this
A this
behaves a little differently in JavaScript compared to other languages. It also has some differences between strict mode and non-strict mode.
In most cases, the value of this
is determined by how a function is called (runtime binding). It can't be set by assignment during execution, and it may be different each time the function is called. ES5 introduced the bind()
method to set the value of a function's this
regardless of how it's called, and ES2015 introduced arrow functions which don't provide their own this
binding (it retains the this
value of the enclosing lexical context).
Syntax
this
Value
A property of an execution context (global, function or eval) that, in non–strict mode, is always a reference to an object and in strict mode can be any value.
Description
Global context
In the global execution context (outside of any function), this
refers to the global object whether in strict mode or not.
// In web browsers, the window object is also the global object: console.log(this === window); // true a = 37; console.log(window.a); // 37 this.b = "MDN"; console.log(window.b) // "MDN" console.log(b) // "MDN"
Note: You can always easily get the global object using the global globalThis
property, regardless of the current context in which your code is running.
Function context
Inside a function, the value of this
depends on how the function is called.
Since the following code is not in strict mode, and because the value of this
is not set by the call, this
will default to the global object, which is window
in a browser.
function f1() { return this; } // In a browser: f1() === window; // true // In Node: f1() === globalThis; // true
In strict mode, however, if the value of this
is not set when entering an execution context, it remains as undefined
, as shown in the following example:
function f2() { 'use strict'; // see strict mode return this; } f2() === undefined; // true
Note: In the second example, this
should be undefined
, because f2
was called directly and not as a method or property of an object (e.g. window.f2()
). This feature wasn't implemented in some browsers when they first started to support strict mode. As a result, they incorrectly returned the window
object.
To set the value of this
to a particular value when calling a function, use call()
, or apply()
as in the examples below.
Class context
The behavior of this
in classes and functions is similar, since classes are functions under the hood. But there are some differences and caveats.
Within a class constructor, this
is a regular object. All non-static methods within the class are added to the prototype of this
:
class Example { constructor() { const proto = Object.getPrototypeOf(this); console.log(Object.getOwnPropertyNames(proto)); } first(){} second(){} static third(){} } new Example(); // ['constructor', 'first', 'second']
Note: Static methods are not properties of this
. They are properties of the class itself.
Derived classes
Unlike base class constructors, derived constructors have no initial this
binding. Calling super()
creates a this
binding within the constructor and essentially has the effect of evaluating the following line of code, where Base is the inherited class:
this = new Base();
Warning: Referring to this
before calling super()
will throw an error.
Derived classes must not return before calling super()
, unless they return an Object
or have no constructor at all.
class Base {} class Good extends Base {} class AlsoGood extends Base { constructor() { return {a: 5}; } } class Bad extends Base { constructor() {} } new Good(); new AlsoGood(); new Bad(); // ReferenceError
Examples
this in function contexts
// An object can be passed as the first argument to call or apply and this will be bound to it. var obj = {a: 'Custom'}; // We declare a variable and the variable is assigned to the global window as its property. var a = 'Global'; function whatsThis() { return this.a; // The value of this is dependent on how the function is called } whatsThis(); // 'Global' as this in the function isn't set, so it defaults to the global/window object whatsThis.call(obj); // 'Custom' as this in the function is set to obj whatsThis.apply(obj); // 'Custom' as this in the function is set to obj
this and object conversion
function add(c, d) { return this.a + this.b + c + d; } var o = {a: 1, b: 3}; // The first parameter is the object to use as // 'this', subsequent parameters are passed as // arguments in the function call add.call(o, 5, 7); // 16 // The first parameter is the object to use as // 'this', the second is an array whose // members are used as the arguments in the function call add.apply(o, [10, 20]); // 34
Note that in non–strict mode, with call
and apply
, if the value passed as this
is not an object, an attempt will be made to convert it to an object. Values null
and undefined
become the global object. Primitives like 7
or 'foo'
will be converted to an Object using the related constructor, so the primitive number 7
is converted to an object as if by new Number(7)
and the string 'foo'
to an object as if by new String('foo')
, e.g.
