2069

I have an array like this:

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

How can I randomize / shuffle it?

1

58 Answers 58

1
2
2

function shuffleArray(array) {
        // Create a new array with the length of the given array in the parameters
        const newArray = array.map(() => null);

        // Create a new array where each index contain the index value
        const arrayReference = array.map((item, index) => index);

        // Iterate on the array given in the parameters
        array.forEach(randomize);
        
        return newArray;

        function randomize(item) {
            const randomIndex = getRandomIndex();

            // Replace the value in the new array
            newArray[arrayReference[randomIndex]] = item;
            
            // Remove in the array reference the index used
            arrayReference.splice(randomIndex,1);
        }

        // Return a number between 0 and current array reference length
        function getRandomIndex() {
            const min = 0;
            const max = arrayReference.length;
            return Math.floor(Math.random() * (max - min)) + min;
        }
    }
    
console.log(shuffleArray([10,20,30,40,50,60,70,80,90,100]));

1
  • This solution has no redeeming qualities, being both slow and complicated.
    – Ry-
    Mar 26 at 6:40
2

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];
        q.push(p[j]);
        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.

1
  • Definitely elegant! Jan 24, 2018 at 17:34
2

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;

console.log(JSON.stringify(shuffle([0,1,2,3,4,5,6,7,8,9])));

Edit: The above code is O(n^2) due to the employment of .splice() but we can eliminate splice and shuffle in O(n) by the swap trick.

var shuffle = (a, l = a.length, r = ~~(Math.random()*l)) => l ? ([a[r],a[l-1]] = [a[l-1],a[r]], shuffle(a, l-1))
                                                              : a;

var arr = Array.from({length:3000}, (_,i) => i);
console.time("shuffle");
shuffle(arr);
console.timeEnd("shuffle");

The problem is, JS can not coop on with big recursions. In this particular case you array size is limited with like 3000~7000 depending on your browser engine and some unknown facts.

2

For completeness, in addition to the Durstenfeld variation of Fischer-Yates, I'd also point out Sattolo's algorithm which is just one tiny change away and results in every element changing place.

function sattoloCycle(arr) {
   for (let i = arr.length - 1; 0 < i; i--) {
      const j = Math.floor(Math.random() * i);
      [arr[i], arr[j]] = [arr[j], arr[i]];
   }
   return arr
}

The difference is in how random index j is computed, with Math.random() * i versus Math.random() * (i + 1).

1

This variation of Fisher-Yates is slightly more efficient because it avoids swapping an element with itself:

function shuffle(array) {
  var elementsRemaining = array.length, temp, randomIndex;
  while (elementsRemaining > 1) {
    randomIndex = Math.floor(Math.random() * elementsRemaining--);
    if (randomIndex != elementsRemaining) {
      temp = array[elementsRemaining];
      array[elementsRemaining] = array[randomIndex];
      array[randomIndex] = temp;
    }
  }
  return array;
}
1
var shuffledArray = function(inpArr){
    //inpArr - is input array
    var arrRand = []; //this will give shuffled array
    var arrTempInd = []; // to store shuffled indexes
    var max = inpArr.length;
    var min = 0;
    var tempInd;
    var i = 0;

    do{
        //generate random index between range
        tempInd = Math.floor(Math.random() * (max - min));
        //check if index is already available in array to avoid repetition
        if(arrTempInd.indexOf(tempInd)<0){
            //push character at random index
            arrRand[i] = inpArr[tempInd];
            //push random indexes
            arrTempInd.push(tempInd);
            i++;
        }
    }
    // check if random array length is equal to input array length
    while(arrTempInd.length < max){
        return arrRand; // this will return shuffled Array
    }
};

Just pass the array to function and in return get the shuffled array

1

Considering apply it to in loco or to a new immutable array, following other solutions, here is a suggested implementation:

Array.prototype.shuffle = function(local){
  var a = this;
  var newArray = typeof local === "boolean" && local ? this : [];
  for (var i = 0, newIdx, curr, next; i < a.length; i++){
    newIdx = Math.floor(Math.random()*i);
    curr = a[i];
    next = a[newIdx];
    newArray[i] = next;
    newArray[newIdx] = curr;
  }
  return newArray;
};
1

I see no one has yet given a solution that can be concatenated while not extending the Array prototype (which is a bad practice). Using the slightly lesser known reduce() we can easily do shuffling in a way that allows for concatenation:

var randomsquares = [1, 2, 3, 4, 5, 6, 7].reduce(shuffle).map(n => n*n);

You'd probably want to pass the second parameter [], as otherwise if you try to do this on an empty array it'd fail:

// Both work. The second one wouldn't have worked as the one above
var randomsquares = [1, 2, 3, 4, 5, 6, 7].reduce(shuffle, []).map(n => n*n);
var randomsquares = [].reduce(shuffle, []).map(n => n*n);

Let's define shuffle as:

var shuffle = (rand, one, i, orig) => {
  if (i !== 1) return rand;  // Randomize it only once (arr.length > 1)

  // You could use here other random algorithm if you wanted
  for (let i = orig.length; i; i--) {
    let j = Math.floor(Math.random() * i);
    [orig[i - 1], orig[j]] = [orig[j], orig[i - 1]];
  }

  return orig;
}

You can see it in action in JSFiddle or here:

var shuffle = (all, one, i, orig) => {
    if (i !== 1) return all;

    // You could use here other random algorithm here
    for (let i = orig.length; i; i--) {
        let j = Math.floor(Math.random() * i);
        [orig[i - 1], orig[j]] = [orig[j], orig[i - 1]];
    }

    return orig;
}

for (var i = 0; i < 5; i++) {
  var randomarray = [1, 2, 3, 4, 5, 6, 7].reduce(shuffle, []);
  console.log(JSON.stringify(randomarray));
}

1
  • It seems that you're exchanging for too much times. With reduce you can totally perform a streaming "inside-out" Fisher-Yates that uses (acc, el) => { acc.push(el); let i = Math.floor(Math.random() * (acc.length)); [acc[i], acc[acc.length - 1]] = [acc[acc.length - 1], acc[i]]; return acc; } as the callback. (Adapted from public domain code on zhihu.) Dec 14, 2016 at 4:39
1

I was thinking about oneliner to paste in console. All tricks with .sort was giving wrong results, here is my implementation:

 ['Bob', 'Amy', 'Joy'].map((person) => `${Math.random().toFixed(10)}${person}`).sort().map((person) => person.substr(12));

But don't use it in production code, it's not optimal and works with strings only.

1
  • 1
    It works with any kind of variable: array.map(e => [Math.random(), e]).sort((a, b) => a[0] - b[0]).map(e => e[1]) (but is not optimal). Aug 15, 2017 at 19:43
1
// Create a places array which holds the index for each item in the
// passed in array.
// 
// Then return a new array by randomly selecting items from the
// passed in array by referencing the places array item. Removing that
// places item each time though.
function shuffle(array) {
    let places = array.map((item, index) => index);
    return array.map((item, index, array) => {
      const random_index = Math.floor(Math.random() * places.length);
      const places_value = places[random_index];
      places.splice(random_index, 1);
      return array[places_value];
    })
}
1

By using shuffle-array module you can shuffle your array . Here is a simple code of it .

var shuffle = require('shuffle-array'),
 //collection = [1,2,3,4,5];
collection = ["a","b","c","d","e"];
shuffle(collection);

console.log(collection);

Hope this helps.

1

d3.js provides a built-in version of the Fisher–Yates shuffle:

console.log(d3.shuffle(["a", "b", "c", "d"]));
<script src="http://d3js.org/d3.v5.min.js"></script>

d3.shuffle(array[, lo[, hi]]) <>

Randomizes the order of the specified array using the Fisher–Yates shuffle.

