# How to flatten nested array in javascript? [duplicate]

As we know, to flatten the array `[[0, 1], [2, 3], [4, 5]]` by using the method `reduce()`

``````var flattened = [[0, 1], [2, 3], [4, 5]].reduce(function(a, b) {
return a.concat(b);
});
``````

So how to flatten this array `[[[0], [1]], [[2], [3]], [[4], [5]]]` to `[0, 1, 2, 3, 4, 5]`?

• See this discussion here: stackoverflow.com/questions/10865025/… Dec 3, 2014 at 8:08
• [[[0], [1]], [[2], [3]], [[4], [5]]].toString().split(",").map(Number); Dec 3, 2014 at 8:11
• @dandavis this is black magic. What if he has strings or other types? :D
– Leo
Dec 3, 2014 at 8:58
• @LeoDeng: i didn't see any strings, and other methods would be too complicated to fit in a comment... Dec 3, 2014 at 9:00
• @dandavis I mean, he was just taking 12345 for an example, I assume. Essentially I think it should be a recursion. The code he posted was from this page: developer.mozilla.org/en/docs/Web/JavaScript/Reference/…
– Leo
Dec 3, 2014 at 9:02

Perfect use case for recursion, which could handle even deeper structure:

``````function flatten(ary) {
var ret = [];
for(var i = 0; i < ary.length; i++) {
if(Array.isArray(ary[i])) {
ret = ret.concat(flatten(ary[i]));
} else {
ret.push(ary[i]);
}
}
return ret;
}

flatten([[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]]) // [0, 1, 2, 3, 4, 5]
``````

Alternatively, as an Array method:

``````Array.prototype.flatten = function() {
var ret = [];
for(var i = 0; i < this.length; i++) {
if(Array.isArray(this[i])) {
ret = ret.concat(this[i].flatten());
} else {
ret.push(this[i]);
}
}
return ret;
};

[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flatten() // [0, 1, 2, 3, 4, 5]
``````

EDIT #1: Well, think it a little bit functional way (except for the named recursion which should be using Y-combinator for pure functional :D).

``````function flatten(ary) {
return ary.reduce(function(a, b) {
if (Array.isArray(b)) {
return a.concat(flatten(b))
}
return a.concat(b)
}, [])
}
``````

Let's adopt some ES6 syntax which makes it even shorter, in one line.

``````const flatten = (ary) => ary.reduce((a, b) => a.concat(Array.isArray(b) ? flatten(b) : b), [])
``````

But remember, this one cannot be applied as an array method, because arrow functions don't have theirs own `this`.

EDIT #2: With the latest `Array.prototype.flat` proposal this is super easy. The array method accepts an optional parameter `depth`, which specifies how deep a nested array structure should be flattened (default to `1`).

``````[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flat()  // [[[[0]], [1]], [[[2], [3]]], [[4], [5]]]
[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flat(2) // [[[0]], [1], [[2], [3]], [4], [5]]
[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flat(3) // [[0], 1, [2], [3], 4, 5]
[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flat(4) // [0, 1, 2, 3, 4, 5]
``````

So to flatten an array of arbitrary depth, just call `flat` method with `Infinity`.

``````[[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]].flat(Infinity) // [0, 1, 2, 3, 4, 5]
``````
• This could be made a bit faster by reusing the `ret` array. See my answer for such an solution. Jan 13, 2016 at 3:00
• isn't this n^2? `concat` is not a constant time operation. It's a O(n) operation AFAIK. May 3, 2018 at 1:07

ES6-style with recursion:

``````Redacted
``````

June 2018 Update:

There is now an ES proposal for an `Array.prototype.flat` method. It is currently at stage 3, meaning it's likely to be implemented by browsers soon(ish) and make it into the spec in its current form. There are probably some polyfills floating around.

Example:

``````const nested = [[[0], [1]], [[2], [3]], [[4], [5]]];
const flattened = nested.flat(2);  // Need to specify depth if > 1
``````

June 2019 Update:

`Array.prototype.flat` was officially added to the language in the ES2019 spec.

