The problem: Consider the following floats[]:

d[i] =     1.7 -0.3  2.1  0.5

What I want is an array of int[] that represents the order of the original array with indices.

s[i] =       1    3    0    2
d[s[i]] = -0.3  0.5  1.7  2.1

Of course it could be done with a custom comparator, a sorted set of custom objects, or by simply sorting the array and then searching for the indices in the original array (shudder).

What I am in fact looking for is the equivalent for the second return argument of Matlab's sort function.

Is there an easy way to do that (<5 LOC)? May there be a solution that does not need to allocate a new object for each element?


Thanks for your responses. Unfortunately, none of what has been proposed so far resembles the simple and efficient solution I was hoping for. I therefore openened a thread in the JDK feedback forum, proposing the addition of a new class-library function to address the issue. Lets see what Sun/Oracle thinks about the issue.


  • even if this were put into the JDK, something I really doubt would ever happen, it would end up being a static utility method on the Arrays class (or something similar) and would end up being implemented very similar to something below. So why can't you just write the function? – Jherico Jun 12 '09 at 3:36
  • What is the problem with a custom comparator as a solution? I may be misunderstanding the approach this implies in your mind. – jerryjvl Jun 12 '09 at 3:38
  • Maybe I'm not looking hard enough, but for what I know there is no way to use a Comparator without boxing every element on each call to the Comparator. For an array of n floats that would mean 2*n*log(n) Floats for the garbage collector. With n=10000 that means 80000 pieces of garbage. I would much prefer a static utility method in the Arrays class. If I didn't care about the garbage, I could have used a TreeMap or something in the first place. – edgar.holleis Jun 17 '09 at 18:39
  • This is so useful and I wish you could do it in Java. In R you can just use the rank() function. – twolfe18 Sep 30 '10 at 1:13
  • If you have less than 5000 numbers, just use bubble sort. It's easy to read, short, and fast enough. – Thomas Ahle Nov 17 '11 at 14:26

15 Answers 15


I would tailor the quicksort algorithm to perform the exchange operation on multiple arrays at the same time: the index array and the value array. For example (based on this quicksort):

public static void quicksort(float[] main, int[] index) {
    quicksort(main, index, 0, index.length - 1);

// quicksort a[left] to a[right]
public static void quicksort(float[] a, int[] index, int left, int right) {
    if (right <= left) return;
    int i = partition(a, index, left, right);
    quicksort(a, index, left, i-1);
    quicksort(a, index, i+1, right);

// partition a[left] to a[right], assumes left < right
private static int partition(float[] a, int[] index, 
int left, int right) {
    int i = left - 1;
    int j = right;
    while (true) {
        while (less(a[++i], a[right]))      // find item on left to swap
            ;                               // a[right] acts as sentinel
        while (less(a[right], a[--j]))      // find item on right to swap
            if (j == left) break;           // don't go out-of-bounds
        if (i >= j) break;                  // check if pointers cross
        exch(a, index, i, j);               // swap two elements into place
    exch(a, index, i, right);               // swap with partition element
    return i;

// is x < y ?
private static boolean less(float x, float y) {
    return (x < y);

// exchange a[i] and a[j]
private static void exch(float[] a, int[] index, int i, int j) {
    float swap = a[i];
    a[i] = a[j];
    a[j] = swap;
    int b = index[i];
    index[i] = index[j];
    index[j] = b;
  • 3
    Even though far from the desired <= 5 LOC requirement, it's the only solution offered so far, that maintains reasonable performance characteristic. Sorry folks :-( – edgar.holleis Jul 3 '09 at 13:03
  • 2
    This is very sad. I have the same problem, and this is the only acceptable solution for large data sets. – ansgri Jan 14 '10 at 3:14
  • 3
    But this solution modifies the data array. Normally the point of sorting an index is to avoid modifying the data order. To make it read-only, don't swap the data in exch() and replace each a[x] with a[index[x]]. – xan Jan 1 '11 at 21:14
  • Finally someone that gets it! Thanks! – stolsvik Feb 18 '17 at 20:03

Simple solution to create an indexer array: sort the indexer comparing the data values:

final Integer[] idx = { 0, 1, 2, 3 };
final float[] data = { 1.7f, -0.3f,  2.1f,  0.5f };

