What's the difference between
var A = function () {
this.x = function () {
//do something
};
};
and
var A = function () { };
A.prototype.x = function () {
//do something
};
The examples have very different outcomes.
Before looking at the differences, the following should be noted:
A constructor's prototype provides a way to share methods and values among instances via the instance's private [[Prototype]] property.
A function's this is set by how the function is called or by the use of bind (not discussed here). Where a function is called on an object (e.g. myObj.method()) then this within the method references the object. Where this is not set by the call or by the use of bind, it defaults to the global object (window in a browser) or in strict mode, remains undefined.
JavaScript is an object-oriented language, i.e. most values are objects, including functions. (Strings, numbers, and booleans are not objects.)
So here are the snippets in question:
var A = function () {
this.x = function () {
//do something
};
};
In this case, variable A is assigned a value that is a reference to a function. When that function is called using A(), the function's this isn't set by the call so it defaults to the global object and the expression this.x is effective window.x. The result is that a reference to the function expression on the right-hand side is assigned to window.x.
In the case of:
var A = function () { };
A.prototype.x = function () {
//do something
};
something very different occurs. In the first line, variable A is assigned a reference to a function. In JavaScript, all functions objects have a prototype property by default so there is no separate code to create an A.prototype object.
In the second line, A.prototype.x is assigned a reference to a function. This will create an x property if it doesn't exist, or assign a new value if it does. So the difference with the first example in which object's x property is involved in the expression.
Another example is below. It's similar to the first one (and maybe what you meant to ask about):
var A = new function () {
this.x = function () {
//do something
};
};
In this example, the new operator has been added before the function expression so that the function is called as a constructor. When called with new, the function's this is set to reference a new Object whose private [[Prototype]] property is set to reference the constructor's public prototype. So in the assignment statement, the x property will be created on this new object. When called as a constructor, a function returns its this object by default, so there is no need for a separate return this; statement.
To check that A has an x property:
console.log(A.x) // function () {
// //do something
// };
This is an uncommon use of new since the only way to reference the constructor is via A.constructor. It would be much more common to do:
var A = function () {
this.x = function () {
//do something
};
};
var a = new A();
Another way of achieving a similar result is to use an immediately invoked function expression:
var A = (function () {
this.x = function () {
//do something
};
}());
In this case, A assigned the return value of calling the function on the right-hand side. Here again, since this is not set in the call, it will reference the global object and this.x is effective window.x. Since the function doesn't return anything, A will have a value of undefined.
These differences between the two approaches also manifest if you're serializing and de-serializing your Javascript objects to/from JSON. Methods defined on an object's prototype are not serialized when you serialize the object, which can be convenient when for example you want to serialize just the data portions of an object, but not it's methods:
var A = function () {
this.objectsOwnProperties = "are serialized";
};
A.prototype.prototypeProperties = "are NOT serialized";
var instance = new A();
console.log(instance.prototypeProperties); // "are NOT serialized"
console.log(JSON.stringify(instance));
// {"objectsOwnProperties":"are serialized"}
Related questions:
What does it mean that JavaScript is a prototypal language?
What is the scope of a function in JavaScript?
How does the "this" keyword work?
Sidenote: There may not be any significant memory savings between the two approaches, however using the prototype to share methods and properties will likely use less memory than each instance having its own copy.
JavaScript isn't a low-level language. It may not be very valuable to think of prototyping or other inheritance patterns as a way to explicitly change the way memory is allocated.
As others have said the first version, using "this" results in every instance of the class A having its own independent copy of function method "x". Whereas using "prototype" will mean that each instance of class A will use the same copy of method "x".
