I have an array like this:

var arr1 = ["a", "b", "c", "d"];

How can I randomize / shuffle it?

43 Answers 43

up vote 1159 down vote accepted

The de-facto unbiased shuffle algorithm is the Fisher-Yates (aka Knuth) Shuffle.

See https://github.com/coolaj86/knuth-shuffle

You can see a great visualization here (and the original post linked to this)

function shuffle(array) {
  var currentIndex = array.length, temporaryValue, randomIndex;

  // While there remain elements to shuffle...
  while (0 !== currentIndex) {

    // Pick a remaining element...
    randomIndex = Math.floor(Math.random() * currentIndex);
    currentIndex -= 1;

    // And swap it with the current element.
    temporaryValue = array[currentIndex];
    array[currentIndex] = array[randomIndex];
    array[randomIndex] = temporaryValue;

  return array;

// Used like so
var arr = [2, 11, 37, 42];
arr = shuffle(arr);

Some more info about the algorithm used.

  • 4
    Here's a CoffeeScript implementation of the Fisher-Yates algorithm: gist.github.com/859699 – Derek Dahmer Mar 8 '11 at 1:57
  • 12
    The above answer skips element 0, the condition should be i-- not --i. Also, the test if (i==0)... is superfluous since if i == 0 the while loop will never be entered. The call to Math.floor can be done faster using ...| 0. Either tempi or tempj can be removed and the value be directly assigned to myArray[i] or j as appropriate. – RobG Jun 8 '11 at 7:21
  • 21
    @prometheus, all RNGs are pseudo-random unless connected to expensive hardware. – Phil H Apr 13 '12 at 14:10
  • 33
    @RobG the implementation above is functionally correct. In the Fisher-Yates algorithm, the loop isn't meant to run for the first element in the array. Check out wikipedia where there are other implementations that also skip the first element. Also check out this article which talks about why it is important for the loop not to run for the first element. – theon Jul 20 '12 at 12:57
  • 24
    @nikola "not random at all" is a little strong a qualification for me. I would argue that it is sufficiently random unless you're a cryptographer, in which case you're probably not using Math.Random() in the first place. – toon81 Apr 24 '13 at 9:19

Here is a JavaScript implementation of the Durstenfeld shuffle, a computer-optimized version of Fisher-Yates:

 * Randomize array element order in-place.
 * Using Durstenfeld shuffle algorithm.
function shuffleArray(array) {
    for (var i = array.length - 1; i > 0; i--) {
        var j = Math.floor(Math.random() * (i + 1));
        var temp = array[i];
        array[i] = array[j];
        array[j] = temp;

The Fisher-Yates algorithm works by picking one random element for each original array element, and then excluding it from the next draw. Just like randomly picking from a deck of cards.

This exclusion is done in a clever way (invented by Durstenfeld for use by computers) by swapping the picked element with the current element, and then picking the next random element from the remainder. For optimal efficiency, the loop runs backwards so that the random pick is simplified (it can always start at 0), and it skips the last element because there are no other choices anymore.

The running time of this algorithm is O(n). Note that the shuffle is done in-place. So if you do not want to modify the original array, make a copy of it first with .slice(0).

Updating to ES6 / ECMAScript 2015

The new ES6 allows us to assign two variables at once. This is especially handy when we want to swap the values of two variables, as we can do it in one line of code. Here is a shorter form of the same function, using this feature.

function shuffleArray(array) {
    for (let i = array.length - 1; i > 0; i--) {
        const j = Math.floor(Math.random() * (i + 1));
        [array[i], array[j]] = [array[j], array[i]];
  • 16
    p.s. The same algorithm as ChristopheD’s answer, but with explanation and cleaner implementation. – Laurens Holst Sep 28 '12 at 20:47
  • 10
    People are attributing the wrong person for the algorithm. It's not Fisher-Yates shuffle but Durstenfeld shuffle. The true original Fisher-Yates algorithm is runs in n^2 time, not n time – Pacerier Oct 31 '14 at 12:32
  • 6
    It is not required to return array since JavaScript passes arrays by reference when used as function arguments. I assume this is to save on stack space, but it's an interesting little feature. Performing the shuffle on the array will shuffle the original array. – Joel Trauger Aug 9 '16 at 13:31
  • 5
    The implementation in this answer favors the lower end of the array. Found out the hard way. Math.random() should not be multiplied with the loop counter + 1, but with array.lengt()`. See Generating random whole numbers in JavaScript in a specific range? for a very comprehensive explanation. – Marjan Venema Dec 18 '16 at 20:17
  • 9
    @MarjanVenema Not sure if you're still watching this space, but this answer is correct, and the change you're suggesting actually introduces bias. See blog.codinghorror.com/the-danger-of-naivete for a nice writeup of this mistake. – smarx Mar 11 '17 at 1:44