1

Edit: Don't use this. The result will always make the elements from the beginning closer to the middle. Who knows, maybe there's a use for this algorithm but not for completely random sorting.

Randomly either push or unshift(add in the beginning).

['a', 'b', 'c', 'd'].reduce((acc, el) => {
  Math.random() > 0.5 ? acc.push(el) : acc.unshift(el);
  return acc;
}, []);
0

I have written a shuffle function on my own . The difference here is it will never repeat a value (checks in the code for this) :-

function shuffleArray(array) {
 var newArray = [];
 for (var i = 0; i < array.length; i++) {
     newArray.push(-1);
 }

 for (var j = 0; j < array.length; j++) {
    var id = Math.floor((Math.random() * array.length));
    while (newArray[id] !== -1) {
        id = Math.floor((Math.random() * array.length));
    }

    newArray.splice(id, 1, array[j]);
 }
 return newArray; }
0

Rebuilding the entire array, one by one putting each element at a random place.

[1,2,3].reduce((a,x,i)=>{a.splice(Math.floor(Math.random()*(i+1)),0,x);return a},[])

var ia= [1,2,3];
var it= 1000;
var f = (a,x,i)=>{a.splice(Math.floor(Math.random()*(i+1)),0,x);return a};
var a = new Array(it).fill(ia).map(x=>x.reduce(f,[]));
var r = new Array(ia.length).fill(0).map((x,i)=>a.reduce((i2,x2)=>x2[i]+i2,0)/it)

console.log("These values should be quite equal:",r);

5
  • 3
    You should explain what your code is doing, some people may not understand 1 liners of this complexity.
    – ricks
    May 9, 2019 at 18:57
  • also note that due to the use of Math.round(... * i) this is biased, you want to be doing Math.floor(.. * (i+1)) instead
    – Sam Mason
    May 10, 2019 at 8:27
  • @SamMason Probablity of getting .5 is 1:1000000000000000000 May 10, 2019 at 19:15
  • 1
    if you use round, the probability of selecting first and last index (i.e. 0 and n) are 0.5/n, the probability of selecting any other element is 1/n (where n = a.length). this is pretty bad for short arrays
    – Sam Mason
    May 10, 2019 at 19:27
  • @SamMason thank you for pointing the error, I have updated the answer and made a tester too May 10, 2019 at 20:08
0

Community says arr.sort((a, b) => 0.5 - Math.random()) isn't 100% random!
yes! I tested and recommend do not use this method!

let arr = [1, 2, 3, 4, 5, 6]
arr.sort((a, b) => 0.5 - Math.random());

But I am not sure. So I Write some code to test !...You can also Try ! If you are interested enough!

let data_base = []; 
for (let i = 1; i <= 100; i++) { // push 100 time new rendom arr to data_base!
  data_base.push(
    [1, 2, 3, 4, 5, 6].sort((a, b) => {
      return  Math.random() - 0.5;     // used community banned method!  :-)      
    })
  );
} // console.log(data_base);  // if you want to see data!
let analysis = {};
for (let i = 1; i <= 6; i++) {
  analysis[i] = Array(6).fill(0);
}
for (let num = 0; num < 6; num++) {
  for (let i = 1; i <= 100; i++) {
    let plus = data_base[i - 1][num];
    analysis[`${num + 1}`][plus-1]++;
  }
}
console.log(analysis); // analysed result 

In 100 different random arrays. (my analysed result)

{ player> 1   2   3  4   5   6
   '1': [ 36, 12, 17, 16, 9, 10 ],
   '2': [ 15, 36, 12, 18, 7, 12 ],
   '3': [ 11, 8, 22, 19, 17, 23 ],
   '4': [ 9, 14, 19, 18, 22, 18 ],
   '5': [ 12, 19, 15, 18, 23, 13 ],
   '6': [ 17, 11, 15, 11, 22, 24 ]
}  
// player 1 got > 1(36 times),2(15 times),...,6(17 times)
// ... 
// ...
// player 6 got > 1(10 times),2(12 times),...,6(24 times)

As you can see It is not that much random ! soo... do not use this method!