Here is some code to show this subtle difference:
// x is a method assigned to the object using "this"
var A = function () {
this.x = function () { alert('A'); };
};
A.prototype.updateX = function( value ) {
this.x = function() { alert( value ); }
};
var a1 = new A();
var a2 = new A();
a1.x(); // Displays 'A'
a2.x(); // Also displays 'A'
a1.updateX('Z');
a1.x(); // Displays 'Z'
a2.x(); // Still displays 'A'
// Here x is a method assigned to the object using "prototype"
var B = function () { };
B.prototype.x = function () { alert('B'); };
B.prototype.updateX = function( value ) {
B.prototype.x = function() { alert( value ); }
}
var b1 = new B();
var b2 = new B();
b1.x(); // Displays 'B'
b2.x(); // Also displays 'B'
b1.updateX('Y');
b1.x(); // Displays 'Y'
b2.x(); // Also displays 'Y' because by using prototype we have changed it for all instances
As others have mentioned, there are various reasons to choose one method or the other. My sample is just meant to clearly demonstrate the difference.
Take these 2 examples:
var A = function() { this.hey = function() { alert('from A') } };
vs.
var A = function() {}
A.prototype.hey = function() { alert('from prototype') };
Most people here (especially the top-rated answers) tried to explain how they are different without explaining WHY. I think this is wrong and if you understand the fundamentals first, the difference will become obvious. Let's try to explain the fundamentals first...
a) A function is an object in JavaScript. EVERY object in JavaScript gets an internal property (meaning, you can't access it like other properties, except maybe in browsers like Chrome), often referred to as __proto__ (you can actually type anyObject.__proto__ in Chrome to see what it references. This is just that, a property, nothing more. A property in JavaScript = a variable inside an object, nothing more. What do variables do? They point to things.
So what does this __proto__ property points to? Well, usually another object (we'll explain why later). The only way to force JavaScript for the __proto__ property to NOT point to another object is to use var newObj = Object.create(null). Even if you do this, the __proto__ property STILL exists as a property of the object, just it doesn't point to another object, it points to null.
Here's where most people get confused:
When you create a new function in JavaScript (which is an object as well, remember?), the moment it is defined, JavaScript automatically creates a new property on that function called prototype. Try it:
var A = [];
A.prototype // undefined
A = function() {}
A.prototype // {} // got created when function() {} was defined
A.prototype is TOTALLY DIFFERENT from the __proto__ property. In our example, 'A' now has TWO properties called 'prototype' and __proto__ . This is a big confusion for people. prototype and __proto__ properties are in no way related, they're separate things pointing to separate values.
You may wonder: Why does JavaScript has __proto__ property created on every single object? Well, one word: delegation. When you call a property on an object and the object doesn't have it, then JavaScript looks for the object referenced by __proto__ to see if it maybe has it. If it doesn't have it, then it looks at that object's __proto__ property and so on...until the chain ends. Thus the name prototype chain. Of course, if __proto__ doesn't point to an object and instead points to null, well tough luck, JavaScript realizes that and will return you undefined for the property.
You may also wonder, why does JavaScript creates a property called prototype for a function when you define the function? Because it tries to fool you, yes fool you that it works like class-based languages.
Let's go on with our example and create an "object" out of A:
var a1 = new A();
There's something happening in the background when this thing happened. a1 is an ordinary variable which was assigned a new, empty object.
The fact that you used the operator new before a function invocation A() did something ADDITIONAL in the background. The new keyword created a new object which now references a1 and that object is empty. Here's what happening additionally:
We said that on each function definition there's a new property created called prototype (which you can access it, unlike with the __proto__ property) created? Well, that property is being used now.
So we're now at the point where we have a freshly baked empty a1 object. We said that all objects in JavaScript have an internal __proto__ property which points to something (a1 also has it), whether it's null or another object. What the new operator does is that it sets that __proto__ property to point to the function's prototype property. Read that again. It's basically this:
a1.__proto__ = A.prototype;
We said that A.prototype is nothing more than an empty object (unless we change it to something else before defining a1). So now basically a1.__proto__ points to the same thing A.prototype points to, which is that empty object. They both point to the same object which was created when this line happened:
A = function() {} // JS: cool. let's also create A.prototype pointing to empty {}
Now, there's another thing happening when var a1 = new A() statement is processed. Basically A() is executed and if A is something like this:
var A = function() { this.hey = function() { alert('from A') } };
All that stuff inside function() { } is going to execute. When you reach the this.hey.. line, this is changed to a1 and you get this:
a1.hey = function() { alert('from A') }
I won't cover why this changes to a1 but this is a great answer to learn more.