Arrays.sort(idx, new Comparator<Integer>() {
    @Override public int compare(final Integer o1, final Integer o2) {
        return Float.compare(data[o1], data[o2]);
  • Quite elegant, but uses an unfortunate amount autoboxing. I therefore suspect it's not as efficient as kd304's answer. It's simpler though. – edgar.holleis Apr 23 '10 at 10:09
  • Try to speed test it. If the integers are small, not much autoboxing will be used. And java's sort is more optimized than kd304's. – Thomas Ahle Nov 17 '11 at 14:24
  • Definitely what I was looking for. The final is a minor drawback – keyser Mar 8 '14 at 15:27
  • 1
    @keyser why is final a drawback? – Neo M Hacker Jun 5 '15 at 7:41
  • @NeoMHacker It's a requirement since we are using it in an anonymous inner class, not much trouble in this case since we are not modifying the data array anyway. See stackoverflow.com/q/4162531/209882 – Bar Apr 12 '17 at 12:45

Create a TreeMap of values to indices

    float[] array = new float[]{};
    Map<Float, Integer> map = new TreeMap<Float, Integer>();
    for (int i = 0; i < array.length; ++i) {
        map.put(array[i], i);
    Collection<Integer> indices = map.values();

indices will be the sorted by the floats they point to, the original array is untouched. Converting the Collection<Integer> to a int[] is left as an exercise if it's really necessary.

EDIT: As noted in the comments, this approach does not work if there are duplicate values in the float array. This can be addressed by making the Map<Float, Integer> into a Map<Float, List<Integer>> though this will complicate the inside of the for loop and the generation of the final collection slightly.

  • precisely the mapping I was putting together. – Tetsujin no Oni Jun 4 '09 at 17:19
  • Uses an unfortunate amount of autoboxing, but does the trick. +1 – Michael Myers Jun 4 '09 at 17:25
  • 9
    The flaw with this approach is that is does not handle duplicate float values. – Mark Jun 5 '09 at 9:12

Using Java 8 features ( without extra library) , concise way of achieving it.

int[] a = {1,6,2,7,8}
int[] sortedIndices = IntStream.range(0, a.length)
                .boxed().sorted((i, j) -> a[i] - a[j])
                .mapToInt(ele -> ele).toArray();

With Functional Java:

import static fj.data.Array.array;
import static fj.pre.Ord.*;
import fj.P2;

array(d).toStream().zipIndex().sort(p2Ord(doubleOrd, intOrd))
  .map(P2.<Double, Integer>__2()).toArray();
  • 5
    Don't take this the wrong way... but - wow! Totally unreadable code! Sorry - just couldn't resist :-) It does meet the <5 LOC requirement though - including the imports - very impressive! – Kevin Day Jun 5 '09 at 5:43
  • 5
    Unreadable how? Let's read it. Take your array to a stream, pair (zip) each element with its index, quicksort them by pair order (by the double first, then the int), get the second half of each pair, and then take all that to an array. Easy! – Apocalisp Jun 5 '09 at 6:46
  • It's only unreadable if you're new to functional programming. This kind of thing is perfectly normal in functional languages. Can this be done in Java 8 without a 3rd party library? – SigmaX Feb 13 '15 at 3:35

The more general case of Jherico's answer that allows duplicate values would be this:

// Assuming you've got: float[] array; defined already

TreeMap<Float, List<Integer>> map = new TreeMap<Float, List<Integer>>();
for(int i = 0; i < array.length; i++) {
    List<Integer> ind = map.get(array[i]);
    if(ind == null){
        ind = new ArrayList<Integer>();
        map.put(array[i], ind);

// Now flatten the list
List<Integer> indices = new ArrayList<Integer>();
for(List<Integer> arr : map.values()) {
  • I think map.put(array[i], ind); should be placed after ind.add(i); – lizzie Feb 7 '14 at 9:58
  • @lizzie it works as is, because ind holds the location of the list, and the thing being updated by ind.add will be the same as the thing in the map. – Mark Elliot Feb 8 '14 at 10:19

The best solution would be along the lines of C's qsort, which allows you to specify functions for compare and swap, so qsort needn't be aware of the type or organization of the data being sorted. Here is one you can try. Since Java doesn't have functions, use the Array inner class to wrap the array or collection to be sorted. Then wrap that in an IndexArray and sort. The result of getIndex() on the IndexArray will be an array of indices as described in the JavaDoc.