[community edit: This answer is incorrect; see comments. It is being left here for future reference because the idea is not that rare.]

[1,2,3,4,5,6].sort(function() {
  return .5 - Math.random();
  • 12
    i like this solution, enough to give a basic random – Alex K Oct 28 '13 at 9:49
  • 115
    Downvoting as this isn't really that random. I don't know why it has so many upvotes. Do not use this method. It looks pretty, but isn't completely correct. Here are results after 10,000 iterations on how many times each number in your array hits index [0] (I can give the other results too): 1 = 29.19%, 2 = 29.53%, 3 = 20.06%, 4 = 11.91%, 5 = 5.99%, 6 = 3.32% – radtad Nov 13 '13 at 18:35
  • 16
    It's also the least efficient of all the methods available. – Blazemonger Dec 17 '13 at 14:21
  • 184
    but it's very cute – spencercooly Apr 27 '14 at 22:26
  • 10
    The problem is that it's not deterministic, which will give wrong results (if 1 > 2 and 2 > 3, it should be given that 1 > 3, but this will not guarantee that. This will confuse the sort, and give the result commented by @radtad). – MatsLindh Sep 10 '14 at 14:07

One could (or should) use it as a protoype from Array:

From ChristopheD:

Array.prototype.shuffle = function() {
  var i = this.length, j, temp;
  if ( i == 0 ) return this;
  while ( --i ) {
     j = Math.floor( Math.random() * ( i + 1 ) );
     temp = this[i];
     this[i] = this[j];
     this[j] = temp;
  return this;
  • 16
    +1 for using prototype... – user1589754 Sep 22 '13 at 14:22
  • 32
    Really no benefit to this, IMOHO, except possibly stomping on someone else's implementation .. – user2864740 Sep 15 '14 at 4:17
  • 38
    One could (or should) avoid extending Native Prototypes: javascriptweblog.wordpress.com/2011/12/05/… – Wédney Yuri Aug 25 '15 at 23:03
  • 7
    You shouldn't do this; every single array affected by this can no longer be iterated safely using for...in. Don't extend native prototypes. – Tiny Giant Oct 18 '15 at 21:13
  • 12
    @TinyGiant Actually: don't use for...in loops to iterate over arrays. – Conor O'Brien Nov 7 '15 at 3:27

Use the underscore.js library. The method _.shuffle() is nice for this case. Here is an example with the method:

var _ = require("underscore");

var arr = [1,2,3,4,5,6];
// Testing _.shuffle
var testShuffle = function () {
  var indexOne = 0;
    var stObj = {
      '0': 0,
      '1': 1,
      '2': 2,
      '3': 3,
      '4': 4,
      '5': 5
    for (var i = 0; i < 1000; i++) {
      arr = _.shuffle(arr);
      indexOne = _.indexOf(arr, 1);
      stObj[indexOne] ++;
  • 9
    Great answer! Thanks. I prefer it to the other answers, as it encourages people to use libraries rather than copy and paste potentially buggy functions everywhere. – frabcus Apr 4 '13 at 15:07
  • 44
    @frabcus: There's no point in including an entire library just to get a shuffle function. – Blender Jun 8 '13 at 20:42
  • 8
    I disagree with @Blender. There are many reasons to include an entire library just to get a function you need. One of them is there is less risk of a bug when you write it yourself. If it's a performance problem, then you shouldn't use it. But just because it could be a performance problem doesn't mean it will be. – Daniel Kaplan Jul 16 '13 at 23:04
  • 7
    @tieTYT: So why do you need the rest of the library? The Fisher-Yates shuffle is trivial to implement. You don't need a library to pick a random element out of an array (I hope), so there's no reason to use a library unless you're actually going to use more than one function from it. – Blender Jul 16 '13 at 23:19
  • 14
    @Blender: I gave a reason why. 1) I assure you, you can introduce a bug into any code you write, no matter how trivial it is. Why risk it? 2) Don't pre-optimize. 3) 99% of the time when you need a shuffle algo, your app isn't about writing a shuffle algo. It's about something that needs a shuffle algo. Leverage others' work. Don't think about implementation details unless you have to. – Daniel Kaplan Jul 17 '13 at 17:35


