I volontari di MDN non hanno ancora tradotto questo articolo in Italiano. Registrati per tradurlo tu.
A couple of additions to ECMAScript 2015 (ES6) aren't new built-ins or syntax, but protocols. These protocols can be implemented by any object respecting some conventions.
There are two protocols: The iterable protocol and the iterator protocol.
The iterable protocol
The iterable protocol allows JavaScript objects to define or customize their iteration behavior, such as what values are looped over in a for..of
construct. Some built-in types are built-in iterables with a default iteration behavior, such as Array
or Map
, while other types (such as Object
) are not.
In order to be iterable, an object must implement the @@iterator method, meaning that the object (or one of the objects up its prototype chain) must have a property with a @@iterator key which is available via constant
:Symbol.iterator
Property | Value |
---|---|
[Symbol.iterator] |
A zero arguments function that returns an object, conforming to the iterator protocol. |
Whenever an object needs to be iterated (such as at the beginning of a for..of
loop), its @@iterator
method is called with no arguments, and the returned iterator is used to obtain the values to be iterated.
The iterator protocol
The iterator protocol defines a standard way to produce a sequence of values (either finite or infinite).
An object is an iterator when it implements a next()
method with the following semantics:
Property | Value |
---|---|
next |
A zero arguments function that returns an object with two properties:
The |
Some iterators are in turn iterables:
var someArray = [1, 5, 7]; var someArrayEntries = someArray.entries(); someArrayEntries.toString(); // "[object Array Iterator]" someArrayEntries === someArrayEntries[Symbol.iterator](); // true
Examples using the iteration protocols
A String
is an example of a built-in iterable object:
var someString = "hi"; typeof someString[Symbol.iterator]; // "function"
String
's default iterator returns the string's characters one by one:
var iterator = someString[Symbol.iterator](); iterator + ""; // "[object String Iterator]" iterator.next(); // { value: "h", done: false } iterator.next(); // { value: "i", done: false } iterator.next(); // { value: undefined, done: true }
Some built-in constructs, such as the spread operator, use the same iteration protocol under the hood:
[...someString] // ["h", "i"]
We can redefine the iteration behavior by supplying our own @@iterator
:
var someString = new String("hi"); // need to construct a String object explicitly to avoid auto-boxing someString[Symbol.iterator] = function() { return { // this is the iterator object, returning a single element, the string "bye" next: function() { if (this._first) { this._first = false; return { value: "bye", done: false }; } else { return { done: true }; } }, _first: true }; };
Notice how redefining @@iterator
affects the behavior of built-in constructs, that use the iteration protocol:
[...someString]; // ["bye"] someString + ""; // "hi"
Iterable examples
Builtin iterables
String
, Array
, TypedArray
, Map
and Set
are all built-in iterables, because the prototype objects of them all have an @@
iterator
method.
User-defined iterables
We can make our own iterables like this:
var myIterable = {}; myIterable[Symbol.iterator] = function* () { yield 1; yield 2; yield 3; }; [...myIterable]; // [1, 2, 3]
Builtin APIs accepting iterables
There are many APIs accepting iterables, for example: Map([iterable])
, WeakMap([iterable])
, Set([iterable])
and WeakSet([iterable])
:
var myObj = {}; new Map([[1,"a"],[2,"b"],[3,"c"]]).get(2); // "b" new WeakMap([[{},"a"],[myObj,"b"],[{},"c"]]).get(myObj); // "b" new Set([1, 2, 3]).has(3); // true new Set("123").has("2"); // true new WeakSet(function*() { yield {}; yield myObj; yield {}; }()).has(myObj); // true
But also Promise.all(iterable)
, Promise.race(iterable)
, and Array.from()
.