public class QuickSortArray {

public interface Array {
    int cmp(int aindex, int bindex);
    void swap(int aindex, int bindex);
    int length();

public static void quicksort(Array a) {
    quicksort(a, 0, a.length() - 1);

public static void quicksort(Array a, int left, int right) {
    if (right <= left) return;
    int i = partition(a, left, right);
    quicksort(a, left, i-1);
    quicksort(a, i+1, right);

public static boolean isSorted(Array a) {
    for (int i = 1, n = a.length(); i < n; i++) {
        if (a.cmp(i-1, i) > 0)
            return false;
    return true;

private static int mid(Array a, int left, int right) {
    // "sort" three elements and take the middle one
    int i = left;
    int j = (left + right) / 2;
    int k = right;
    // order the first two
    int cmp = a.cmp(i, j);
    if (cmp > 0) {
        int tmp = j;
        j = i;
        i = tmp;
    // bubble the third down
    cmp = a.cmp(j, k);
    if (cmp > 0) {
        cmp = a.cmp(i, k);
        if (cmp > 0)
            return i;
        return k;
    return j;

private static int partition(Array a, int left, int right) {
    int mid = mid(a, left, right);
    a.swap(right, mid);
    int i = left - 1;
    int j = right;

    while (true) {
        while (a.cmp(++i, right) < 0)
        while (a.cmp(right, --j) < 0)
            if (j == left) break;
        if (i >= j) break;
        a.swap(i, j);
    a.swap(i, right);
    return i;

public static class IndexArray implements Array {
    int[] index;
    Array a;

    public IndexArray(Array a) {
        this.a = a;
        index = new int[a.length()];
        for (int i = 0; i < a.length(); i++)
            index[i] = i;

     * Return the index after the IndexArray is sorted.
     * The nested Array is unsorted. Assume the name of
     * its underlying array is a. The returned index array
     * is such that a[index[i-1]] <= a[index[i]] for all i
     * in 1..a.length-1.
    public int[] index() {
        int i = 0;
        int j = index.length - 1;
        while (i < j) {
            int tmp = index[i];
            index[i++] = index[j];
            index[j--] = tmp;
        int[] tmp = index;
        index = null;
        return tmp;

    public int cmp(int aindex, int bindex) {
        return a.cmp(index[aindex], index[bindex]);

    public void swap(int aindex, int bindex) {
        int tmp = index[aindex];
        index[aindex] = index[bindex];
        index[bindex] = tmp;

    public int length() {
        return a.length();

public static int[] indexSort(final double[] v, boolean keepUnsorted) {
    final Integer[] II = new Integer[v.length];
    for (int i = 0; i < v.length; i++) II[i] = i;
    Arrays.sort(II, new Comparator<Integer>() {
        public int compare(Integer o1, Integer o2) {
            return Double.compare(v[o1],v[o2]);
    int[] ii = new int[v.length];
    for (int i = 0; i < v.length; i++) ii[i] = II[i];
    if (!keepUnsorted) {
        double[] clon = v.clone();
        for (int i = 0; i < v.length; i++) v[i] = clon[II[i]];
    return ii;
  • It would be better if you added a small explanation to this code. – vefthym May 6 '14 at 15:41
  • nice! i liked this one! – Ofek Ron May 22 '14 at 19:08

Convert the input to a pair class like the one below and then sort this using Arrays.sort(). Arrays.sort() ensures that original order is preserved for equal values like Matlab does. You then need to convert the sorted result back to the separate arrays.

class SortPair implements Comparable<SortPair>
  private int originalIndex;
  private double value;

  public SortPair(double value, int originalIndex)
    this.value = value;
    this.originalIndex = originalIndex;

  @Override public int compareTo(SortPair o)
    return Double.compare(value, o.getValue());

  public int getOriginalIndex()
    return originalIndex;

  public double getValue()
    return value;



Another non-simple solution. Here's a merge sort version which is stable and doesn't modify the source array, though the merge requires extra memory.