function bar() { console.log(Object.prototype.toString.call(this)); } bar.call(7); // [object Number] bar.call('foo'); // [object String] bar.call(undefined); // [object global]
The bind
method
ECMAScript 5 introduced Function.prototype.bind()
. Calling f.bind(someObject)
creates a new function with the same body and scope as f
, but where this
occurs in the original function, in the new function it is permanently bound to the first argument of bind
, regardless of how the function is being used.
function f() { return this.a; } var g = f.bind({a: 'azerty'}); console.log(g()); // azerty var h = g.bind({a: 'yoo'}); // bind only works once! console.log(h()); // azerty var o = {a: 37, f: f, g: g, h: h}; console.log(o.a, o.f(), o.g(), o.h()); // 37,37, azerty, azerty
Arrow functions
In arrow functions, this
retains the value of the enclosing lexical context's this
. In global code, it will be set to the global object:
var globalObject = this; var foo = (() => this); console.log(foo() === globalObject); // true
Note: If this
arg is passed to call
, bind
, or apply
on invocation of an arrow function it will be ignored. You can still prepend arguments to the call, but the first argument (thisArg
) should be set to null
.
// Call as a method of an object var obj = {func: foo}; console.log(obj.func() === globalObject); // true // Attempt to set this using call console.log(foo.call(obj) === globalObject); // true // Attempt to set this using bind foo = foo.bind(obj); console.log(foo() === globalObject); // true
No matter what, foo
's this
is set to what it was when it was created (in the example above, the global object). The same applies to arrow functions created inside other functions: their this
remains that of the enclosing lexical context.
// Create obj with a method bar that returns a function that // returns its this. The returned function is created as // an arrow function, so its this is permanently bound to the // this of its enclosing function. The value of bar can be set // in the call, which in turn sets the value of the // returned function. var obj = { bar: function() { var x = (() => this); return x; } }; // Call bar as a method of obj, setting its this to obj // Assign a reference to the returned function to fn var fn = obj.bar(); // Call fn without setting this, would normally default // to the global object or undefined in strict mode console.log(fn() === obj); // true // But caution if you reference the method of obj without calling it var fn2 = obj.bar; // Calling the arrow function's this from inside the bar method() // will now return window, because it follows the this from fn2. console.log(fn2()() == window); // true
In the above, the function (call it anonymous function A) assigned to obj.bar
returns another function (call it anonymous function B) that is created as an arrow function. As a result, function B's this
is permanently set to the this
of obj.bar
(function A) when called. When the returned function (function B) is called, its this
will always be what it was set to initially. In the above code example, function B's this
is set to function A's this
which is obj
, so it remains set to obj
even when called in a manner that would normally set its this
to undefined
or the global object (or any other method as in the previous example in the global execution context).
As an object method
When a function is called as a method of an object, its this
is set to the object the method is called on.
In the following example, when o.f()
is invoked, inside the function this
is bound to the o
object.
var o = { prop: 37, f: function() { return this.prop; } }; console.log(o.f()); // 37
Note that this behavior is not at all affected by how or where the function was defined. In the previous example, we defined the function inline as the f
member during the definition of o
. However, we could have just as easily defined the function first and later attached it to o.f
. Doing so results in the same behavior:
var o = {prop: 37}; function independent() { return this.prop; } o.f = independent; console.log(o.f()); // 37
This demonstrates that it matters only that the function was invoked from the f
member of o
.
Similarly, the this
binding is only affected by the most immediate member reference. In the following example, when we invoke the function, we call it as a method g
of the object o.b
. This time during execution, this
inside the function will refer to o.b
. The fact that the object is itself a member of o
has no consequence; the most immediate reference is all that matters.
o.b = {g: independent, prop: 42}; console.log(o.b.g()); // 42
this
on the object's prototype chain
The same notion holds true for methods defined somewhere on the object's prototype chain. If the method is on an object's prototype chain, this
refers to the object the method was called on, as if the method were on the object.
var o = {f: function() { return this.a + this.b; }}; var p = Object.create(o); p.a = 1; p.b = 4; console.log(p.f()); // 5
In this example, the object assigned to the variable p
doesn't have its own f
property, it inherits it from its prototype. But it doesn't matter that the lookup for f
eventually finds a member with that name on o
; the lookup began as a reference to p.f
, so this
inside the function takes the value of the object referred to as p
. That is, since f
is called as a method of p
, its this
refers to p
. This is an interesting feature of JavaScript's prototype inheritance.
this
with a getter or setter
Again, the same notion holds true when a function is invoked from a getter or a setter. A function used as getter or setter has its this
bound to the object from which the property is being set or gotten.
function sum() { return this.a + this.b + this.c; } var o = { a: 1, b: 2, c: 3, get average() { return (this.a + this.b + this.c) / 3; } }; Object.defineProperty(o, 'sum', { get: sum, enumerable: true, configurable: true}); console.log(o.average, o.sum); // 2, 6
As a constructor
When a function is used as a constructor (with the new
keyword), its this
is bound to the new object being constructed.
