The Array.from() static method creates a new, shallow-copied Array instance from an array-like or iterable object.

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Syntax

Array.from( arrayLike [, mapFn [, thisArg ]])

Parameters

arrayLike An array-like or iterable object to convert to an array. mapFn Optional Map function to call on every element of the array. thisArg Optional Value to use as this when executing mapFn .

Return value

A new Array instance.

Description

Array.from() lets you create Array s from:

array-like objects (objects with a length property and indexed elements); or

property and indexed elements); or iterable objects (objects such as Map and Set ).

Array.from() has an optional parameter mapFn , which allows you to execute a map() function on each element of the array being created.

More clearly, Array.from( obj , mapFn , thisArg )

has the same result as Array.from( obj ).map( mapFn , thisArg ) ,

except that it does not create an intermediate array.

This is especially important for certain array subclasses, like typed arrays , since the intermediate array would necessarily have values truncated to fit into the appropriate type.

The length property of the from() method is 1 .

In ES2015, the class syntax allows sub-classing of both built-in and user-defined classes. As a result, static methods such as Array.from() are "inherited" by subclasses of Array , and create new instances of the subclass, not Array .

Polyfill

Array.from() was added to the ECMA-262 standard in the 6th Edition (ES2015). As such, it may not be present in other implementations of the standard.

You can work around this by inserting the following code at the beginning of your scripts, allowing use of Array.from() in implementations that don't natively support it.

Polyfill Notes: This algorithm is exactly as specified in ECMA-262 6th Edition (assuming Object and TypeError have their original values and that callback .call() evaluates to the original value of Function.prototype.call() ). In addition, since true iterables cannot be polyfilled, this implementation does not support generic iterables as defined in the 6th Edition of ECMA-262.

// Production steps of ECMA-262, Edition 6, 22.1.2.1 if (!Array.from) { Array.from = (function () { var symbolIterator; try { symbolIterator = Symbol.iterator ? Symbol.iterator : 'Symbol(Symbol.iterator)'; } catch (e) { symbolIterator = 'Symbol(Symbol.iterator)'; } var toStr = Object.prototype.toString; var isCallable = function (fn) { return ( typeof fn === 'function' || toStr.call(fn) === '[object Function]' ); }; var toInteger = function (value) { var number = Number(value); if (isNaN(number)) return 0; if (number === 0 || !isFinite(number)) return number; return (number > 0 ? 1 : -1) * Math.floor(Math.abs(number)); }; var maxSafeInteger = Math.pow(2, 53) - 1; var toLength = function (value) { var len = toInteger(value); return Math.min(Math.max(len, 0), maxSafeInteger); }; var setGetItemHandler = function setGetItemHandler(isIterator, items) { var iterator = isIterator && items[symbolIterator](); return function getItem(k) { return isIterator ? iterator.next() : items[k]; }; }; var getArray = function getArray( T, A, len, getItem, isIterator, mapFn ) { // 16. Let k be 0. var k = 0; // 17. Repeat, while k < len… or while iterator is done (also steps a - h) while (k < len || isIterator) { var item = getItem(k); var kValue = isIterator ? item.value : item; if (isIterator && item.done) { return A; } else { if (mapFn) { A[k] = typeof T === 'undefined' ? mapFn(kValue, k) : mapFn.call(T, kValue, k); } else { A[k] = kValue; } } k += 1; } if (isIterator) { throw new TypeError( 'Array.from: provided arrayLike or iterator has length more then 2 ** 52 - 1' ); } else { A.length = len; } return A; }; // The length property of the from method is 1. return function from(arrayLikeOrIterator /*, mapFn, thisArg */) { // 1. Let C be the this value. var C = this; // 2. Let items be ToObject(arrayLikeOrIterator). var items = Object(arrayLikeOrIterator); var isIterator = isCallable(items[symbolIterator]); // 3. ReturnIfAbrupt(items). if (arrayLikeOrIterator == null && !isIterator) { throw new TypeError( 'Array.from requires an array-like object or iterator - not null or undefined' ); } // 4. If mapfn is undefined, then let mapping be false. var mapFn = arguments.length > 1 ? arguments[1] : void undefined; var T; if (typeof mapFn !== 'undefined') { // 5. else // 5. a If IsCallable(mapfn) is false, throw a TypeError exception. if (!isCallable(mapFn)) { throw new TypeError( 'Array.from: when provided, the second argument must be a function' ); } // 5. b. If thisArg was supplied, let T be thisArg; else let T be undefined. if (arguments.length > 2) { T = arguments[2]; } } // 10. Let lenValue be Get(items, "length"). // 11. Let len be ToLength(lenValue). var len = toLength(items.length); // 13. If IsConstructor(C) is true, then // 13. a. Let A be the result of calling the [[Construct]] internal method // of C with an argument list containing the single item len. // 14. a. Else, Let A be ArrayCreate(len). var A = isCallable(C) ? Object(new C(len)) : new Array(len); return getArray( T, A, len, setGetItemHandler(isIterator, items), isIterator, mapFn ); }; })(); }

