- Learn ES2015
- Introduction
- ECMAScript 2015 Features
- Arrows and Lexical This
- Classes
- Enhanced Object Literals
- Template Strings
- Destructuring
- Default + Rest + Spread
- Let + Const
- Iterators + For..Of
- Generators
- Comprehensions
- Unicode
- Modules
- Module Loaders
- Map + Set + WeakMap + WeakSet
- Proxies
- Symbols
- Subclassable Built-ins
- Math + Number + String + Object APIs
- Binary and Octal Literals
- Promises
- Reflect API
- Tail Calls
Learn ES2015
es6features
This document was originally taken from Luke Hoban’s excellent es6features repo. Go give it a star on GitHub!
REPL
Be sure to try these features out in the online REPL.
Introduction
ECMAScript 2015 is an ECMAScript standard that was ratified in June 2015.
ES2015 is a significant update to the language, and the first major update to the language since ES5 was standardized in 2009. Implementation of these features in major JavaScript engines is underway now.
See the ES2015 standard for full specification of the ECMAScript 2015 language.
ECMAScript 2015 Features
Arrows and Lexical This
Arrows are a function shorthand using the =>
syntax. They are syntactically similar to the related feature in C#, Java 8 and CoffeeScript. They support both expression and statement bodies. Unlike functions, arrows share the same lexical this
as their surrounding code. If an arrow is inside another function, it shares the “arguments” variable of its parent function.
JavaScript
// Expression bodies
var odds = evens.map(v => v + 1);
var nums = evens.map((v, i) => v + i);
// Statement bodies
nums.forEach(v => {
if (v % 5 === 0)
fives.push(v);
});
// Lexical this
var bob = {
_name: "Bob",
_friends: [],
printFriends() {
this._friends.forEach(f =>
console.log(this._name + " knows " + f));
}
};
// Lexical arguments
function square() {
let example = () => {
let numbers = [];
for (let number of arguments) {
numbers.push(number * number);
}
return numbers;
};
return example();
}
square(2, 4, 7.5, 8, 11.5, 21); // returns: [4, 16, 56.25, 64, 132.25, 441]
Classes
ES2015 classes are syntactic sugar over the prototype-based OO pattern. Having a single convenient declarative form makes class patterns easier to use, and encourages interoperability. Classes support prototype-based inheritance, super calls, instance and static methods and constructors.
JavaScript
class SkinnedMesh extends THREE.Mesh {
constructor(geometry, materials) {
super(geometry, materials);
this.idMatrix = SkinnedMesh.defaultMatrix();
this.bones = [];
this.boneMatrices = [];
//...
}
update(camera) {
//...
super.update();
}
static defaultMatrix() {
return new THREE.Matrix4();
}
}
Enhanced Object Literals
Object literals are extended to support setting the prototype at construction, shorthand for foo: foo
assignments, defining methods and making super calls. Together, these also bring object literals and class declarations closer together, and let object-based design benefit from some of the same conveniences.
JavaScript
var obj = {
// Sets the prototype. "__proto__" or '__proto__' would also work.
__proto__: theProtoObj,
// Computed property name does not set prototype or trigger early error for
// duplicate __proto__ properties.
['__proto__']: somethingElse,
// Shorthand for ‘handler: handler’
handler,
// Methods
toString() {
// Super calls
return "d " + super.toString();
},
// Computed (dynamic) property names
[ "prop_" + (() => 42)() ]: 42
};
caution
The **proto**
property requires native support, and was deprecated in previous ECMAScript versions. Most engines now support the property, but some do not. Also, note that only web browsers are required to implement it, as it’s in Annex B. It is available in Node.
Template Strings
Template strings provide syntactic sugar for constructing strings. This is similar to string interpolation features in Perl, Python and more. Optionally, a tag can be added to allow the string construction to be customized, avoiding injection attacks or constructing higher level data structures from string contents.
JavaScript
// Basic literal string creation
`This is a pretty little template string.`
// Multiline strings
`In ES5 this is
not legal.`
// Interpolate variable bindings
var name = "Bob", time = "today";
`Hello ${name}, how are you ${time}?`
// Unescaped template strings
String.raw`In ES5 "\n" is a line-feed.`
// Construct an HTTP request prefix is used to interpret the replacements and construction
GET`http://foo.org/bar?a=${a}&b=${b}
Content-Type: application/json
X-Credentials: ${credentials}
{ "foo": ${foo},
"bar": ${bar}}`(myOnReadyStateChangeHandler);
Destructuring
Destructuring allows binding using pattern matching, with support for matching arrays and objects. Destructuring is fail-soft, similar to standard object lookup foo["bar"]
, producing undefined
values when not found.