Shorter & probably *faster Fisher-Yates shuffle algorithm

  1. it uses while---
  2. bitwise to floor (numbers up to 10 decimal digits (32bit))
  3. removed unecessary closures & other stuff

function fy(a,b,c,d){//array,placeholder,placeholder,placeholder

script size (with fy as function name): 90bytes

DEMO http://jsfiddle.net/vvpoma8w/

*faster probably on all browsers except chrome.

If you have any questions just ask.


yes it is faster

PERFORMANCE: http://jsperf.com/fyshuffle

using the top voted functions.

EDIT There was a calculation in excess (don't need --c+1) and noone noticed

shorter(4bytes)&faster(test it!).

function fy(a,b,c,d){//array,placeholder,placeholder,placeholder

Caching somewhere else var rnd=Math.random and then use rnd() would also increase slightly the performance on big arrays.


Readable version (use the original version. this is slower, vars are useless, like the closures & ";", the code itself is also shorter ... maybe read this How to 'minify' Javascript code , btw you are not able to compress the following code in a javascript minifiers like the above one.)

function fisherYates( array ){
 var count = array.length,
 while( count ){
  randomnumber = Math.random() * count-- | 0;
  temp = array[count];
  array[count] = array[randomnumber];
  array[randomnumber] = temp
  • 6
    check out the performance ... 2x faster on most browsers... but needs more jsperf testers... – cocco Sep 23 '14 at 11:20
  • 12
    Yes, fine, but that's not the reason to make it unreadable. – georg Sep 23 '14 at 11:23
  • 10
    js is a language that accepts many shortcuts and different ways to write it.. while there are many slow readable functions in here i just like to show how it could be done in a more performant way, also saving some bytes... bitwise and shorthand is really underestimated here and the web is full of buggy and slow code. – cocco Sep 23 '14 at 11:29
  • 2
    And minifiers don't work properly....stackoverflow.com/a/21353032/2450730 – cocco Sep 23 '14 at 11:33
  • Not a slam dunk perf increase. Swapping the fy and shuffle prototype, I get fy consistently at the bottom in Chrome 37 on OS X 10.9.5 (81% slower ~20k ops compared to ~100k) and Safari 7.1 it's up to ~8% slower. YMMV, but it's not always faster. jsperf.com/fyshuffle/3 – Spig Oct 9 '14 at 18:49

You can do it easily with map and sort:

let unshuffled = ['hello', 'a', 't', 'q', 1, 2, 3, {cats: true}]

let shuffled = unshuffled
  .map((a) => ({sort: Math.random(), value: a}))
  .sort((a, b) => a.sort - b.sort)
  .map((a) => a.value)
  1. We put each element in the array in an object, and give it a random sort key
  2. We sort using the random key
  3. We unmap to get the original objects

You can shuffle polymorphic arrays, and the sort is as random as Math.random, which is good enough for most purposes.

Since the elements are sorted against consistent keys that are not regenerated each iteration, and each comparison pulls from the same distribution, any non-randomness in the distribution of Math.random is canceled out.