• Good practice for ES6 Feb 24, 2016 at 2:55
• any draw back to calling this method with infinity as the other answer suggests? we don't always know the depth of the array. Aug 16, 2021 at 17:31
• @AngelaP It's designed to be used like that, however in practice it seems there's a limit to how deep the array can go. After testing, for me in Chrome that limit seems to be 7387 - any more and it will throw a "Maximum call stack size exceeded" error. I'm also able to flatten an array with a circular reference (i.e. infinitely recursive) up to that limit - in other words `.flat(7387)` works but `.flat(7388)` throws the same error. Other browsers/engines may behave differently, but if the arrays you're operating on are anywhere near that deep I think you have bigger issues. Feb 14, 2022 at 8:37

This is an alternative to recursion (see jsfiddle here) and should accept any level of depth which avoids stack overflow.

``````var array = [[0, 1], [2, 3], [4, 5, [6, 7, [8, [9, 10]]]]];
console.log(flatten(array), array); // does not mutate array
console.log(flatten(array, true), array); // array is now empty

// This is done in a linear time O(n) without recursion
// memory complexity is O(1) or O(n) if mutable param is set to false
function flatten(array, mutable) {
var toString = Object.prototype.toString;
var arrayTypeStr = '[object Array]';

var result = [];
var nodes = (mutable && array) || array.slice();
var node;

if (!array.length) {
return result;
}

node = nodes.pop();

do {
if (toString.call(node) === arrayTypeStr) {
nodes.push.apply(nodes, node);
} else {
result.push(node);
}
} while (nodes.length && (node = nodes.pop()) !== undefined);

result.reverse(); // we reverse result to restore the original order
return result;
}``````

• Why are you using `Object.prototype.toString.call(node) == '[object Array]'` instead of `Array.isArray(node)`? Dec 4, 2014 at 3:57
• It's just for ie8 and below Dec 4, 2014 at 8:17
• sneaky using apply in there to split the arr, love it. Jul 8, 2016 at 15:49
• Why not use instanceof operator instead of toString? if (node instanceof Array) { nodes.push.apply(nodes, node); } else { result.push(node); } Jul 31, 2016 at 19:03
• You could do that too, yes. Matter of taste at this point Aug 3, 2016 at 6:37
``````ary.flat(Infinity);
``````

That's it. It's that simple. You can change `Infinity` to be the appropriate level of flattenedness if you wish.

Example:

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

Other, longer solutions that work with older browsers below.

Based on @Leo's solution, but faster by reusing the same array and preventing `.concat`

``````function flatten(ary, ret = []) {
for (const entry of ary) {
if (Array.isArray(entry) {
flatten(entry, ret);
} else {
ret.push(entry);
}
}
return ret;
}
console.log(flatten([[[0], [1]], [[2], [3]], [[4], [5]]]));``````

Or with `Array.prototype.reduce`, since you mentioned it:

``````function flatten(ary, ret = []) {
return ary.reduce((ret, entry) => {
if (Array.isArray(entry)) {
flatten(entry, ret);
} else {
ret.push(entry);
}
return ret;
}, ret);
}
console.log(flatten([[[0], [1]], [[2], [3]], [[4], [5]]]));``````

• Probably the best and most readable solution out here Sep 13, 2016 at 13:08
• Much, much, much better answer than most here. There's no good reason at all for all of the temporary arrays floating around the other answers. Feb 27, 2017 at 13:16
• @timothygu can you explain how will you describe time and space complexity of both solutions in Big-O Notation? Mar 12, 2017 at 9:52
• @baltusaj Asymptotic analysis is pretty much useless for this specific case, since all solutions in this question follow essentially the same algorithm. It's about the constant terms (like creation of an empty array) that differentiate this solution from the rest. Mar 20, 2017 at 4:44
• This is still slower than the accepted answer. Nov 30, 2017 at 18:24

ES6 one-liner:

``````function flatten(a) {
return Array.isArray(a) ? [].concat(...a.map(flatten)) : a;
}
``````

Also, non-recursive version for very deep arrays (not very efficient but rather elegant)