JavaScript
// list matching
var [a, ,b] = [1,2,3];
a === 1;
b === 3;
// object matching
var { op: a, lhs: { op: b }, rhs: c }
= getASTNode()
// object matching shorthand
// binds `op`, `lhs` and `rhs` in scope
var {op, lhs, rhs} = getASTNode()
// Can be used in parameter position
function g({name: x}) {
console.log(x);
}
g({name: 5})
// Fail-soft destructuring
var [a] = [];
a === undefined;
// Fail-soft destructuring with defaults
var [a = 1] = [];
a === 1;
// Destructuring + defaults arguments
function r({x, y, w = 10, h = 10}) {
return x + y + w + h;
}
r({x:1, y:2}) === 23
Default + Rest + Spread
Callee-evaluated default parameter values. Turn an array into consecutive arguments in a function call. Bind trailing parameters to an array. Rest replaces the need for arguments
and addresses common cases more directly.
JavaScript
function f(x, y=12) {
// y is 12 if not passed (or passed as undefined)
return x + y;
}
f(3) == 15
JavaScript
function f(x, ...y) {
// y is an Array
return x * y.length;
}
f(3, "hello", true) == 6
JavaScript
function f(x, y, z) {
return x + y + z;
}
// Pass each elem of array as argument
f(...[1,2,3]) == 6
Let + Const
Block-scoped binding constructs. let
is the new var
. const
is single-assignment. Static restrictions prevent use before assignment.
JavaScript
function f() {
{
let x;
{
// this is ok since it's a block scoped name
const x = "sneaky";
// error, was just defined with `const` above
x = "foo";
}
// this is ok since it was declared with `let`
x = "bar";
// error, already declared above in this block
let x = "inner";
}
}
Iterators + For..Of
Iterator objects enable custom iteration like CLR IEnumerable or Java Iterable. Generalize for..in
to custom iterator-based iteration with for..of
. Don’t require realizing an array, enabling lazy design patterns like LINQ.
JavaScript
let fibonacci = {
[Symbol.iterator]() {
let pre = 0, cur = 1;
return {
next() {
[pre, cur] = [cur, pre + cur];
return { done: false, value: cur }
}
}
}
}
for (var n of fibonacci) {
// truncate the sequence at 1000
if (n > 1000)
break;
console.log(n);
}
Iteration is based on these duck-typed interfaces (using TypeScript type syntax for exposition only):
interface IteratorResult {
done: boolean;
value: any;
}
interface Iterator {
next(): IteratorResult;
}
interface Iterable {
[Symbol.iterator](): Iterator
}
Support via polyfill
In order to use Iterators you must include the Babel polyfill.
Generators
Generators simplify iterator-authoring using function*
and yield
. A function declared as function* returns a Generator instance. Generators are subtypes of iterators which include additional next
and throw
. These enable values to flow back into the generator, so yield
is an expression form which returns a value (or throws).
Note: Can also be used to enable ‘await’-like async programming, see also ES7 await
proposal.
JavaScript
var fibonacci = {
[Symbol.iterator]: function*() {
var pre = 0, cur = 1;
for (;;) {
var temp = pre;
pre = cur;
cur += temp;
yield cur;
}
}
}
for (var n of fibonacci) {
// truncate the sequence at 1000
if (n > 1000)
break;
console.log(n);
}
The generator interface is (using TypeScript type syntax for exposition only):
interface Generator extends Iterator {
next(value?: any): IteratorResult;
throw(exception: any);
}
Support via polyfill
In order to use Generators you must include the Babel polyfill.
Comprehensions
Removed in Babel 6.0
Unicode
Non-breaking additions to support full Unicode, including new unicode literal form in strings and new RegExp u
mode to handle code points, as well as new APIs to process strings at the 21bit code points level. These additions support building global apps in JavaScript.
JavaScript
// same as ES5.1
"𠮷".length == 2
// new RegExp behaviour, opt-in ‘u’
"𠮷".match(/./u)[0].length == 2
// new form
"\u{20BB7}" == "𠮷"
"𠮷" == "\uD842\uDFB7"
// new String ops
"𠮷".codePointAt(0) == 0x20BB7
// for-of iterates code points
for(var c of "𠮷") {
console.log(c);
}
Modules
Language-level support for modules for component definition. Codifies patterns from popular JavaScript module loaders (AMD, CommonJS). Runtime behaviour defined by a host-defined default loader. Implicitly async model – no code executes until requested modules are available and processed.