So to summarize, when you do var a1 = new A() there are 3 things happening in the background:
A totally new empty object is created and assigned to a1. a1 = {}
a1.__proto__ property is assigned to point at the same thing as A.prototype points to (another empty object {} )
The function A() is being executed with this set to the new, empty object created in step 1 (read the answer I referenced above as to why this changes to a1)
Now, let's try to create another object:
var a2 = new A();
Steps 1,2,3 will repeat. Do you notice something? The key word is repeat. Step 1: a2 will be a new empty object, step 2: its __proto__ property will point to the same thing A.prototype points to and most importantly, step 3: function A() is AGAIN executed, which means that a2 will get hey property containing a function. a1 and a2 have two SEPARATE properties named hey which point to 2 SEPARATE functions! We now have duplicate functions in same two different objects doing the same thing, oops...You can imagine the memory implications of this if we have 1000 objects created with new A, after all functions declarations take more memory than something like the number 2. So how do we prevent this?
Remember why the __proto__ property exists on every object? So that if you retrieve the yoMan property on a1 (which doesn't exist), its __proto__ property will be consulted, which if it's an object (and is most cases it is), it will check if it contains yoMan, and if it doesn't, it will consult that object's __proto__ etc. If it does, it will take that property value and display it to you.
So someone decided to use this fact + the fact that when you create a1, its __proto__ property points to the same (empty) object A.prototype points to and do this:
var A = function() {}
A.prototype.hey = function() { alert('from prototype') };
Cool! Now, when you create a1, it again goes through all of the 3 steps above, and in step 3, it doesn't do anything, since function A() has nothing to execute. And if we do:
a1.hey
It will see that a1 does not contain hey and it will check its __proto__ property object to see if it has it, which is the case.
With this approach we eliminate the part from step 3 where functions are duplicated on each new object creation. Instead of a1 and a2 having a separate hey property, now NONE of them has it. Which, I guess, you figured out yourself by now. That's the nice thing...if you understand __proto__ and Function.prototype, questions like these will be pretty obvious.
NOTE: Some people tend to not call the internal Prototype property as __proto__, I've used this name through the post to distinguish it clearly to the Functional.prototype property as two different things.
In most cases they are essentially the same, but the second version saves memory because there is only one instance of the function instead of a separate function for each object.
A reason to use the first form is to access "private members". For example:
var A = function () {
var private_var = ...;
this.x = function () {
return private_var;
};
this.setX = function (new_x) {
private_var = new_x;
};
};
Because of javascript's scoping rules, private_var is available to the function assigned to this.x, but not outside the object.
The first example changes the interface for that object only. The second example changes the interface for all object of that class.
The ultimate problem with using this instead of prototype is that when overriding a method, the constructor of the base class will still refer to the overridden method. Consider this:
BaseClass = function() {
var text = null;
this.setText = function(value) {
text = value + " BaseClass!";
};
this.getText = function() {
return text;
};
this.setText("Hello"); // This always calls BaseClass.setText()
};
SubClass = function() {
// setText is not overridden yet,
// so the constructor calls the superclass' method
BaseClass.call(this);
// Keeping a reference to the superclass' method
var super_setText = this.setText;
// Overriding
this.setText = function(value) {
super_setText.call(this, "SubClass says: " + value);
};
};
SubClass.prototype = new BaseClass();
var subClass = new SubClass();
console.log(subClass.getText()); // Hello BaseClass!
subClass.setText("Hello"); // setText is already overridden
console.log(subClass.getText()); // SubClass says: Hello BaseClass!
versus:
BaseClass = function() {
this.setText("Hello"); // This calls the overridden method
};
BaseClass.prototype.setText = function(value) {
this.text = value + " BaseClass!";
};
BaseClass.prototype.getText = function() {
return this.text;
};
SubClass = function() {
// setText is already overridden, so this works as expected
BaseClass.call(this);
};
SubClass.prototype = new BaseClass();
SubClass.prototype.setText = function(value) {
BaseClass.prototype.setText.call(this, "SubClass says: " + value);
};
var subClass = new SubClass();
console.log(subClass.getText()); // SubClass says: Hello BaseClass!