  • 2
    This is short and sweet. – Rexford Dec 6 '17 at 8:31
  • 1
    @superluminary Oops, you're right. Notice that this answer already used the same approach. – Bergi Dec 6 '17 at 19:42
  • @Bergi - Ah yes, you are right, although I think my implementation is slightly prettier. – superluminary Dec 7 '17 at 11:24
  • 1
    Very nice. This is the Schwartzian transform in js. – Mark Grimes Jun 29 at 10:43
  • But performance is worse than FY. – user9315861 Jul 8 at 7:25

A very simple way for small arrays is simply this:

const someArray = [1, 2, 3, 4, 5];

someArray.sort(() => Math.random() - 0.5);

It's probably not very efficient, but for small arrays this works just fine. Here's an example so you can see how random (or not) it is, and whether it fits your usecase or not.

const resultsEl = document.querySelector('#results');
const buttonEl = document.querySelector('#trigger');

const generateArrayAndRandomize = () => {
  const someArray = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9];
  someArray.sort(() => Math.random() - 0.5);
  return someArray;

const renderResultsToDom = (results, el) => {
  el.innerHTML = results.join(' ');

buttonEl.addEventListener('click', () => renderResultsToDom(generateArrayAndRandomize(), resultsEl));
<button id="trigger">Generate</button>
<p id="results">0 1 2 3 4 5 6 7 8 9</p>

  • Nice one, but does generate a complete random elements every time? – Azarus Apr 10 '17 at 20:00
  • Not quite sure if I understood you correctly. This approach will indeed shuffle the array in a random way (albeit pseudo-random) every time you call the sort array - it's not a stable sort, for obvious reasons. – Kris Selbekk Apr 11 '17 at 11:00
  • 3
    For the same reasons as explained at stackoverflow.com/a/18650169/28234 . This is much more likely to leave early elements near the start of the array. – AlexC Jun 23 '17 at 10:41
  • 3
    This is a great, easy one-liner for when you need to scramble an array, but don't care too much about having the results be academically provably random. Sometimes, that last few inches to perfection take more time than it's worth. – Daniel Griscom Nov 3 '17 at 18:48
  • 1
    It would be lovely if this worked, but it doesn't. Because of the way quick-search works, an inconsistent comparator will be likely to leave array elements close to their original position. Your array will not be scrambled. – superluminary Mar 14 at 14:34

Adding to @Laurens Holsts answer. This is 50% compressed.

function shuffleArray(d) {
  for (var c = d.length - 1; c > 0; c--) {
    var b = Math.floor(Math.random() * (c + 1));
    var a = d[c];
    d[c] = d[b];
    d[b] = a;
  return d
  • 2
    We should be encouraging people to use _.shuffle rather than pasting code from stack overflow; and, we should be discouraging people from compressing their stack overflow answers. That's what jsmin is for. – David Jones Apr 5 '13 at 8:28
  • 37
    @DavidJones: Why would I include an entire 4kb library just to shuffle an array? – Blender May 4 '13 at 19:23
  • 1
    @KingKongFrog name calling is also not conductive to a assemblage of a reasonable community. – wheaties May 8 '13 at 3:21
  • 2
    is it efficient to do var b = in a loop instead of declaring b outside loop and assigning it with b = in a loop? – Alex K Oct 28 '13 at 9:51
  • 2
    @Brian Won't make a difference; the hoisting happens when the source code is parsed. No probably involved. – user2864740 Sep 15 '14 at 4:18

With ES2015 you can use this one:

Array.prototype.shuffle = function() {
  let m = this.length, i;
  while (m) {
    i = (Math.random() * m--) >>> 0;
    [this[m], this[i]] = [this[i], this[m]]
  return this;


[1, 2, 3, 4, 5, 6, 7].shuffle();
  • 4
    To truncate, you should use n >>> 0 instead of ~~n. Array indices can be higher than 2³¹-1. – Oriol Jul 24 '16 at 3:46
  • 1
    Destructuring like this makes for such a clean implementation +1 – lukejacksonn May 11 '17 at 12:28
var shuffle = function(array) {
   temp = [];
   for (var i = 0; i < array.length ; i++) {
   return temp;
  • This is obviously not as optimal as the Fisher-Yates algorithm, but would it work for technical interviews? – davidatthepark May 19 '16 at 22:17
  • 1
    Am I wrong or this is completely broken? – Andrea Feb 15 at 17:15

I found this variant hanging out in the "deleted by author" answers on a duplicate of this question. Unlike some of the other answers that have many upvotes already, this is:

  1. Actually random
  2. Not in-place (hence the shuffled name rather than shuffle)
  3. Not already present here with multiple variants

Here's a jsfiddle showing it in use.

