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=={{header|Ursala}}== |
=={{header|Ursala}}== |
Revision as of 00:03, 1 February 2010
You are encouraged to solve this task according to the task description, using any language you may know.
Sorting Algorithm
This is a sorting algorithm. It may be applied to a set of data in order to sort it.
For comparing various sorts, see compare sorts.
For other sorting algorithms, see sorting algorithms, or:
Heap sort | Merge sort | Patience sort | Quick sort
O(n log2n) sorts
Shell Sort
O(n2) sorts
Bubble sort |
Cocktail sort |
Cocktail sort with shifting bounds |
Comb sort |
Cycle sort |
Gnome sort |
Insertion sort |
Selection sort |
Strand sort
other sorts
Bead sort |
Bogo sort |
Common sorted list |
Composite structures sort |
Custom comparator sort |
Counting sort |
Disjoint sublist sort |
External sort |
Jort sort |
Lexicographical sort |
Natural sorting |
Order by pair comparisons |
Order disjoint list items |
Order two numerical lists |
Object identifier (OID) sort |
Pancake sort |
Quickselect |
Permutation sort |
Radix sort |
Ranking methods |
Remove duplicate elements |
Sleep sort |
Stooge sort |
[Sort letters of a string] |
Three variable sort |
Topological sort |
Tree sort
In this task, the goal is to sort an array (or list) of elements using the Selection sort algorithm. It works as follows:
First find the smallest element in the array and exchange it with the element in the first position, then find the second smallest element and exchange it with the element in the second position, and continue in this way until the entire array is sorted. Its asymptotic complexity is O(n2) making it inefficient on large arrays.
Ada
<lang ada>with Ada.Text_IO; use Ada.Text_IO;
procedure Test_Selection_Sort is
type Integer_Array is array (Positive range <>) of Integer; procedure Sort (A : in out Integer_Array) is Min : Positive; Temp : Integer; begin for I in A'First..A'Last - 1 loop Min := I; for J in I + 1..A'Last loop if A (Min) > A (J) then Min := J; end if; end loop; if Min /= I then Temp := A (I); A (I) := A (Min); A (Min) := Temp; end if; end loop; end Sort;
A : Integer_Array := (4, 9, 3, -2, 0, 7, -5, 1, 6, 8);
begin
Sort (A); for I in A'Range loop Put (Integer'Image (A (I)) & " "); end loop;
end Test_Selection_Sort;</lang> Sample output:
-5 -2 0 1 3 4 6 7 8 9
ALGOL 68
<lang algol68>MODE DATA = REF CHAR;
PROC in place selection sort = (REF[]DATA a)VOID: BEGIN
INT min; DATA temp; FOR i FROM LWB a TO UPB a DO min := i; FOR j FROM i + 1 TO UPB a DO IF a [min] > a [j] THEN min := j FI OD; IF min /= i THEN temp := a [i]; a [i] := a [min]; a [min] := temp FI OD
END # in place selection sort #;
[32]CHAR data := "big fjords vex quick waltz nymph"; [UPB data]DATA ref data; FOR i TO UPB data DO ref data[i] := data[i] OD; in place selection sort(ref data); FOR i TO UPB ref data DO print(ref data[i]) OD; print(new line); print((data))</lang> Output:
abcdefghiijklmnopqrstuvwxyz big fjords vex quick waltz nymph