If you test multiple times.You would see that player 1 got (number 1) so many times!
and player 6 got (number 6) most of the times!

0
 const arr = [
  { index: 0, value: "0" },
  { index: 1, value: "1" },
  { index: 2, value: "2" },
  { index: 3, value: "3" },
];
let shuffle = (arr) => {
  let set = new Set();
  while (set.size != arr.length) {
    let rand = Math.floor(Math.random() * arr.length);
    set.add(arr[rand]);
  }
  console.log(set);
};
shuffle(arr);
0

For more flexibility you can add another parameter. In this case, you can take a random array from an array and specify the length of the new array:

  function shuffle(array, len = array.length) {
        for (let i = array.length - 1; i > 0; i--) {
            let j = Math.floor(Math.random() * (i + 1));
            [array[i], array[j]] = [array[j], array[i]];
        }

        return array.slice(0, len);
    }
1
  • There’s an optimization possible when you muddy the signature of shuffle to include a length, but this implementation doesn’t do it and is strictly worse than shuffle(array).slice(0, len).
    – Ry-
    Mar 26 at 6:45
0

Randomize array without duplicates

    function randomize(array){
        let nums = [];
        for(let i = 0; i < array.length; ++i){
            nums.push(i);
        }   
        nums.sort(() => Math.random() - Math.random()).slice(0, array.length)
        for(let i = 0; i < array.length; ++i){
            array[i] = array[nums[i]];
        }
    }
    randomize(array);
0

Use forEach and Math.random()

var data = ['a','b','c','d','e']
data.forEach( (value,i) => {
   var random = Math.floor(Math.random() * data.length)
   var tmp = data[random]
   data[random] = value
   data[i] = tmp
})
console.log(data)

1
  • I think there is potential for the random number to be the same and so data[random] could contain duplicates.
    – Sambuxc
    Aug 22, 2023 at 13:39
-1

Shuffling array using recursion JS.

Not the best implementation but it's recursive and respect immutability.

const randomizer = (array, output = []) => {
    const arrayCopy = [...array];
    if (arrayCopy.length > 0) {    
        const idx = Math.floor(Math.random() * arrayCopy.length);
        const select = arrayCopy.splice(idx, 1);
        output.push(select[0]);
        randomizer(arrayCopy, output);
    }
    return output;
};
-1

I like to share one of the million ways to solve this problem =)

function shuffleArray(array = ["banana", "ovo", "salsicha", "goiaba", "chocolate"]) {
const newArray = [];
let number = Math.floor(Math.random() * array.length);
let count = 1;
newArray.push(array[number]);

while (count < array.length) {
    const newNumber = Math.floor(Math.random() * array.length);
    if (!newArray.includes(array[newNumber])) {
        count++;
        number = newNumber;
        newArray.push(array[number]);
    }
}

return newArray;

}

4
  • And have you tried this with a million elements? Jan 20, 2021 at 16:42
  • I would expect that this is O (n ^ 2). That's why I asked. Jan 22, 2021 at 18:08
  • 1
    I made it for a small collection, so I didn't worry about it. The collection I was getting was, for sure, maximum 20 items. good observation! Feb 19, 2021 at 14:44
  • Yes, there's always a question of when to bother with any optimizations. Often, when working with small amounts of data, it's just silly. But several answers here already posted variants of the most common efficient shuffle (Fischer-Yates) and they are not much more complex than this. I'm not suggesting that there's anything wrong here, only that you might want to avoid this for large arrays. Feb 19, 2021 at 14:51
-1