Array.prototype.shuffled = function() {
  return this.map(function(n){ return [Math.random(), n] })
             .sort().map(function(n){ return n[1] });
  • (I suspect it was deleted as it is a very inefficient way to randomize the array, especially for larger arrays... whereas the accepted answer, and a number of other clones of that answer randomize in-place). – WiredPrairie Jul 14 '15 at 12:17
  • 1
    Yeah, but given that the well-known wrong answer is still up with a bunch of votes, an inefficient but correct solution should at least be mentioned. – Daniel Martin Jul 14 '15 at 18:54
  • Which one is the "well-known wrong answer"? – WiredPrairie Jul 14 '15 at 22:49
  • [1,2,3,4,5,6].sort(function() { return .5 - Math.random(); }); - it doesn't give a random sort, and if you use it you can end up embarrassed: robweir.com/blog/2010/02/microsoft-random-browser-ballot.html – Daniel Martin Jul 14 '15 at 22:58
  • 2
    You need to use .sort(function(a,b){ return a[0] - b[0]; }) if you want the sort to compare values numerically. The default .sort() comparator is lexicographic, meaning it will consider 10 to be less than 2 since 1 is less than 2. – 4castle Nov 10 '17 at 14:39

With ES6, 2018

Some of the answers could be shortened with the latest ES6.

Shuffle Array In place

function shuffleArray (array){
    for (let i = array.length - 1; i > 0; i--) {
        const rand = Math.floor(Math.random() * (i + 1));
        [array[i], array[rand]] = [array[rand], array[i]];

With ES6 we can assign two values at once. This is especially handy in line 4 above, where two variables are swapped in one line of code.

Leave original Array intact and return a shuffled array

If you want to make a more pure function, and leave the original array intact, you can simply duplicate the array and then run the same algorithm.

function getShuffledArray (arr){
    let newArr = [...arr]
    for (let i = newArr.length - 1; i > 0; i--) {
        const rand = Math.floor(Math.random() * (i + 1));
        [newArr[i], newArr[rand]]=[newArr[rand], newArr[i]];
    return newArr;

An ascending Algorithm

The algorithm below uses an ascending loop. It is less intuitive, yet short and valid.

function getShuffledArrayAsc (arr){
    let newArr = [...arr];
    for (let i = 1; i < newArr.length ; i++) {
        const rand = Math.floor( Math.random() * (i + 1) ); 
        [newArr[i], newArr[rand]] = [newArr[rand], newArr[i]];
    return newArr;

Testing Reliability of the Randomising function

The functions above presented even distribution when passed to the 'testShuffledArrayFun' below, both in Chrome, and in Node. This is in accordance with what we would expect from a randomizing function.

function testShuffledArrayFun(getShuffledArrayFun){
    // Tests the reliability of the suffleArrayFunction, by callying it 1,000 times and presenting the distribution. 
    const testArr = [0,1,2,3,4];
    const countArr = testArr.map( position => // for for each possible position in the shuffledArr, for each possible value, we'll create a counter. the counter of value 0 in position 0 will be countArr[0][0]
        testArr.map( value => 0)  

    const n = 10000;
    for (var i=0 ; i<n ; i++){
        // We'll call getShuffledArrayFun for n times. For each shuffledArray we receive we'll increment the counterArr accordingly. At the end we'll print the distribution.
        var shuffledArr = getShuffledArrayFun(testArr);
            (value, key) => {countArr[key][value]++}

        (valueCountArr,key) => {
            console.log(`Position ${key}:`);
                (count,originalValue) => {
                    console.log(`The Value ${originalValue} appeared ${count*100/n}% `);
  • So, where is the ES6(ES2015) ? [array[i], array[rand]]=[array[rand], array[i]] ? Maybe you can outline how that works. Why do you choose to iterate downwards? – sheriffderek Sep 11 '17 at 19:00
  • @sheriffderek Yes, the ES6 feature I'm using is the assignment of two vars at once, which allows us to swap two vars in one line of code. – Ben Sep 12 '17 at 2:47
  • Credit to @sheriffderek who suggested the ascending Algorithm. The ascending algorithm could be proved in induction. – Ben Sep 15 '17 at 1:00