AutoHotkey
ahk forum: discussion <lang AutoHotkey>MsgBox % SelecSort("") MsgBox % SelecSort("xxx") MsgBox % SelecSort("3,2,1") MsgBox % SelecSort("dog,000000,xx,cat,pile,abcde,1,cat,zz,xx,z")
SelecSort(var) { ; SORT COMMA SEPARATED LIST
StringSplit a, var, `, ; make array, size = a0
Loop % a0-1 { i := A_Index, mn := a%i%, j := m := i Loop % a0-i { ; find minimum j++ If (a%j% < mn) mn := a%j%, m := j } t := a%i%, a%i% := a%m%, a%m% := t ; swap first with minimum } Loop % a0 ; construct string from sorted array sorted .= "," . a%A_Index% Return SubStr(sorted,2) ; drop leading comma
}</lang>
AWK
<lang awk>function getminindex(gl, gi, gs) {
min = gl[gi] gm = gi for(gj=gi; gj <= gs; gj++) { if ( gl[gj] < min ) { min = gl[gj] gm = gj } } return gm
}
{
line[NR] = $0
} END { # sort it with selection sort
for(i=1; i <= NR; i++) { mi = getminindex(line, i, NR) t = line[i] line[i] = line[mi]; line[mi] = t } #print it for(i=1; i <= NR; i++) { print line[i] }
}</lang>
C
<lang c>#include <stdio.h>
int getminindex(int *a, int s, int b)
{
int i, min=a[s], mi=s; for(i=s; i < b; i++) { if ( a[i] < min ) { min = a[i]; mi = i; } } return mi;
}
void selectionsort(int *a, int s) {
int i, t, mi; for(i=0; i<s ; i++) { mi = getminindex(a, i, s); t = a[i]; a[i] = a[mi]; a[mi] = t; }
}
int main()
{
int ar[] = { 5, 200, 1, 65, 30, 99, 2, 0 }; int i; selectionsort(ar, 8); for(i=0; i<8; i++) { printf("%d\n", ar[i]); } return 0;
}</lang>
Sample output
0 1 2 5 30 65 99 200
C++
Compiler: g++ (version 4.3.2 20081105 (Red Hat 4.3.2-7))
<lang cpp>#include <algorithm>
- include <iterator>
template<typename ForwardIterator> void selectionSort(ForwardIterator begin, ForwardIterator end) {
ForwardIterator i = begin; while(i != end) { ForwardIterator j = i; ForwardIterator min = i; while(j != end) { if(*j < *min) { min = j; } ++j; } std::iter_swap(i, min); ++i; }
}</lang>
C#
This is a generic implementation that works with any type that implements the IComparable interface
<lang csharp>class SelectionSort<T> where T : IComparable {
public T[] Sort(T[] list) { int k; T temp;
for (int i = 0; i < list.Length; i++) { k = i; for (int j=i + 1; j < list.Length; j++) { if (list[j].CompareTo(list[k]) < 0) { k = j; } } temp = list[i]; list[i] = list[k]; list[k] = temp; }
return list; }
}</lang>
Example of usage: <lang csharp>String[] str = { "this", "is", "a", "test", "of", "generic", "selection", "sort" };
SelectionSort<String> mySort = new SelectionSort<string>();
String[] result = mySort.Sort(str);
for (int i = 0; i < result.Length; i++) {
Console.WriteLine(result[i]);
}</lang>
Output:
a generic is of selection sort test this
Clojure
This is an implementation that mutates a Java arraylist in place.
<lang lisp>(import 'java.util.ArrayList)
(defn arr-swap! [#^ArrayList arr i j]
(let [t (.get arr i)] (doto arr (.set i (.get arr j)) (.set j t))))
(defn sel-sort!
([arr] (sel-sort! compare arr)) ([cmp #^ArrayList arr] (let [n (.size arr)] (letfn [(move-min!