here with simple while loop

 function ShuffleColor(originalArray) {
        let shuffeledNumbers = [];
        while (shuffeledNumbers.length <= originalArray.length) {
            for (let _ of originalArray) {
                const randomNumb = Math.floor(Math.random() * originalArray.length);
                if (!shuffeledNumbers.includes(originalArray[randomNumb])) {
                    shuffeledNumbers.push(originalArray[randomNumb]);
                }
            }
            if (shuffeledNumbers.length === originalArray.length)
                break;
        }
        return shuffeledNumbers;
    }
const colors = [
    '#000000',
    '#2B8EAD',
    '#333333',
    '#6F98A8',
    '#BFBFBF',
    '#2F454E'
]
ShuffleColor(colors)
-1

This leaves the original array alone.

It builds an array of keys, duplicates a value into a new array using a random key and removes the key from the keys array.

arr = [10,11,12,13,14,15,16,17,18,19,20];
rnd = [];
keys = arr.map((a,b)=>b);
while(keys.length){
  rnd.push(arr[keys.splice(Math.floor(Math.random()*keys.length ),1)]);
}
console.log(rnd);

To write out the while loop a bit for clarity:

while(keys.length){

    // pick a random position in the keys array
    rndkey = Math.floor(Math.random()*keys.length)

    //remove a key from the keys array
    curkey = keys.splice(rndkey,1)

    // use the key to get a value from the array
    value = arr[curkey]

    // put the value in the new array
    rnd.push(value);
}

You often want to shuffle an array often. If it is enormous you could build the keys array one time then .slice() it for each use.

-2

Using sort method and Math method :

var arr =  ["HORSE", "TIGER", "DOG", "CAT"];
function shuffleArray(arr){
  return arr.sort( () => Math.floor(Math.random() * Math.floor(3)) - 1)  
}

// every time it gives random sequence
shuffleArr(arr);
// ["DOG", "CAT", "TIGER", "HORSE"]
// ["HORSE", "TIGER", "CAT", "DOG"]
// ["TIGER", "HORSE", "CAT", "DOG"]
1
  • This isn't properly random. See other comments on similar answers that use random() inside sort(). Oct 16, 2020 at 19:43
-2
//doesn change array
Array.prototype.shuffle = function () {
    let res = [];
    let copy = [...this];

    while (copy.length > 0) {
        let index = Math.floor(Math.random() * copy.length);
        res.push(copy[index]);
        copy.splice(index, 1);
    }

    return res;
};

let a=[1, 2, 3, 4, 5, 6, 7, 8, 9];
console.log(a.shuffle());
-3

$=(m)=>console.log(m);

//----add this method to Array class 
Array.prototype.shuffle=function(){
  return this.sort(()=>.5 - Math.random());
};

$([1,65,87,45,101,33,9].shuffle());
$([1,65,87,45,101,33,9].shuffle());
$([1,65,87,45,101,33,9].shuffle());
$([1,65,87,45,101,33,9].shuffle());
$([1,65,87,45,101,33,9].shuffle());

4
  • 3
    This is very bad as the elements have a high probability of staying near their original position or barely moving from there.
    – Domino
    Jul 26, 2016 at 5:03
  • 2
    If it bad , chain it twice or more : array.shuffle().shuffle().shuffle() Jul 26, 2016 at 6:23
  • 5
    Repeating the call slightly reduces the probabilities of getting very similar results, but it doesn't make it a true random shuffle. In the worst case scenario, even an infinite number of calls to shuffle could still give the exact same array we started with. The Fisher-Yates algorithm is a much better and still efficient choice.
    – Domino
    Jul 27, 2016 at 4:03
  • 6
    Not the same awful answer again, please.
    – Oriol
    Aug 2, 2016 at 17:39
-3

A functional solution using Ramda.

const {map, compose, sortBy, prop} = require('ramda')

const shuffle = compose(
  map(prop('v')),
  sortBy(prop('i')),
  map(v => ({v, i: Math.random()}))
)

shuffle([1,2,3,4,5,6,7])
1
2

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