JavaScript
// lib/math.js
export function sum(x, y) {
return x + y;
}
export var pi = 3.141593;
JavaScript
// app.js
import * as math from "lib/math";
console.log("2π = " + math.sum(math.pi, math.pi));
JavaScript
// otherApp.js
import {sum, pi} from "lib/math";
console.log("2π = " + sum(pi, pi));
Some additional features include export default
and export *
:
JavaScript
// lib/mathplusplus.js
export * from "lib/math";
export var e = 2.71828182846;
export default function(x) {
return Math.exp(x);
}
JavaScript
// app.js
import exp, {pi, e} from "lib/mathplusplus";
console.log("e^π = " + exp(pi));
Module Formatters
Babel can transpile ES2015 Modules to several different formats including Common.js, AMD, System, and UMD. You can even create your own. For more details see the modules docs.
Module Loaders
Not part of ES2015
This is left as implementation-defined within the ECMAScript 2015 specification. The eventual standard will be in WHATWG’s Loader specification, but that is currently a work in progress. What is below is from a previous ES2015 draft.
Module loaders support:
- Dynamic loading
- State isolation
- Global namespace isolation
- Compilation hooks
- Nested virtualization
The default module loader can be configured, and new loaders can be constructed to evaluate and load code in isolated or constrained contexts.
JavaScript
// Dynamic loading – ‘System’ is default loader
System.import("lib/math").then(function(m) {
alert("2π = " + m.sum(m.pi, m.pi));
});
// Create execution sandboxes – new Loaders
var loader = new Loader({
global: fixup(window) // replace ‘console.log’
});
loader.eval("console.log(\"hello world!\");");
// Directly manipulate module cache
System.get("jquery");
System.set("jquery", Module({$: $})); // WARNING: not yet finalized
Additional polyfill needed
Since Babel defaults to using common.js modules, it does not include the polyfill for the module loader API. Get it here.
Using Module Loader
In order to use this, you’ll need to tell Babel to use the system
module formatter. Also be sure to check out System.js.
Map + Set + WeakMap + WeakSet
Efficient data structures for common algorithms. WeakMaps provides leak-free object-key’d side tables.
JavaScript
// Sets
var s = new Set();
s.add("hello").add("goodbye").add("hello");
s.size === 2;
s.has("hello") === true;
// Maps
var m = new Map();
m.set("hello", 42);
m.set(s, 34);
m.get(s) == 34;
// Weak Maps
var wm = new WeakMap();
wm.set(s, { extra: 42 });
wm.size === undefined
// Weak Sets
var ws = new WeakSet();
ws.add({ data: 42 });
// Because the added object has no other references, it will not be held in the set
Support via polyfill
In order to support Maps, Sets, WeakMaps, and WeakSets in all environments you must include the Babel polyfill.
Proxies
Proxies enable creation of objects with the full range of behaviors available to host objects. Can be used for interception, object virtualization, logging/profiling, etc.
JavaScript
// Proxying a normal object
var target = {};
var handler = {
get: function (receiver, name) {
return `Hello, ${name}!`;
}
};
var p = new Proxy(target, handler);
p.world === "Hello, world!";
JavaScript
// Proxying a function object
var target = function () { return "I am the target"; };
var handler = {
apply: function (receiver, ...args) {
return "I am the proxy";
}
};
var p = new Proxy(target, handler);
p() === "I am the proxy";
There are traps available for all of the runtime-level meta-operations:
JavaScript
var handler =
{
// target.prop
get: ...,
// target.prop = value
set: ...,
// 'prop' in target
has: ...,
// delete target.prop
deleteProperty: ...,
// target(...args)
apply: ...,
// new target(...args)
construct: ...,
// Object.getOwnPropertyDescriptor(target, 'prop')
getOwnPropertyDescriptor: ...,
// Object.defineProperty(target, 'prop', descriptor)
defineProperty: ...,
// Object.getPrototypeOf(target), Reflect.getPrototypeOf(target),
// target.__proto__, object.isPrototypeOf(target), object instanceof target
getPrototypeOf: ...,
// Object.setPrototypeOf(target), Reflect.setPrototypeOf(target)
setPrototypeOf: ...,
// Object.keys(target)
ownKeys: ...,
// Object.preventExtensions(target)
preventExtensions: ...,
// Object.isExtensible(target)
isExtensible :...
}
Unsupported feature
Due to the limitations of ES5, Proxies cannot be transpiled or polyfilled. See support in various JavaScript engines.
