de ; DE = end() (and return it preserved) jp quicksort_a_impl</syntaxhighlight> Full example with test/debug data for ZX Spectrum is at [[https://gist.github.com/ped7g/0c4e94796b474994ed88d0bdd1bf2f25 github]]. =={{header\|Zig}}== {{trans\|Rust}} '''Works with:''' 0.10.x, 0.11.x, 0.12.0-dev.1390+94cee4fb2 <syntaxhighlight lang="zig">const std = @import("std"); pub fn quickSort(comptime T: type, arr: []T, comptime compareFn: fn (T, T) bool) void { if (arr.len < 2) return; const pivot_index = partition(T, arr, compareFn); quickSort(T, arr[0..pivot_index], compareFn); quickSort(T, arr[pivot_index + 1 .. arr.len], compareFn); } fn partition(comptime T: type, arr: []T, comptime compareFn: fn (T, T) bool) usize { const pivot_index = arr.len / 2; const last_index = arr.len - 1; std.mem.swap(T, &arr[pivot_index], &arr[last_index]); var store_index: usize = 0; for (arr[0 .. arr.len - 1]) \|elem_ptr\| { if (compareFn(elem_ptr., arr[last_index])) { std.mem.swap(T, elem_ptr, &arr[store_index]); store_index += 1; } } std.mem.swap(T, &arr[store_index], &arr[last_index]); return store_index; }</syntaxhighlight> <syntaxhighlight lang="zig">const std = @import("std"); pub fn main() void { const print = std.debug.print; var arr = [_]i16{ 4, 65, 2, -31, 0, 99, 2, 83, 782, 1 }; print("Before: {any}\n\n", .{arr}); print("Sort numbers in ascending order.\n", .{}); quickSort(i16, &arr, struct { fn sortFn(left: i16, right: i16) bool { return left < right; } }.sortFn); print("After: {any}\n\n", .{arr}); print("Sort numbers in descending order.\n", .{}); quickSort(i16, &arr, struct { fn sortFn(left: i16, right: i16) bool { return left > right; } }.sortFn); print("After: {any}\n\n", .{arr}); }</syntaxhighlight> {{out}} <pre> Before: { 4, 65, 2, -31, 0, 99, 2, 83, 782, 1 } Sort numbers in ascending order. After: { -31, 0, 1, 2, 2, 4, 65, 83, 99, 782 } Sort numbers in descending order. After: { 782, 99, 83, 65, 4, 2, 2, 1, 0, -31 } </pre> =={{header\|zkl}}== These are the Wikipedia algorithms. Quick sort immutable sequence using crappy pivot choice: <syntaxhighlight lang="zkl">fcn qtSort(list,cmp=Op("<")){ // sort immutable lists fcn(list,cmp,N){ // spendy to keep recreating cmp reg pivot=list[0], rest=list[1,]; left,right:=rest.filter22(cmp,pivot); N+=1; T.extend(self.fcn(left,cmp,N),T(pivot),self.fcn(right,cmp,N)); }(list,cmp,0); }</syntaxhighlight> In place quick sort: <syntaxhighlight lang="zkl">fcn qiSort(list,cmp='<){ // in place quick sort fcn(list,left,right,cmp){ if (left<right){ // partition list pivotIndex:=(left+right)/2; // or median of first,middle,last pivot:=list[pivotIndex]; list.swap(pivotIndex,right); // move pivot to end pivotIndex:=left; i:=left; do(right-left){ // foreach i in ([left..right-1]) if(cmp(list[i],pivot)){ // not cheap list.swap(i,pivotIndex); pivotIndex+=1; } i+=1; } list.swap(pivotIndex,right); // move pivot to final place // sort the partitions self.fcn(list,left,pivotIndex-1,cmp); return(self.fcn(list,pivotIndex+1,right,cmp)); } }(list,0,list.len()-1,cmp); list; }</syntaxhighlight>