``````function flatten(a) {
var queue = a.slice();
var result = [];
while(queue.length) {
let curr = queue.pop();
if(Array.isArray(curr)) {
queue.push(...curr);
}
else result.push(curr);
}
return result;
}
``````
• You ES6 one-liner looks very nice but can you add explanation about how is it working exactly? Mar 12, 2017 at 9:45
• @baltusaj it's a recursive solution. If the current element is not an array, return it. If it is, flatten every element of the array (using Array.map) and then concatenate the resulting arrays (using Array.concat and spreading the array to function parameters) Mar 12, 2017 at 9:49
• thanks. I guess the "spreading" is done by the three dots. Mar 12, 2017 at 9:54
• more es6 magic: let flatten = a => Array.isArray(a) ? [].concat(...a.map(flatten)) : a; Jul 7, 2017 at 17:03
• @matanso your non recursive solution is printing the array in reverse order, instead on queue.pop() if you use queue.shift() it will work fine as expected. Sep 10, 2020 at 5:02

Flattens 2 levels only:

``````var arr = [1, [2, 3], [4, 5, 6]];
[].concat.apply([], arr) // -> [1, 2, 3, 4, 5, 6]
``````

``````    var array = [[[0], [1]], [[2], [3]], [[4], [5]]];
var flattend = array.join(",").split(",");
console.log(flattend);
``````

Only side affect is that the join converts all items to strings, but that can be easilly fixed

• For numbers and strings this solution is pretty intelligent, but the problem becomes more complicated when objects and functions are involved. Jan 13, 2016 at 3:19
• I was looking for easy solution to use on strings arrays. This one is perfect. Apr 22, 2021 at 13:27

I like my solution :)

``````var flattenClosure = function(a) {
var store = [];

return function() {
var internMapper = function(b) {
if (Array.isArray(b)) {
return b.map(internMapper);
}
store.push(b);
return b;
}
a.map(internMapper);
return store;
}
};

console.log(flattenClosure([[[[[[[[1]]]], [2], [4], [6, 8, 9], 2]]], 10, 11, [15, 17, 20], [], 33])());
``````

If you're aware the array is made up of only numbers you can just do the following:

``````array.join().split(',').map(Number);
``````
• answered an interview question with something like this. Not sure the humor was appreciated... lol Feb 8, 2018 at 18:15

Inspired by code from Eloquent JavaScript and the answer provided by @axelduch (A lot more efficient from what I can tell too.)

``````function flatten(array, mutable) {
var nodes = (mutable && array) || array.slice(); // return a new array.
var flattened = [];

for (var node = nodes.shift(); node !== undefined; node = nodes.shift()) {
if (Array.isArray(node)) {
nodes.unshift.apply(nodes, node);
} else {
flattened.push(node);
}
}

return flattened;
}
``````
• These solutions need more upvotes, the usage of apply is so clutch for efficiency. Jul 8, 2016 at 15:58
• looks like the original by @axelduch is faster Nov 27, 2017 at 14:43

Disclaimer: I know that it is an old and already answered question, but @Nick has got me into it as I have commented his answer as one of the most expensive way to flatten an array. I haven't been coding JavaScript for years, but it's like riding a bike - once you learn you'll never forget ;)

Here is my full recursive code (no `for` loop needed):

``````var flattened = [];
function flatten(a, i) {
if(a.length > i) {
if(Array.isArray(a[i]))
flatten(a[i], 0);
else
flattened.push(a[i]);
flatten(a, i + 1);
}
}

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

I have tested it against `toString().split(',')` solution and mine is about 7 times faster. That's what I mean when talking about expensiveness ;)

``````function flatten(array) {
return array.reduce(
(previous, current) =>
Array.isArray(current)
? [...previous, ...flatten(current)]
: [...previous, current]
, []
);
}
``````
• While this code may answer the question, providing additional context regarding why and/or how this code answers the question improves its long-term value. Mar 11, 2016 at 6:48
``````var nested = [[[0], [1]], [[2], [3]], [[4], [5]]];
var flattened = [].concat.apply([],[].concat.apply([],nested));
console.log('-> flattened now: ' + flattened);
``````
• if we change `nested` to `[[[0], [[1]]], [[2], [3]], [[4], [5]]]` it would flatten everything... also when printing, cannot use `+` or else some debugger might print out by flattening things for you, need to use a `,` instead Nov 20, 2015 at 22:30
• This solution limits the depth to at most three levels. For example, `[[[[4]]]]` will return `[[4]]` rather than `[4]`. Jan 13, 2016 at 2:56

