# Transposing a 2D-array in JavaScript

I've got an array of arrays, something like:

``````[
[1,2,3],
[1,2,3],
[1,2,3],
]
``````

I would like to transpose it to get the following array:

``````[
[1,1,1],
[2,2,2],
[3,3,3],
]
``````

It's not difficult to programmatically do so using loops:

``````function transposeArray(array, arrayLength){
var newArray = [];
for(var i = 0; i < array.length; i++){
newArray.push([]);
};

for(var i = 0; i < array.length; i++){
for(var j = 0; j < arrayLength; j++){
newArray[j].push(array[i][j]);
};
};

return newArray;
}
``````

This, however, seems bulky, and I feel like there should be an easier way to do it. Is there?

• Can you guarantee that the two dimensions will always be the same? 1x1, 2x2, 3x3, etc. What is the `arrayLength` parameter used for exactly? To ensure that you don't go beyond a certain number of elements in the array? Commented Jul 2, 2013 at 14:45
• This has nothing to do with JQuery, I changed the title.
– Joe
Commented Jul 2, 2013 at 14:47
• Check this out: stackoverflow.com/questions/4492678/…. What you are doing is transposing a matrix Commented Jul 2, 2013 at 14:48
• Yes, transposing. Inverting would be completely different and I'm not interested in it. For now. Commented Jul 2, 2013 at 14:59
• The top left to bottom right diagonal is unchanged so there is an optimisation opportunity. Commented Sep 8, 2016 at 17:07

``````output = array[0].map((_, colIndex) => array.map(row => row[colIndex]));
``````

`map` calls a provided `callback` function once for each element in an array, in order, and constructs a new array from the results. `callback` is invoked only for indexes of the array which have assigned values; it is not invoked for indexes which have been deleted or which have never been assigned values.

`callback` is invoked with three arguments: the value of the element, the index of the element, and the Array object being traversed. [source]

• This is a good solution. However, if you care about performance you should use OP's original solution (w/ the bug fix to support M x N arrays where M != N). check this jsPerf Commented Aug 4, 2015 at 22:28
• If you use it twice on the same array, it comes back to the first one intead of rotating 90' again Commented Mar 3, 2017 at 13:51
• why `array[0].map` instead of `array.map` ? Commented Sep 8, 2018 at 16:48
• `array[0].map` because he wants to iterate however many times that there are columns, `array.map` would iterate how many rows there are. Commented Oct 23, 2018 at 19:45
• @BillyMcKee in year 2019 and Chrome 75 `loops` are 45% slower than `map`. And yes, it transposes correctly, so the second run returns initial matrix. Commented Jul 19, 2019 at 5:27

Many good answers here! I consolidated them into one answer and updated some of the code for a more modern syntax:

One-liners inspired by Fawad Ghafoor and Óscar Gómez Alcañiz

``````function transpose(matrix) {
return matrix[0].map((col, i) => matrix.map(row => row[i]));
}

function transpose(matrix) {
return matrix[0].map((col, c) => matrix.map((row, r) => matrix[r][c]));
}
``````

Functional approach style with reduce by Andrew Tatomyr

``````function transpose(matrix) {
return matrix.reduce((prev, next) => next.map((item, i) =>
(prev[i] || []).concat(next[i])
), []);
}
``````

Lodash/Underscore by marcel

``````function transpose(matrix) {
return _.zip(...matrix);
}

function transpose(matrix) {
return _.zip.apply(_, [[1,2,3], [1,2,3], [1,2,3]])
}
``````

Even simpler Lodash/Underscore solution by Vigrant

``````_.unzip(matrix);
``````

Vanilla approach

``````function transpose(matrix) {
const rows = matrix.length, cols = matrix[0].length;
const grid = [];
for (let j = 0; j < cols; j++) {
grid[j] = Array(rows);
}
for (let i = 0; i < rows; i++) {
for (let j = 0; j < cols; j++) {
grid[j][i] = matrix[i][j];
}
}
return grid;
}
``````