A recursive solution:

function shuffle(a,b){
    return a.length==0?b:function(c){
        return shuffle(a,(b||[]).concat(c));

Fisher-Yates shuffle in javascript. I'm posting this here because the use of two utility functions (swap and randInt) clarifies the algorithm compared to the other answers here.

function swap(arr, i, j) { 
  // swaps two elements of an array in place
  var temp = arr[i];
  arr[i] = arr[j];
  arr[j] = temp;
function randInt(max) { 
  // returns random integer between 0 and max-1 inclusive.
  return Math.floor(Math.random()*max);
function shuffle(arr) {
  // For each slot in the array (starting at the end), 
  // pick an element randomly from the unplaced elements and
  // place it in the slot, exchanging places with the 
  // element in the slot. 
  for(var slot = arr.length - 1; slot > 0; slot--){
    var element = randInt(slot+1);
    swap(arr, element, slot);

First of all, have a look here for a great visual comparison of different sorting methods in javascript.

Secondly, if you have a quick look at the link above you'll find that the random order sort seems to perform relatively well compared to the other methods, while being extremely easy and fast to implement as shown below:

function shuffle(array) {
  var random = array.map(Math.random);
  array.sort(function(a, b) {
    return random[array.indexOf(a)] - random[array.indexOf(b)];

Edit: as pointed out by @gregers, the compare function is called with values rather than indices, which is why you need to use indexOf. Note that this change makes the code less suitable for larger arrays as indexOf runs in O(n) time.

  • Array.prototype.sort passes in two values as a and b, not the index. So this code doesn't work. – gregers Mar 29 '16 at 13:34
  • @gregers you're right, I've edited the answer. Thanks. – 0sh May 15 '16 at 15:00
  • 1
    This is not very random. Depending on the implementation of sort, an element at the lowest array index might require more comparisons in order to get to the highest index than the element next to the highest index. This means that it is less likely for the element at the lowest index to get to the highest index. – 1' OR 1 -- Jul 19 '16 at 0:16

You can do it easily with:

// array
var fruits = ["Banana", "Orange", "Apple", "Mango"];
// random
fruits.sort(function(a, b){return 0.5 - Math.random()});
// out

Please reference at JavaScript Sorting Arrays

a shuffle function that doesn't change the source array

Update: Here I'm suggesting a relatively simple (not from complexity perspective) and short algorithm that will do just fine with small sized arrays, but it's definitely going to cost a lot more than the classic Durstenfeld algorithm when you deal with huge arrays. You can find the Durstenfeld in one of the top replies to this question.

Original answer:

If you don't wish your shuffle function to mutate the source array, you can copy it to a local variable, then do the rest with a simple shuffling logic.

function shuffle(array) {
  var result = [], source = array.concat([]);

  while (source.length) {
    let index = Math.floor(Math.random() * source.length);
    source.splice(index, 1);

  return result;

Shuffling logic: pick up a random index, then add the corresponding element to the result array and delete it from the source array copy. Repeat this action until the source array gets empty.

And if you really want it short, here's how far I could get:

function shuffle(array) {
  var result = [], source = array.concat([]);

  while (source.length) {
    let index = Math.floor(Math.random() * source.length);
    result.push(source.splice(index, 1)[0]);

  return result;
  • This is essentially the original Fisher-Yates algorithm, with your splice being a horribly inefficient way to do what they called "striking out". If you don't want to mutate the original array, then just copy it, and then shuffle that copy in place using the much more efficient Durstenfeld variant. – user9315861 Jul 9 at 4:49
  • @torazaburo, thank you for your feedback. I've updated my answer, to make it clear that I'm rather offering a nice-looking solution, than a super-scaling one – Evgenia Manolova Jul 20 at 11:10

yet another implementation of Fisher-Yates, using strict mode:

function shuffleArray(a) {
    "use strict";
    var i, t, j;
    for (i = a.length - 1; i > 0; i -= 1) {
        t = a[i];
        j = Math.floor(Math.random() * (i + 1));
        a[i] = a[j];
        a[j] = t;
    return a;
  • What value does the addition of use strict provide over the accepted answer? – shortstuffsushi Sep 17 '17 at 15:21
  • To learn more about strict mode and how it influences performance you can read about it here: developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/… – Raphael C Sep 18 '17 at 17:55
  • Hmm, could you point to something specific from the referenced document? Nothing in there seems to reference "improving performance," aside from a vague comment at the top about potentially making it difficult for the js engine to optimize. In this case, it's unclear to me what use strict would improve. – shortstuffsushi Sep 19 '17 at 15:04
  • Strict mode has been around for quite some time, and there are sufficient reads out there for anyone to make their own opinion if they should always use it or not and why. Jslint for instance makes it clear enough that you should always use strict mode. Douglas Crockford has written quite an amount of articles and some great videos on why it is important to always use strict mode not only as a good practice but also how it is interpreted differently by browser js engines such as V8. I strongly advise you to Google it and make your own opinion about it. – Raphael C Sep 20 '17 at 15:53
  • Here is an old thread about perfs in strict mode, a bit old but still relevant: stackoverflow.com/questions/3145966/… – Raphael C Sep 20 '17 at 16:06

All the other answers are based on Math.random() which is fast but not suitable for cryptgraphic level randomization.

The below code is using the well known Fisher-Yates algorithm while utilizing Web Cryptography API for cryptographic level of randomization.

var d = [1,2,3,4,5,6,7,8,9,10];

function shuffle(a) {
	var x, t, r = new Uint32Array(1);
	for (var i = 0, c = a.length - 1, m = a.length; i < c; i++, m--) {
		x = Math.floor(r / 65536 / 65536 * m) + i;
		t = a [i], a [i] = a [x], a [x] = t;

	return a;


Just to have a finger in the pie. Here i present a recursive implementation of Fisher Yates shuffle (i think). It gives uniform randomness.

Note: The ~~ (double tilde operator) is in fact behaves like Math.floor() for positive real numbers. Just a short cut it is.

var shuffle = a => a.length ? a.splice(~~(Math.random()*a.length),1).concat(shuffle(a))
                            : a;


Though there are a number of implementations already advised but I feel we can make it shorter and easier using forEach loop, so we don't need to worry about calculating array length and also we can safely avoid using a temporary variable.

var arr1 = ["a", "b", "c", "d"];

arr1.forEach((val, key) => {
  randomIndex = Math.ceil(Math.random()*(key + 1));
  arr1[key] = arr1[randomIndex];
  arr1[randomIndex] = val;

A simple modification of CoolAJ86's answer that does not modify the original array:

 * Returns a new array whose contents are a shuffled copy of the original array.
 * @param {Array} The items to shuffle.
 * https://stackoverflow.com/a/2450976/1673761
 * https://stackoverflow.com/a/44071316/1673761
const shuffle = (array) => {
  let currentIndex = array.length;
  let temporaryValue;
  let randomIndex;
  const newArray = array.slice();
  // While there remains elements to shuffle...
  while (currentIndex) {
    randomIndex = Math.floor(Math.random() * currentIndex);
    currentIndex -= 1;
    // Swap it with the current element.
    temporaryValue = newArray[currentIndex];
    newArray[currentIndex] = newArray[randomIndex];
    newArray[randomIndex] = temporaryValue;
  return newArray;

the shortest arrayShuffle function

function arrayShuffle(o) {
    for(var j, x, i = o.length; i; j = parseInt(Math.random() * i), x = o[--i], o[i] = o[j], o[j] = x);
    return o;

From a theoretical point of view, the most elegant way of doing it, in my humble opinion, is to get a single random number between 0 and n!-1 and to compute a one to one mapping from {0, 1, …, n!-1} to all permutations of (0, 1, 2, …, n-1). As long as you can use a (pseudo-)random generator reliable enough for getting such a number without any significant bias, you have enough information in it for achieving what you want without needing several other random numbers.