[start-i] (loop [i start-i] (when (< i n) (when (< (cmp (.get arr i) (.get arr start-i)) 0) (arr-swap! arr start-i i)) (recur (inc i)))))] (doseq [start-i (range (dec n))] (move-min! start-i)) arr))))</lang>
Common Lisp
<lang lisp>(defun selection-sort-vector (array predicate)
(do ((length (length array)) (i 0 (1+ i))) ((eql i length) array) (do ((mindex i) (min (aref array i)) (j i (1+ j))) ((eql j length) (rotatef (aref array i) (aref array mindex))) (when (funcall predicate (aref array j) min) (setf min (aref array j) mindex j)))))
(defun selection-sort-list (list predicate)
(flet ((min-first (list) (do ((before-min nil) (min (first list)) (prev list (rest prev)) (curr (rest list) (rest curr))) ((endp curr) (if (null before-min) list (let ((min (cdr before-min))) (rplacd before-min (cdr min)) (rplacd min list) min))) (when (funcall predicate (first curr) min) (setf before-min prev min (first curr)))))) (let ((result (min-first list))) (do ((head result (rest head))) ((endp (rest head)) result) (rplacd head (min-first (rest head)))))))
(defun selection-sort (sequence predicate)
(etypecase sequence (list (selection-sort-list sequence predicate)) (vector (selection-sort-vector sequence predicate))))</lang>
Example use:
> (selection-sort (list 8 7 4 3 2 0 9 1 5 6) '<) (0 1 2 3 4 5 6 7 8 9) > (selection-sort (vector 8 7 4 3 2 0 9 1 5 6) '>) #(9 8 7 6 5 4 3 2 1 0)
D
<lang d>// Written in D 2.0.
import std.stdio;
void swap(T)(ref T lhs, ref T rhs) {
T temp = lhs; lhs = rhs; rhs = temp;
}
void selectionSort(T)(T[] data) {
foreach(i; 0..data.length) { size_t minIndex = i; foreach(j; i + 1..data.length) { if(data[j] < data[minIndex]) { minIndex = j; } } swap(data[i], data[minIndex]); }
}
void main() {
auto foo = [3, 1, 4, 1, 5, 9, 2, 6, 5, 3, 5, 8, 9, 7, 9, 3, 2]; selectionSort(foo); writeln(foo);
}</lang>
E
<lang e>def selectionSort := {
def cswap(c, a, b) { def t := c[a] c[a] := c[b] c[b] := t println(c) } def indexOfMin(array, first, last) { var min := array[first] var mini := first for i in (first+1)..last { if (array[i] < min) { min := array[i] mini := i } } return mini }
/** Selection sort (in-place). */ def selectionSort(array) { def last := (array.size()-1) for i in 0..(last - 1) { cswap(array, i, indexOfMin(array, i + 1, last)) } }
}</lang>
Forth
<lang forth>defer less? ' < is less?
- least ( start end -- least )
over cell+ do i @ over @ less? if drop i then cell +loop ;
- selection ( array len -- )
cells over + tuck ( end start end ) cell- swap do ( end ) i over least ( end least ) i @ over @ i ! swap ! cell +loop drop ;
create array 8 , 1 , 4 , 2 , 10 , 3 , 7 , 9 , 6 , 5 ,
array 10 selection array 10 cells dump</lang>
Fortran
<lang fortran>PROGRAM SELECTION
IMPLICIT NONE
INTEGER :: intArray(10) = (/ 4, 9, 3, -2, 0, 7, -5, 1, 6, 8 /) WRITE(*,"(A,10I5)") "Unsorted array:", intArray CALL Selection_sort(intArray) WRITE(*,"(A,10I5)") "Sorted array :", intArray
CONTAINS
SUBROUTINE Selection_sort(a) INTEGER, INTENT(IN OUT) :: a(:) INTEGER :: i, minIndex, temp
DO i = 1, SIZE(a)-1 minIndex = MINLOC(a(i:), 1) + i - 1 IF (a(i) > a(minIndex)) THEN temp = a(i) a(i) = a(minIndex) a(minIndex) = temp END IF END DO END SUBROUTINE Selection_sort
END PROGRAM SELECTION</lang> Output:
Unsorted array: 4 9 3 -2 0 7 -5 1 6 8 Sorted array : -5 -2 0 1 3 4 6 7 8 9
Haskell
<lang haskell>selectionSort [] = [] selectionSort (first:lst) = selectR first [] lst where
selectR small output [] = small : selectionSort output selectR small output (x:xs) | x < small = selectR x (small:output) xs | otherwise = selectR small (x:output) xs</lang>
HaXe
<lang HaXe>static function selectionSort(arr:Array<Int>) { var len = arr.length; for (index in 0...len) { var minIndex = index; for (remainingIndex in (index+1)...len) { if (arr[minIndex] > arr[remainingIndex]) { minIndex = remainingIndex; } } if (index != minIndex) { var temp = arr[index]; arr[index] = arr[minIndex]; arr[minIndex] = temp; } } }</lang>
J
Create the following script and load it to a J session. <lang j>selectionSort=: verb define data=. y for_xyz. y do.