Vanilla in-place ES6 approach inspired by Emanuel Saringan

``````function transpose(matrix) {
for (var i = 0; i < matrix.length; i++) {
for (var j = 0; j < i; j++) {
const temp = matrix[i][j];
matrix[i][j] = matrix[j][i];
matrix[j][i] = temp;
}
}
}

// Using destructing
function transpose(matrix) {
for (var i = 0; i < matrix.length; i++) {
for (var j = 0; j < i; j++) {
[matrix[i][j], matrix[j][i]] = [matrix[j][i], matrix[i][j]];
}
}
}
``````
• Thanks for this compilation. #1 is fast and #ES6 with destruction. Commented Nov 13, 2022 at 23:27

here is my implementation in modern browser (without dependency):

``````transpose = m => m[0].map((x,i) => m.map(x => x[i]))
``````

You could use underscore.js

``````_.zip.apply(_, [[1,2,3], [1,2,3], [1,2,3]])
``````
• That was pretty - also, underscore is more necessary to me than jQuery is. Commented Jul 2, 2013 at 14:52
• or if you are using a functional library like `rambda` you can just do `const transpose = apply(zip)` Commented Apr 26, 2018 at 5:09
• Why would this option be better than the selected answer? Commented Jul 31, 2018 at 15:46
• This question is years old and I'm not sure it is, now. It is, though, cleaner than the original version of the accepted answer. You'll notice that it's been edited substantially since. Looks like it uses ES6, which I don't think was available in 2013 when the question widely was asked.
– Joe
Commented Jul 31, 2018 at 16:02

shortest way with `lodash`/`underscore` and `es6`:

``````_.zip(...matrix)
``````

where `matrix` could be:

``````const matrix = [[1,2,3], [1,2,3], [1,2,3]];
``````
• Or, without ES6: `_.zip.apply(_, matrix)`
– ach
Commented Jul 29, 2015 at 20:21
• Close but _.unzip(matrix) is shorter ;) Commented Mar 18, 2016 at 7:21
• Can you expand on this? I don't get what you're saying here. That short snipplet is supposed to solve the problem? or is it just a part or what? Commented Sep 5, 2016 at 9:00
• my gosh that's a short solution. just learned about the ... operator - used it to break down a string into an array of letters... thanks for the reply Commented Sep 9, 2016 at 17:15

Neat and pure:

``````[[0, 1], [2, 3], [4, 5]].reduce((prev, next) => next.map((item, i) =>
(prev[i] || []).concat(next[i])
), []); // [[0, 2, 4], [1, 3, 5]]
``````

Previous solutions may lead to failure in case an empty array is provided.

Here it is as a function:

``````function transpose(array) {
return array.reduce((prev, next) => next.map((item, i) =>
(prev[i] || []).concat(next[i])
), []);
}

console.log(transpose([[0, 1], [2, 3], [4, 5]]));
``````

Update. It can be written even better with spread operator:

``````const transpose = matrix => matrix.reduce(
(\$, row) => row.map((_, i) => [...(\$[i] || []), row[i]]),
[]
)
``````
• I dont know that I would call that update any better. It is clever, sure, but that is a nightmare to read. Commented Feb 6, 2020 at 3:33

You can do it in in-place by doing only one pass:

``````function transpose(arr,arrLen) {
for (var i = 0; i < arrLen; i++) {
for (var j = 0; j <i; j++) {
//swap element[i,j] and element[j,i]
var temp = arr[i][j];
arr[i][j] = arr[j][i];
arr[j][i] = temp;
}
}
}
``````
• if your array is not a square (for example 2x8) this doesnt work I guess Commented Mar 3, 2017 at 13:54
• This solution changes the original array. If you still need the original array then this solution might be not what you want. Other solutions create a new array instead.
– Alex
Commented Aug 21, 2017 at 13:43
• Does anyone know how this is done in ES6 syntax? I tried `[arr[j][j],arr[i][j]] = [arr[i][j],arr[j][j]]` but it doesn't seem to work, am I missing something? Commented Apr 22, 2020 at 13:51
• @Nikasv you likely want `[arr[j][i], arr[i][j]] = [arr[i][j], arr[j][i]]`. Note that you have some `arr[j][j]` terms which will always refer to cells on the diagonal. Commented Jun 14, 2020 at 20:00

Just another variation using `Array.map`. Using indexes allows to transpose matrices where `M != N`:

``````// Get just the first row to iterate columns first
var t = matrix[0].map(function (col, c) {
// For each column, iterate all rows
return matrix.map(function (row, r) {
return matrix[r][c];
});
});
``````

All there is to transposing is mapping the elements column-first, and then by row.