When computing with IEEE754 double precision floating numbers, you can expect your random generator to provide about 15 decimals. Since you have 15!=1,307,674,368,000 (with 13 digits), you can use the following functions with arrays containing up to 15 elements and assume there will be no significant bias with arrays containing up to 14 elements. If you work on a fixed-size problem requiring to compute many times this shuffle operation, you may want to try the following code which may be faster than other codes since it uses Math.random only once (it involves several copy operations however).

The following function will not be used, but I give it anyway; it returns the index of a given permutation of (0, 1, 2, …, n-1) according to the one to one mapping used in this message (the most natural one when enumerating permuations); it is intended to work with up to 16 elements:

function permIndex(p) {
    var fact = [1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800, 39916800, 479001600, 6227020800, 87178291200, 1307674368000];
    var tail = [];
    var i;
    if (p.length == 0) return 0;
    for(i=1;i<(p.length);i++) {
        if (p[i] > p[0]) tail.push(p[i]-1);
        else tail.push(p[i]);
    return p[0] * fact[p.length-1] + permIndex(tail);

The reciprocal of the previous function (required for your own question) is below; it is intended to work with up to 16 elements; it returns the permutation of order n of (0, 1, 2, …, s-1):

function permNth(n, s) {
    var fact = [1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800, 39916800, 479001600, 6227020800, 87178291200, 1307674368000];
    var i, j;
    var p = [];
    var q = [];
    for(i=0;i<s;i++) p.push(i);
    for(i=s-1; i>=0; i--) {
        j = Math.floor(n / fact[i]);
        n -= j*fact[i];
        for(;j<i;j++) p[j]=p[j+1];
    return q;

Now, what you want merely is:

function shuffle(p) {
    var fact = [1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800, 39916800, 479001600, 6227020800, 87178291200, 1307674368000, 20922789888000];
    return permNth(Math.floor(Math.random()*fact[p.length]), p.length).map(
            function(i) { return p[i]; });

It should work for up to 16 elements with a little theoretical bias (though unnoticeable from a practical point of view); it can be seen as fully usable for 15 elements; with arrays containing less than 14 elements, you can safely consider there will be absolutely no bias.

Funny enough there was no non mutating recursive answer:

var shuffle = arr => {
  const recur = (arr,currentIndex)=>{
      return arr;
    const randomIndex = Math.floor(Math.random() * currentIndex);
    const swap = arr[currentIndex];
    arr[currentIndex] = arr[randomIndex];
    arr[randomIndex] = swap;
    return recur(
      currentIndex - 1
  return recur(arr.map(x=>x),arr.length-1);

var arr = [1,2,3,4,5,[6]];

  • 2
    Maybe there wasn't because it's pretty inefficient? :-P – Bergi Feb 9 at 4:08
  • @Bergi Correct, updated with first answer logic. Still need to copy the array for immutability. Added because this is flagged as the duplicate of a question asking for a function that takes an array and returned a shuffled array without mutating the array. Now the question actually has an answer the OP was looking for. – HMR Feb 9 at 6:48

Modern short inline solution using ES6 features:

['a','b','c','d'].map(x => [Math.random(), x]).sort(([a], [b]) => a - b).map(([_, x]) => x);

(for educational purposes)

   var len = this.length,temp,i
    i=Math.random()*len-- |0;
   return this;
  • To truncate, you should use n >>> 0 instead of n | 0. Array indices can be higher than 2³¹-1. – Oriol Aug 11 '16 at 21:39

Randomize array using array.splice()

function shuffleArray(array) {
   var temp = [];
   var len=array.length;
   return temp;
//console.log("Here >>> "+shuffleArray([4,2,3,5,8,1,0]));


  • 1
    Essentially the same as Tophe posted more than a year before. – trincot Jul 20 '16 at 21:08

Randomize array

 var arr = ['apple','cat','Adam','123','Zorro','petunia']; 
 var n = arr.length; var tempArr = [];

 for ( var i = 0; i < n-1; i++ ) {

    // The following line removes one random element from arr 
     // and pushes it onto tempArr 

 // Push the remaining item onto tempArr 
  • There shouldn't be a -1 for n as you used < not <= – Mohebifar May 9 '15 at 9:04

protected by Community Oct 30 '14 at 6:12

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