Examples

Array from a String

Array.from('foo'); // [ "f", "o", "o" ]

Array from a Set

const set = new Set(['foo', 'bar', 'baz', 'foo']); Array.from(set); // [ "foo", "bar", "baz" ]

Array from a Map

const map = new Map([[1, 2], [2, 4], [4, 8]]); Array.from(map); // [[1, 2], [2, 4], [4, 8]] const mapper = new Map([['1', 'a'], ['2', 'b']]); Array.from(mapper.values()); // ['a', 'b']; Array.from(mapper.keys()); // ['1', '2'];

Array from an Array-like object (arguments)

function f() { return Array.from(arguments); } f(1, 2, 3); // [ 1, 2, 3 ]

Using arrow functions and Array.from()

// Using an arrow function as the map function to // manipulate the elements Array.from([1, 2, 3], x => x + x); // [2, 4, 6] // Generate a sequence of numbers // Since the array is initialized with `undefined` on each position, // the value of `v` below will be `undefined` Array.from({length: 5}, (v, i) => i); // [0, 1, 2, 3, 4]

Sequence generator (range)

// Sequence generator function (commonly referred to as "range", e.g. Clojure, PHP etc) const range = (start, stop, step) => Array.from({ length: (stop - start) / step + 1}, (_, i) => start + (i * step)); // Generate numbers range 0..4 range(0, 4, 1); // [0, 1, 2, 3, 4] // Generate numbers range 1..10 with step of 2 range(1, 10, 2); // [1, 3, 5, 7, 9] // Generate the alphabet using Array.from making use of it being ordered as a sequence range('A'.charCodeAt(0), 'Z'.charCodeAt(0), 1).map(x => String.fromCharCode(x)); // ["A", "B", "C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", "N", "O", "P", "Q", "R", "S", "T", "U", "V", "W", "X", "Y", "Z"]

Specifications

Specification Initial publication ECMAScript (ECMA-262)

The definition of 'Array.from' in that specification. ECMAScript 2015

Browser compatibility

The compatibility table in this page is generated from structured data. If you'd like to contribute to the data, please check out https://github.com/mdn/browser-compat-data and send us a pull request.

Update compatibility data on GitHub Desktop Mobile Server Chrome Edge Firefox Internet Explorer Opera Safari Android webview Chrome for Android Firefox for Android Opera for Android Safari on iOS Samsung Internet Node.js from Chrome Full support 45 Edge Full support 12 Firefox Full support 32 IE No support No Opera Full support 32 Safari Full support 9 WebView Android Full support 45 Chrome Android Full support 45 Firefox Android Full support 32 Opera Android Full support 32 Safari iOS Full support 9 Samsung Internet Android Full support 5.0 nodejs Full support 4.0.0 Legend Full support Full support No support No support

See also