Another approach by iterating the array from outside to inside and reduce the matrix by mapping inner values.

``````const
transpose = array => array.reduce((r, a) => a.map((v, i) => [...(r[i] || []), v]), []),
matrix = [[1, 2, 3], [1, 2, 3], [1, 2, 3]];

console.log(transpose(matrix));``````

• Indeed! You have optimized @Andrew Tatomyr answer ! (benchmarks work on your favor! ;) Commented Oct 10, 2018 at 20:29

If you have an option of using Ramda JS and ES6 syntax, then here's another way to do it:

``````const transpose = a => R.map(c => R.map(r => r[c], a), R.keys(a[0]));

console.log(transpose([
[1, 2, 3, 4],
[5, 6, 7, 8],
[9, 10, 11, 12]
])); // =>  [[1,5,9],[2,6,10],[3,7,11],[4,8,12]]``````
``<script src="https://cdnjs.cloudflare.com/ajax/libs/ramda/0.22.1/ramda.min.js"></script>``

• Awesomeness for using both Ramda and ES6 to solve this Commented May 29, 2015 at 17:31
• Ramda actually has a `transpose`-function now. Commented Jan 11, 2017 at 23:29

If using RamdaJS is an option, this can be achieved in one line: `R.transpose(myArray)`

### `Spread` syntax should not be used as an alternative to `push`, it should only be used when you don't want to mutate the existing array.

Algorithm: For every column, just check if for that column there's a row in the resultant matrix, if there's already a row then simply `push` the element, else create a new row array and then `push`.

So, unlike many other solutions above, this solution doesn't create new arrays again and again, instead pushes onto the same array.

Also, take some time to appreciate the use of the Nullish Coalescing Operator.

``````const
transpose = arr => arr.reduce((m, r) => (r.forEach((v, i) => (m[i] ??= [], m[i].push(v))), m), []),
matrix = [[1, 2, 3], [1, 2, 3], [1, 2, 3]]

console.log(transpose(matrix))``````

You can achieve this without loops by using the following.

It looks very elegant and it does not require any dependencies such as jQuery of Underscore.js.

``````function transpose(matrix) {
return zeroFill(getMatrixWidth(matrix)).map(function(r, i) {
return zeroFill(matrix.length).map(function(c, j) {
return matrix[j][i];
});
});
}

function getMatrixWidth(matrix) {
return matrix.reduce(function (result, row) {
return Math.max(result, row.length);
}, 0);
}

function zeroFill(n) {
return new Array(n+1).join('0').split('').map(Number);
}
``````

Minified

``````function transpose(m){return zeroFill(m.reduce(function(m,r){return Math.max(m,r.length)},0)).map(function(r,i){return zeroFill(m.length).map(function(c,j){return m[j][i]})})}function zeroFill(n){return new Array(n+1).join("0").split("").map(Number)}
``````

Here is a demo I threw together. Notice the lack of loops :-)

``````// Create a 5 row, by 9 column matrix.
var m = CoordinateMatrix(5, 9);

// Make the matrix an irregular shape.
m[2] = m[2].slice(0, 5);
m[4].pop();