Note: While the default for a constructor is to return the object referenced by this
, it can instead return some other object (if the return value isn't an object, then the this
object is returned).
/* * Constructors work like this: * * function MyConstructor(){ * // Actual function body code goes here. * // Create properties on |this| as * // desired by assigning to them. E.g., * this.fum = "nom"; * // et cetera... * * // If the function has a return statement that * // returns an object, that object will be the * // result of the |new| expression. Otherwise, * // the result of the expression is the object * // currently bound to |this| * // (i.e., the common case most usually seen). * } */ function C() { this.a = 37; } var o = new C(); console.log(o.a); // 37 function C2() { this.a = 37; return {a: 38}; } o = new C2(); console.log(o.a); // 38
In the last example (C2
), because an object was returned during construction, the new object that this
was bound to gets discarded. (This essentially makes the statement "this.a = 37;
" dead code. It's not exactly dead because it gets executed, but it can be eliminated with no outside effects.)
As a DOM event handler
When a function is used as an event handler, its this
is set to the element on which the listener is placed (some browsers do not follow this convention for listeners added dynamically with methods other than addEventListener()
).
// When called as a listener, turns the related element blue function bluify(e) { // Always true console.log(this === e.currentTarget); // true when currentTarget and target are the same object console.log(this === e.target); this.style.backgroundColor = '#A5D9F3'; } // Get a list of every element in the document var elements = document.getElementsByTagName('*'); // Add bluify as a click listener so when the // element is clicked on, it turns blue for (var i = 0; i < elements.length; i++) { elements[i].addEventListener('click', bluify, false); }
In an inline event handler
When the code is called from an inline on-event handler, its this
is set to the DOM element on which the listener is placed:
<button onclick="alert(this.tagName.toLowerCase());"> Show this </button>
The above alert shows button
. Note however that only the outer code has its this
set this way:
<button onclick="alert((function() { return this; })());"> Show inner this </button>
In this case, the inner function's this
isn't set so it returns the global/window object (i.e. the default object in non–strict mode where this
isn't set by the call).
this in classes
Just like with regular functions, the value of this
within methods depends on how they are called. Sometimes it is useful to override this behavior so that this
within classes always refers to the class instance. To achieve this, bind the class methods in the constructor:
class Car { constructor() { // Bind sayBye but not sayHi to show the difference this.sayBye = this.sayBye.bind(this); } sayHi() { console.log(`Hello from ${this.name}`); } sayBye() { console.log(`Bye from ${this.name}`); } get name() { return 'Ferrari'; } } class Bird { get name() { return 'Tweety'; } } const car = new Car(); const bird = new Bird(); // The value of 'this' in methods depends on their caller car.sayHi(); // Hello from Ferrari bird.sayHi = car.sayHi; bird.sayHi(); // Hello from Tweety // For bound methods, 'this' doesn't depend on the caller bird.sayBye = car.sayBye; bird.sayBye(); // Bye from Ferrari
Note: Classes are always strict mode code. Calling methods with an undefined this
will throw an error.
Specifications
Browser compatibility
Desktop | Mobile | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Chrome | Edge | Firefox | Internet Explorer | Opera | Safari | WebView Android | Chrome Android | Firefox for Android | Opera Android | Safari on IOS | Samsung Internet | |
this |
1 |
12 |
1 |
4 |
9.5 |
1 |
1 |
18 |
4 |
10.1 |
1 |
1.0 |
See also
- Strict mode
- Gentle explanation of 'this' keyword in JavaScript
- Getting the global context:
globalThis
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Licensed under the Creative Commons Attribution-ShareAlike License v2.5 or later.
https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Operators/this