temp=. xyz_index }. data nvidx=. xyz_index + temp i. <./ temp data=. ((xyz_index, nvidx) { data) (nvidx, xyz_index) } data
end. data )</lang>
In an email discussion, Roger_Hui presented the following tacit code: <lang j>ix=: C.~ <@~.@(0, (i. <./)) ss1=: ({. , $:@}.)@ix^:(*@#)</lang>
To validate: <lang j> [data=. 6 15 19 12 14 19 0 17 0 14 6 15 19 12 14 19 0 17 0 14
selectionSort data
0 0 6 12 14 14 15 17 19 19
ss1 data
0 0 6 12 14 14 15 17 19 19</lang>
Java
This algorithm sorts in place. The call sort(array) will rearrange the array and not create a new one. <lang java>public static void sort(int[] nums){ for(int currentPlace = 0;currentPlace<nums.length-1;currentPlace++){ int smallest = Integer.MAX_VALUE; int smallestAt = currentPlace+1; for(int check = currentPlace; check<nums.length;check++){ if(nums[check]<smallest){ smallestAt = check; smallest = nums[check]; } } int temp = nums[currentPlace]; nums[currentPlace] = nums[smallestAt]; nums[smallestAt] = temp; } }</lang>
MAXScript
<lang maxscript>fn selectionSort arr = (
local min = undefined for i in 1 to arr.count do ( min = i for j in i+1 to arr.count do ( if arr[j] < arr[min] then ( min = j ) ) swap arr[i] arr[min] ) arr
)
data = selectionSort #(4, 9, 3, -2, 0, 7, -5, 1, 6, 8) print data</lang>
OCaml
<lang ocaml>let rec selection_sort = function
[] -> [] | first::lst -> let rec select_r small output = function [] -> small :: selection_sort output | x::xs when x < small -> select_r x (small::output) xs | x::xs -> select_r small (x::output) xs in select_r first [] lst</lang>
Oz
Although lists are much more used in Oz than arrays, this algorithm seems more natural for arrays. <lang oz>declare
proc {SelectionSort Arr} proc {Swap K L} Arr.K := (Arr.L := Arr.K) end Low = {Array.low Arr} High = {Array.high Arr} in %% for every index I of the array for I in Low..High do
%% find the index of the minimum element %% with an index >= I Min = {NewCell Arr.I}
MinIndex = {NewCell I} in for J in I..High do if Arr.J < @Min then
Min := Arr.J MinIndex := J
end
end %% and put that minimum element to the left {Swap @MinIndex I}
end end A = {Tuple.toArray unit(3 1 4 1 5 9 2 6 5)}
in
{SelectionSort A} {Show {Array.toRecord unit A}}</lang>
Perl
<lang perl>sub selection_sort
{my @a = @_; foreach my $i (0 .. $#a - 1) {my $min = $i + 1; $a[$_] < $a[$min] and $min = $_ foreach $min .. $#a; $a[$i] > $a[$min] and @a[$i, $min] = @a[$min, $i];} return @a;}</lang>
Python
<lang python>def selectionSort(lst):
for i in range(0,len(lst)-1): mn = min(range(i,len(lst)), key=lst.__getitem__) lst[i],lst[mn] = lst[mn],lst[i] return lst</lang>
R
For loop: <lang r>selectionsort.loop <- function(x) {
lenx <- length(x) for(i in seq_along(x)) { mini <- (i - 1) + which.min(x[i:lenx]) start_ <- seq_len(i-1) x <- c(x[start_], x[mini], x[-c(start_, mini)]) } x
}</lang> Recursive:
(A prettier solution, but, you may need to increase the value of options("expressions") to test it. Also, you may get a stack overflow if the length of the input vector is more than a few thousand.) <lang r>selectionsort.rec <- function(x) {
if(length(x) > 1) { mini <- which.min(x) c(x[mini], selectionsort(x[-mini])) } else x
}</lang>
Ruby
<lang ruby>class Array
def selectionsort! 0.upto(length - 2) do |i| (min_idx = i + 1).upto(length - 1) do |j| if self[j] < self[min_idx] min_idx = j end end if self[i] > self[min_idx] self[i], self[min_idx] = self[min_idx], self[i] end end self end
end ary = [7,6,5,9,8,4,3,1,2,0] ary.selectionsort!