// Transpose and print the matrix.
println(formatMatrix(transpose(m)));

function Matrix(rows, cols, defaultVal) {
return AbstractMatrix(rows, cols, function(r, i) {
return arrayFill(cols, defaultVal);
});
}
function ZeroMatrix(rows, cols) {
return AbstractMatrix(rows, cols, function(r, i) {
return zeroFill(cols);
});
}
function CoordinateMatrix(rows, cols) {
return AbstractMatrix(rows, cols, function(r, i) {
return zeroFill(cols).map(function(c, j) {
return [i, j];
});
});
}
function AbstractMatrix(rows, cols, rowFn) {
return zeroFill(rows).map(function(r, i) {
return rowFn(r, i);
});
}
/** Matrix functions. */
function formatMatrix(matrix) {
return matrix.reduce(function (result, row) {
return result + row.join('\t') + '\n';
}, '');
}
function copy(matrix) {
return zeroFill(matrix.length).map(function(r, i) {
return zeroFill(getMatrixWidth(matrix)).map(function(c, j) {
return matrix[i][j];
});
});
}
function transpose(matrix) {
return zeroFill(getMatrixWidth(matrix)).map(function(r, i) {
return zeroFill(matrix.length).map(function(c, j) {
return matrix[j][i];
});
});
}
function getMatrixWidth(matrix) {
return matrix.reduce(function (result, row) {
return Math.max(result, row.length);
}, 0);
}
/** Array fill functions. */
function zeroFill(n) {
return new Array(n+1).join('0').split('').map(Number);
}
function arrayFill(n, defaultValue) {
return zeroFill(n).map(function(value) {
return defaultValue || value;
});
}
/** Print functions. */
function print(str) {
str = Array.isArray(str) ? str.join(' ') : str;
return document.getElementById('out').innerHTML += str || '';
}
function println(str) {
print.call(null, [].slice.call(arguments, 0).concat(['<br />']));
}``````
``````#out {
white-space: pre;
}``````
``<div id="out"></div>``

• Why would you not want to do it without loops? Without loops it's slow Commented Jul 11, 2016 at 0:31
• Isn't .map a loop? Just one you don't see? I mean it's going over every of the inputs and does stuff to it... Commented Sep 5, 2016 at 8:59

I found the above answers either hard to read or too verbose, so I write one myself. And I think this is most intuitive way to implement transpose in linear algebra, you don't do value exchange, but just insert each element into the right place in the new matrix:

``````function transpose(matrix) {
const rows = matrix.length
const cols = matrix[0].length

let grid = []
for (let col = 0; col < cols; col++) {
grid[col] = []
}
for (let row = 0; row < rows; row++) {
for (let col = 0; col < cols; col++) {
grid[col][row] = matrix[row][col]
}
}
return grid
}
``````

Edit: This answer would not transpose the matrix, but rotate it. I didn't read the question carefully in the first place :D

clockwise and counterclockwise rotation:

``````    function rotateCounterClockwise(a){
var n=a.length;
for (var i=0; i<n/2; i++) {
for (var j=i; j<n-i-1; j++) {
var tmp=a[i][j];
a[i][j]=a[j][n-i-1];
a[j][n-i-1]=a[n-i-1][n-j-1];
a[n-i-1][n-j-1]=a[n-j-1][i];
a[n-j-1][i]=tmp;
}
}
return a;
}

function rotateClockwise(a) {
var n=a.length;
for (var i=0; i<n/2; i++) {
for (var j=i; j<n-i-1; j++) {
var tmp=a[i][j];
a[i][j]=a[n-j-1][i];
a[n-j-1][i]=a[n-i-1][n-j-1];
a[n-i-1][n-j-1]=a[j][n-i-1];
a[j][n-i-1]=tmp;
}
}
return a;
}
``````
• Does not answer the question, though; Transposing is like ... mirroring along the diagonal (not rotating) Commented Oct 19, 2017 at 13:18
• @DerMike thanks for pointing out. I don't know why I made that mistake :) But at least I can see it has been useful for some other people. Commented Oct 20, 2017 at 10:06
• Here is my one-liner code for rotating a matrix: stackoverflow.com/a/58668351/741251 Commented Nov 2, 2019 at 4:58

``````const transpose = array => array[0].map((r, i) => array.map(c => c[i]));
console.log(transpose([[2, 3, 4], [5, 6, 7]]));``````

ES6 1liners as :

``````let invert = a => a[0].map((col, c) => a.map((row, r) => a[r][c]))
``````

so same as Óscar's, but as would you rather rotate it clockwise :

``````let rotate = a => a[0].map((col, c) => a.map((row, r) => a[r][c]).reverse())

let a = [
[1,1,1]
, ["_","_","1"]
]
let b = rotate(a);
let c = rotate(b);
let d = rotate(c);
console.log(`a \${a.join("\na ")}`);
console.log(`b \${b.join("\nb ")}`);
console.log(`c \${c.join("\nc ")}`);
console.log(`d \${d.join("\nd ")}`);
``````