public static int[] sortedIndices(double[] x) {
    int[] ix = new int[x.length];
    int[] scratch = new int[x.length];
    for (int i = 0; i < ix.length; i++) {
        ix[i] = i;
    mergeSortIndexed(x, ix, scratch, 0, x.length - 1);
    return ix;

private static void mergeSortIndexed(double[] x, int[] ix, int[] scratch, int lo, int hi) {
    if (lo == hi)
    int mid = (lo + hi + 1) / 2;
    mergeSortIndexed(x, ix, scratch, lo, mid - 1);
    mergeSortIndexed(x, ix, scratch, mid, hi);
    mergeIndexed(x, ix, scratch, lo, mid - 1, mid, hi);

private static void mergeIndexed(double[] x, int[] ix, int[] scratch, int lo1, int hi1, int lo2, int hi2) {
    int i = 0;
    int i1 = lo1;
    int i2 = lo2;
    int n1 = hi1 - lo1 + 1;
    while (i1 <= hi1 && i2 <= hi2) {
        if (x[ix[i1]] <= x[ix[i2]])
            scratch[i++] = ix[i1++];
            scratch[i++] = ix[i2++];
    while (i1 <= hi1)
        scratch[i++] = ix[i1++];
    while (i2 <= hi2)
        scratch[i++] = ix[i2++];
    for (int j = lo1; j <= hi1; j++)
        ix[j] = scratch[j - lo1];
    for (int j = lo2; j <= hi2; j++)
        ix[j] = scratch[(j - lo2 + n1)];
//Here index array(of length equal to length of d array) contains the numbers from 0 to length of d array   
      public static Integer [] SortWithIndex(float[] data, Integer [] index)
    int len = data.length;
    float temp1[] = new float[len];
    int temp2[] = new int[len];

         for (int i = 0; i <len; i++) {

                for (int j = i + 1; j < len; j++) {

                    temp1[i] = data[i];
                    data[i] = data[j];
                    data[j] = temp1[i];

                    temp2[i] = index[i];
                    index[i] = index[j];
                    index[j] = temp2[i];



        return index;


I would do something like this:

public class SortedArray<T extends Comparable<T>> {
    private final T[] tArray;
    private final ArrayList<Entry> entries;

    public class Entry implements Comparable<Entry> {
        public int index;

        public Entry(int index) {
            this.index = index;

        public int compareTo(Entry o) {
            return tArray[index].compareTo(tArray[o.index]);

    public SortedArray(T[] array) {
        tArray = array;
        entries = new ArrayList<Entry>(array.length);
        for (int i = 0; i < array.length; i++) {
            entries.add(new Entry(i));

    public T getSorted(int i) {
        return tArray[entries.get(i).index];


    public T get(int i) {
        return tArray[i];

Below is a method based on Insertion Sort

public static int[] insertionSort(float[] arr){
    int[] indices = new int[arr.length];
        indices[0] = 0;
        for(int i=1;i<arr.length;i++){
            int j=i;
            for(;j>=1 && arr[j]<arr[j-1];j--){
                    float temp = arr[j];
                    arr[j] = arr[j-1];
                    arr[j-1] = temp;
        return indices;//indices of sorted elements

I'd like to use this because it is very fast.But I use it for int,you can change it to float.

private static void mergeSort(int[]array,int[] indexes,int start,int end){
    int middle = (end-start)/2+start;
private static void merge(int[]array,int[] indexes,int start,int middle,int end){
    int len1 = middle-start+1;
    int len2 = end - middle;
    int leftArray[] = new int[len1];
    int leftIndex[] = new int[len1];
    int rightArray[] = new int[len2];
    int rightIndex[] = new int[len2];
    for(int i=0;i<len1;++i)leftArray[i] = array[i+start];
    for(int i=0;i<len1;++i)leftIndex[i] = indexes[i+start];
    for(int i=0;i<len2;++i)rightArray[i] = array[i+middle+1];
    for(int i=0;i<len2;++i)rightIndex[i] = indexes[i+middle+1];
    int i=0,j=0,k=start;
            array[k] = leftArray[i];
            indexes[k] = leftIndex[i];
            array[k] = rightArray[j];
            indexes[k] = rightIndex[j];
        array[k] = leftArray[i];
        indexes[k] = leftIndex[i];
        array[k] = rightArray[j];
        indexes[k] = rightIndex[j];

I guess the easiest way to do it is to index the array as it is created. You would need key,value pairs. If the index is a separate structure, then i cant see how you could do it without other objects (interested in seeing it though)

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