Based on dashamble's answer, but I believe this is a bit simpler to understand:

``````var steamroller = function(arr) {
var result = [];

var dropHeavyObject = function(auxArr) {
var flatnd = [];

flatnd = auxArr.map(function(x) {
if(Array.isArray(x)) {
return dropHeavyObject(x);
} else {
result.push(x);
return x;
}
});

return flatnd;
};

dropHeavyObject(arr);
return result;
}
``````

There are three utility functions in lodash related to your question `flatten`, `flattenDeep`, flattenDepth in `lodash`. `flatten` goes into a single depth, `flattenDeep` goes all the way into the deepest level and flattenDepth gives you the choice of "how deep" to flatten.

Example:

``````> var arr = [[[0], [1]], [[2], [3]], [[4], [5]]];
> _.flattenDeep(arr)
[0, 1, 2, 3, 4, 5]
``````
``````var flattenWithStack = function(arr) {
var stack = [];
var flat = [];
stack.push(arr);
while(stack.length > 0) {
var curr = stack.pop();
if(curr instanceof Array) {
stack = stack.concat(curr);
} else {
flat.push(curr);
}
}
return flat.reverse();
}
``````

Non recursive. Basically dfs.

• Terribly slow method Nov 30, 2017 at 18:25
``````function flatten(x) {
if (x.length == 0) {return []};
if (Array.isArray(x[0])) {
return flatten(x[0].concat(flatten(x.slice(1,x.length))));
}
return [].concat([x[0]], flatten(x.slice(1,x.length)));
}
``````

recursively flattens the array.

• Cannot handle deeper structure though, `flatten([[[[[0]], [1]], [[[2], [3]]], [[4], [5]]]])` returns `[1, 4, 5, 0, 2, 3]`.
– Leo
Dec 3, 2014 at 9:56
• Thank you for pointing this out. I edited my answer to provide a solution that preserves element order (which is similar to your excellent solution). Dec 3, 2014 at 20:42

I was having this issue the other day and discovered a little hack... actually I just realized it's very similar to the last answer and like comment to the above answer indicates, it won't work for objects, but for simple numbers etc. it works just fine.

If you take a nested array to string, it separates the values by commas. Then you can split it by commas to form a string. If you then need to convert the strings to int or float, you can run through the new array converting each value.

``````stringArray = [[0, 1], [2, 3], [4, 5]].toString().split(',');
stringArray.forEach((v,i,a) => a[i] = parseFloat(a[i]));
``````
• I think that's one of the most expensive way to flatten an array.
Jun 20, 2016 at 16:09
• Thanks, Adam. I'm a newbie, and was experimenting with the functions when I discovered this cheat ;) How do you estimate expense?
– Nick
Jun 21, 2016 at 20:47
• Heh, you've got me into this question ;) Please, take a look at my answer.
Jun 21, 2016 at 21:56
• Thanks! Good news is I learned how to do it recursively shortly after I posted the newbie hack above, and it's (using recursion) so easy it's really not worth doing it another way. I see what you mean by expense!
– Nick
Jun 23, 2016 at 12:26

# An implementation with functional programming

With functional programming we can simply derive `flatten` from another more generic function: `traverse`.

The latter is a function to traverse and reduce arbitrarily nested arrays just like flat arrays. This is possible because nested arrays with unknown depth are no more than a particular version of a tree data structure:

``````const traverse = f => g => acc => xs => {
let [leaf, stack] = xs[0][0] === undefined
? [xs[0], xs.slice(1)]
: f([]) (xs);

return stack.length
? traverse(f) (g) (g(leaf) (acc)) (stack)
: g(leaf) (acc);
};

const dfs = stack => tree => tree[0] === undefined
? [tree, stack]
: dfs(tree.length > 1 ? concat(stack) (tree.slice(1)) : stack) (tree[0]);

const concat = ys => xs => xs.concat(ys);
const flatten = f => traverse(f) (concat) ([]);

const xs = [[[1,2,3],4,5,6],7,8,[9,10,[11,12],[[13]],14],15];

console.log(flatten(dfs) (xs));``````

Please note that tree data structures can either be traversed by depth first (DFS) or by breadth first (BFS). Arrays are usually traversed in depth first order.

As I said `traverse` is a generic reduction function like reduce for flat arrays. So we can easily calculate the sum of all elements as well:

``````const add = y => x => x + y;
traverse(dfs) (add) (0) (xs); // 120
``````

Conclusion: To flatten an arbitrarily nested array in a functional way we just need a one-liner: `const flatten = f => traverse(f) (concat) ([]);`. All other involved functions are generic and have a whole range of other potential applications. This is 100% reusability!

Using `JSON.stringify` and `JSON.parse`

``````arr = JSON.parse("[" +
JSON.stringify(arr)
.replace(/[\[\]]+/g,"")
.replace(/,,/g,",") +
"]");
``````
``````// implementation
function flattenArray(){
const input = arguments[0]
, output = flatten(input)

function flatten(){
return [].concat.apply([], arguments[0])
}

return input.length === output.length
? output
: flattenArray(output)
}

// how to use?
flattenArray([1,2,[3]) // return [1,2,3]
``````
``````function flatten(arrayOfArrays) {
return arrayOfArrays.reduce(function(flat, subElem) {
return flat.concat(Array.isArray(subElem) ? flatten(subElem) : subElem);
}, []);
}

var arr0 = [0, 1, 2, 3, 4];
var arr1 = [[0,1], 2, [3, 4]];
var arr2 = [[[0, 1], 2], 3, 4];
console.log(flatten(arr0));  // [0, 1, 2, 3, 4]
console.log(flatten(arr1));  // [0, 1, 2, 3, 4]
console.log(flatten(arr2));  // [0, 1, 2, 3, 4]
console.log(flatten([]));    // []
``````

Using Lisp conventions.

Using .shift() and .concat() is inefficient, however.

``````    flatten (array) {

// get first element (car) and shift array (cdr)
var car = array.shift();

// check to see if array was empty
if (car === undefined) {
return [];

// if the first element (car) was an array, recurse on it
} else if (_.isArray(car)) {
return flatten(car).concat(flatten(array));

// otherwise, cons (concatenate) the car to the flattened version of cdr (rest of array)
} else {
return [car].concat(flatten(array))
}
}
``````

If you have an infinitely nested array like `a` below, here's what I'd do.

``````const a = [[1,2,[3]],4]

Array.prototype.flatten = (array) => {
const newArray = []
const flattenHelper = (array) => {
array.map(i => {
Array.isArray(i) ? flattenHelper(i) : newArray.push(i)
})
}
flattenHelper(a)
return newArray
}

const newArray = a.flatten()
console.log(newArray);
``````

Heres what I've got:

``````function steamrollArray(arr) {
// the flattened array
var newArr = [];

// recursive function
function flatten(arr, newArr) {
// go through array
for (var i = 0; i < arr.length; i++) {
// if element i of the current array is a non-array value push it
if (Array.isArray(arr[i]) === false) {
newArr.push(arr[i]);
}
// else the element is an array, so unwrap it
else {
flatten(arr[i], newArr);
}
}
}

flatten(arr, newArr);

return newArr;
}
``````
• This will flatten only nested arrays and not linear arrays. Right? Oct 17, 2016 at 8:01

Can be solved like this

``````const array = [[0, 1], [2, 3], [4, 5, [6, 7, [8, [9, 10]]]]];

const flatten(arr) => arr.reduce((acc, item) =>
acc.concat(Array.isArray(item) ? flatten(item) : item);
}, []);

console.log(flatten(array));
``````

Be aware that in case of the deep arrays, the TCO should be applied

The version with the TCO with the recursion solution

``````const array = [[0, 1], [2, 3], [4, 5, [6, 7, [8, [9, 10]]]]];

const flatten = (() => {
const _flatten = (acc, arr) => arr.reduce((acc, item) =>  acc.concat(Array.isArray(item) ? _flatten([], item) : item), acc);

return arr => _flatten([], arr);
})();

console.log(flatten(array))
``````

Think this function works.

`````` function flatten(arr){
return arr.reduce(function(a,b){
return [].concat(Array.isArray(a)? flatten(a) :a,Array.isArray(b)? flatten(b):b);
});

}
``````