Syntaxes expecting iterables
Some statements and expressions are expecting iterables, for example the for-of
loops, spread operator, yield*
, and destructuring assignment.
for(let value of ["a", "b", "c"]){ console.log(value); } // "a" // "b" // "c" [..."abc"]; // ["a", "b", "c"] function* gen(){ yield* ["a", "b", "c"]; } gen().next(); // { value:"a", done:false } [a, b, c] = new Set(["a", "b", "c"]); a // "a"
Non-well-formed iterables
If an iterable's @@iterator
method doesn't return an iterator object, then it's a non-well-formed iterable, using it as such is likely to result in runtime exceptions or buggy behavior:
var nonWellFormedIterable = {} nonWellFormedIterable[Symbol.iterator] = () => 1 [...nonWellFormedIterable] // TypeError: [] is not a function
Iterator examples
Simple iterator
function makeIterator(array){ var nextIndex = 0; return { next: function(){ return nextIndex < array.length ? {value: array[nextIndex++], done: false} : {done: true}; } }; } var it = makeIterator(['yo', 'ya']); console.log(it.next().value); // 'yo' console.log(it.next().value); // 'ya' console.log(it.next().done); // true
Infinite iterator
function idMaker(){ var index = 0; return { next: function(){ return {value: index++, done: false}; } }; } var it = idMaker(); console.log(it.next().value); // '0' console.log(it.next().value); // '1' console.log(it.next().value); // '2' // ...
With a generator
function* makeSimpleGenerator(array){ var nextIndex = 0; while(nextIndex < array.length){ yield array[nextIndex++]; } } var gen = makeSimpleGenerator(['yo', 'ya']); console.log(gen.next().value); // 'yo' console.log(gen.next().value); // 'ya' console.log(gen.next().done); // true function* idMaker(){ var index = 0; while(true) yield index++; } var gen = idMaker(); console.log(gen.next().value); // '0' console.log(gen.next().value); // '1' console.log(gen.next().value); // '2' // ...
Is a generator object an iterator or an iterable?
A generator object is both, iterator and iterable:
var aGeneratorObject = function*(){ yield 1; yield 2; yield 3; }(); typeof aGeneratorObject.next; // "function", because it has a next method, so it's an iterator typeof aGeneratorObject[Symbol.iterator]; // "function", because it has an @@iterator method, so it's an iterable aGeneratorObject[Symbol.iterator]() === aGeneratorObject; // true, because its @@iterator method return its self (an iterator), so it's an well-formed iterable [...aGeneratorObject]; // [1, 2, 3]
Browser compatibility
Feature | Chrome | Firefox (Gecko) | Internet Explorer | Opera | Safari (WebKit) |
---|---|---|---|---|---|
Basic support | 39.0 | 27.0 (27.0) | No support | 26 | No support |
IteratorResult object instead of throwing |
(Yes) | 29.0 (29.0) | No support | (Yes) | No support |
Feature | Android | Android Webview | Firefox Mobile (Gecko) | IE Mobile | Opera Mobile | Safari Mobile | Chrome for Android |
---|---|---|---|---|---|---|---|
Basic support | No support | (Yes) | 27.0 (27.0) | No support | No support | No support | 39.0 |
IteratorResult object instead of throwing |
No support | ? | 29.0 (29.0) | No support | No support | No support | (Yes) |
Firefox-specific notes
IteratorResult
object returned instead of throwing
Starting with Gecko 29 (Firefox 29 / Thunderbird 29 / SeaMonkey 2.26), the completed generator function no longer throws a TypeError
"generator has already finished". Instead, it returns an IteratorResult
object like { value: undefined, done: true }
(bug 958951).
Iterator
property and @@iterator
symbol
From Gecko 17 (Firefox 17 / Thunderbird 17 / SeaMonkey 2.14) to Gecko 26 (Firefox 26 / Thunderbird 26 / SeaMonkey 2.23 / Firefox OS 1.2) the iterator
property was used (bug 907077), and from Gecko 27 to Gecko 35 the "@@iterator"
placeholder was used. In Gecko 36 (Firefox 36 / Thunderbird 36 / SeaMonkey 2.33), the @@iterator
symbol got implemented (bug 918828).
Specifications
Specification | Status | Comment |
---|---|---|
ECMAScript 2015 (6th Edition, ECMA-262) The definition of 'Iteration' in that specification. |
Standard | Initial definition. |
ECMAScript 2017 Draft (ECMA-262) The definition of 'Iteration' in that specification. |
Draft |
See also
- For more information on ES6 generators, see the function* documentation.