Yields

``````a 1,1,1
a _,_,1

b _,1
b _,1
b 1,1

c 1,_,_
c 1,1,1

d 1,1
d 1,_
d 1,_
``````

Since nobody so far mentioned a functional recursive approach here is my take. An adaptation of Haskell's `Data.List.transpose`.

``````var transpose = as => as.length ? as[0].length ? [as.reduce((rs, a) => a.length ? (rs.push(a[0]), rs) :
rs, []
), ...transpose(as.map(a => a.slice(1)))] :
transpose(as.slice(1)) :
[],
mtx = [
[1],
[1, 2],
[1, 2, 3]
];

console.log(transpose(mtx))``````
``````.as-console-wrapper {
max-height: 100% !important
}``````

• I find this u => n ...r [ e.a( d? a , b : l ) e
– Wyck
Commented Sep 14, 2020 at 19:33

I didn't find an answer that satisfied me, so I wrote one myself, I think it is easy to understand and implement and suitable for all situations.

``````    transposeArray: function (mat) {
let newMat = [];
for (let j = 0; j < mat[0].length; j++) {  // j are columns
let temp = [];
for (let i = 0; i < mat.length; i++) {  // i are rows
temp.push(mat[i][j]);  // so temp will be the j(th) column in mat
}
newMat.push(temp);  // then just push every column in newMat
}
return newMat;
}
``````

``````const transpose = <T>(m: Array<Array<T>>): Array<Array<T>> => m[0].map((_, i) => m.map(x => x[i]));
``````

``````const arr = [
[1,2,3],
[1,2,3],
[1,2,3]
];

var output = arr.map((row, rowIndex) => {
row.forEach((col, colIndex) => {
if(colIndex > rowIndex) {
var temp = arr[colIndex][rowIndex];
arr[colIndex][rowIndex] = row[colIndex];
row[colIndex] = temp;
}
});
return row;
});

console.log(output);``````

``````function invertArray(array,arrayWidth,arrayHeight) {
var newArray = [];
for (x=0;x<arrayWidth;x++) {
newArray[x] = [];
for (y=0;y<arrayHeight;y++) {
newArray[x][y] = array[y][x];
}
}
return newArray;
}
``````

One-liner that does not change given array.

``````a[0].map((col, i) => a.map(([...row]) => row[i]))
``````
``````reverseValues(values) {
let maxLength = values.reduce((acc, val) => Math.max(val.length, acc), 0);
return [...Array(maxLength)].map((val, index) => values.map((v) => v[index]));
}
``````
• Please don't post only code as an answer, but include an explanation what your code does and how it solves the problem of the question. Answers with an explanation are generally of higher quality and more likely to attract upvotes. Commented Sep 26, 2019 at 17:36

There is more efficient solution, in cases where `n = m` (number of rows equals to number of columns).

``````const matrix = [
[1,1,1,1],
[2,2,2,2],
[3,3,3,3],
[4,4,4,4]
];

matrix.every((r, i, a) => (
r.every((_, j) => (
j = a.length-j-1,
[ r[j], a[j][i] ] = [ a[j][i], r[j] ],
i < j-1
)),
i < length-2
));

console.log(matrix);
/*
Prints:
[
[1,2,3,4],
[1,2,3,4],
[1,2,3,4],
[1,2,3,4]
]
*/
``````

The example above will do only 6 iterations.
For bigger matrix, say 100x100 it will do 4,900 iterations, this is 51% faster than a full scan.

The principle is simple. You only need to iterate through the upper diagonal half of the matrix (`X`s in the matrix below), and switch with bottom diagonal half (`O`s in the matrix below).

``````[
[-,X,X,X],
[O,-,X,X],
[O,O,-,X],
[O,O,O,-],
]
``````

This way, you can save a lot of running time, especially in a very large matrix.