Symbols
Symbols enable access control for object state. Symbols allow properties to be keyed by either string
(as in ES5) or symbol
. Symbols are a new primitive type. Optional name
parameter used in debugging - but is not part of identity. Symbols are unique (like gensym), but not private since they are exposed via reflection features like Object.getOwnPropertySymbols
.
JavaScript
(function() {
// module scoped symbol
var key = Symbol("key");
function MyClass(privateData) {
this[key] = privateData;
}
MyClass.prototype = {
doStuff: function() {
... this[key] ...
}
};
// Limited support from Babel, full support requires native implementation.
typeof key === "symbol"
})();
var c = new MyClass("hello")
c["key"] === undefined
Limited support via polyfill
Limited support requires the Babel polyfill. Due to language limitations, some features can’t be transpiled or polyfilled. See core.js’s caveats section for more details.
Subclassable Built-ins
In ES2015, built-ins like Array
, Date
and DOM Element
s can be subclassed.
JavaScript
// User code of Array subclass
class MyArray extends Array {
constructor(...args) { super(...args); }
}
var arr = new MyArray();
arr[1] = 12;
arr.length == 2
Partial support
Built-in subclassability should be evaluated on a case-by-case basis as classes such as HTMLElement
can be subclassed while many such as Date
, Array
and Error
cannot be due to ES5 engine limitations.
Math + Number + String + Object APIs
Many new library additions, including core Math libraries, Array conversion helpers, and Object.assign for copying.
JavaScript
Number.EPSILON
Number.isInteger(Infinity) // false
Number.isNaN("NaN") // false
Math.acosh(3) // 1.762747174039086
Math.hypot(3, 4) // 5
Math.imul(Math.pow(2, 32) - 1, Math.pow(2, 32) - 2) // 2
"abcde".includes("cd") // true
"abc".repeat(3) // "abcabcabc"
Array.from(document.querySelectorAll("*")) // Returns a real Array
Array.of(1, 2, 3) // Similar to new Array(...), but without special one-arg behavior
[0, 0, 0].fill(7, 1) // [0,7,7]
[1,2,3].findIndex(x => x == 2) // 1
["a", "b", "c"].entries() // iterator [0, "a"], [1,"b"], [2,"c"]
["a", "b", "c"].keys() // iterator 0, 1, 2
["a", "b", "c"].values() // iterator "a", "b", "c"
Object.assign(Point, { origin: new Point(0,0) })
Limited support from polyfill
Most of these APIs are supported by the Babel polyfill. However, certain features are omitted for various reasons (e.g. String.prototype.normalize
needs a lot of additional code to support). You can find more polyfills here.
Binary and Octal Literals
Two new numeric literal forms are added for binary (b
) and octal (o
).
JavaScript
0b111110111 === 503 // true
0o767 === 503 // true
Only supports literal form
Babel is only able to transform 0o767
and not Number("0o767")
.
Promises
Promises are a library for asynchronous programming. Promises are a first class representation of a value that may be made available in the future. Promises are used in many existing JavaScript libraries.
JavaScript
function timeout(duration = 0) {
return new Promise((resolve, reject) => {
setTimeout(resolve, duration);
})
}
var p = timeout(1000).then(() => {
return timeout(2000);
}).then(() => {
throw new Error("hmm");
}).catch(err => {
return Promise.all([timeout(100), timeout(200)]);
})
Support via polyfill
In order to support Promises you must include the Babel polyfill.
Reflect API
Full reflection API exposing the runtime-level meta-operations on objects. This is effectively the inverse of the Proxy API, and allows making calls corresponding to the same meta-operations as the proxy traps. Especially useful for implementing proxies.
JavaScript
var O = {a: 1};
Object.defineProperty(O, 'b', {value: 2});
O[Symbol('c')] = 3;
Reflect.ownKeys(O); // ['a', 'b', Symbol(c)]
function C(a, b){
this.c = a + b;
}
var instance = Reflect.construct(C, [20, 22]);
instance.c; // 42
Support via polyfill
In order to use the Reflect API you must include the Babel polyfill.
Tail Calls
Calls in tail-position are guaranteed to not grow the stack unboundedly. Makes recursive algorithms safe in the face of unbounded inputs.
JavaScript
function factorial(n, acc = 1) {
"use strict";
if (n <= 1) return acc;
return factorial(n - 1, n * acc);
}
// Stack overflow in most implementations today,
// but safe on arbitrary inputs in ES2015
factorial(100000)
Temporarily Removed in Babel 6
Only explicit self referencing tail recursion was supported due to the complexity and performance impact of supporting tail calls globally. Removed due to other bugs and will be re-implemented.