- => [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]</lang>
Scala
<lang scala>def swap(a: Array[Int], i1: Int, i2: Int) = { val tmp = a(i1); a(i1) = a(i2); a(i2) = tmp }
def selectionSort(a: Array[Int]) =
for (i <- 0 until a.size - 1) swap(a, i, (i + 1 until a.size).foldLeft(i)((currMin, index) => if (a(index) < a(currMin)) index else currMin))</lang>
This version avoids the extra definition by using a function literal:
<lang scala>def selectionSort(a: Array[Int]) = for (i <- 0 until a.size - 1) (
{ (i1: Int, i2: Int) => val tmp = a(i1); a(i1) = a(i2); a(i2) = tmp } ) (i, (i + 1 until a.size).foldLeft(i)((currMin, index) => if (a(index) < a(currMin)) index else currMin) )</lang>
Standard ML
<lang sml>fun selection_sort [] = []
| selection_sort (first::lst) = let fun select_r small ([], output) = small :: selection_sort output | select_r small (x::xs, output) = if x < small then select_r x (xs, small::output) else select_r small (xs, x::output) in select_r first (lst, []) end</lang>
Tcl
Uses struct::list
package from
<lang tcl>package require Tcl 8.5 package require struct::list
proc selectionsort {A} {
set len [llength $A] for {set i 0} {$i < $len - 1} {incr i} { set min_idx [expr {$i + 1}] for {set j $min_idx} {$j < $len} {incr j} { if {[lindex $A $j] < [lindex $A $min_idx]} { set min_idx $j } } if {[lindex $A $i] > [lindex $A $min_idx]} { struct::list swap A $i $min_idx } } return $A
}
puts [selectionsort {8 6 4 2 1 3 5 7 9}] ;# => 1 2 3 4 5 6 7 8 9</lang>
TI-83 BASIC
Store input into L1 and prgmSORTSLCT will store the sorted output into L2.
:L1→L2 :dim(L2)→I :For(A,1,I) :A→C :0→X :For(B,A,I) :If L2(B)<L2(C) :Then :B→C :1→X :End :End :If X=1 :Then :L2(C)→B :L2(A)→L2(C) :B→L2(A) :End :End :DelVar A :DelVar B :DelVar C :DelVar I :DelVar X :Return
Ursala
The selection_sort function is parameterized by a relational predicate p. There are no arrays in Ursala so it uses a list, and the selected item is deleted from the list and inserted into another on each iteration rather than swapped with a preceding item of the same list. <lang Ursala>#import std
selection_sort "p" = @iNX ~&l->rx ^(gldif ==,~&r)^/~&l ^|C/"p"$- ~&</lang> This is already a bad way to code a sorting algorithm in this language, but with only a bit more work, we can get a bigger and slower version that more closely simulates the operations of repeatedly reordering an array. <lang Ursala>selection_sort "p" = ~&itB^?a\~&a ^|JahPfatPRC/~& ~=-~BrhPltPClhPrtPCTlrTQrS^D/"p"$- ~&</lang> Here is a test program sorting by the partial order relation on natural numbers. <lang Ursala>#import nat
- cast %nL
example = selection_sort(nleq) <294,263,240,473,596,392,621,348,220,815></lang> output:
<220,240,263,294,348,392,473,596,621,815>