If you think this is not a problem, then it depends on whether you can live without private variables, and whether you are experienced enough to know a leak when you see one. Also, having to put the constructor logic after the method definitions is inconvenient.
var A = function (param1) {
var privateVar = null; // Private variable
// Calling this.setPrivateVar(param1) here would be an error
this.setPrivateVar = function (value) {
privateVar = value;
console.log("setPrivateVar value set to: " + value);
// param1 is still here, possible memory leak
console.log("setPrivateVar has param1: " + param1);
};
// The constructor logic starts here possibly after
// many lines of code that define methods
this.setPrivateVar(param1); // This is valid
};
var a = new A(0);
// setPrivateVar value set to: 0
// setPrivateVar has param1: 0
a.setPrivateVar(1);
//setPrivateVar value set to: 1
//setPrivateVar has param1: 0
versus:
var A = function (param1) {
this.setPublicVar(param1); // This is valid
};
A.prototype.setPublicVar = function (value) {
this.publicVar = value; // No private variable
};
var a = new A(0);
a.setPublicVar(1);
console.log(a.publicVar); // 1
Every object is linked to a prototype object. When trying to access a property that does not exist, JavaScript will look in the object's prototype object for that property and return it if it exists.
The prototype property of a function constructor refers to the prototype object of all instances created with that function when using new.
In your first example, you are adding a property x to each instance created with the A function.
var A = function () {
this.x = function () {
//do something
};
};
var a = new A(); // constructor function gets executed
// newly created object gets an 'x' property
// which is a function
a.x(); // and can be called like this
In the second example you are adding a property to the prototype object that all the instances created with A point to.
var A = function () { };
A.prototype.x = function () {
//do something
};
var a = new A(); // constructor function gets executed
// which does nothing in this example
a.x(); // you are trying to access the 'x' property of an instance of 'A'
// which does not exist
// so JavaScript looks for that property in the prototype object
// that was defined using the 'prototype' property of the constructor
In conclusion, in the first example a copy of the function is assigned to each instance. In the second example a single copy of the function is shared by all instances.
What's the difference? => A lot.
I think, the this version is used to enable encapsulation, i.e. data hiding.
It helps to manipulate private variables.
Let us look at the following example:
var AdultPerson = function() {
var age;
this.setAge = function(val) {
// some housekeeping
age = val >= 18 && val;
};
this.getAge = function() {
return age;
};
this.isValid = function() {
return !!age;
};
};
Now, the prototype structure can be applied as following:
Different adults have different ages, but all of the adults get the same rights.
So, we add it using prototype, rather than this.
AdultPerson.prototype.getRights = function() {
// Should be valid
return this.isValid() && ['Booze', 'Drive'];
};
Lets look at the implementation now.
var p1 = new AdultPerson;
p1.setAge(12); // ( age = false )
console.log(p1.getRights()); // false ( Kid alert! )
p1.setAge(19); // ( age = 19 )
console.log(p1.getRights()); // ['Booze', 'Drive'] ( Welcome AdultPerson )
var p2 = new AdultPerson;
p2.setAge(45);
console.log(p2.getRights()); // The same getRights() method, *** not a new copy of it ***
Hope this helps.
I know this has been answered to death but I'd like to show an actual example of speed differences.
Function directly on object:
function ExampleFn() {
this.print = function() {
console.log("Calling print! ");
}
}
var objects = [];
console.time('x');
for (let i = 0; i < 2000000; i++) {
objects.push(new ExampleFn());
}
console.timeEnd('x');
//x: 1151.960693359375ms
Function on prototype:
function ExampleFn() {
}
ExampleFn.prototype.print = function() {
console.log("Calling print!");
}
var objects = [];
console.time('y');
for (let i = 0; i < 2000000; i++) {
objects.push(new ExampleFn());
}
console.timeEnd('y');
//x: 617.866943359375ms
Here we're creating 2,000,000 new objects with a print method in Chrome. We're storing every object in an array. Putting print on the prototype takes about 1/2 as long.
Prototype is the template of the class; which applies to all future instances of it. Whereas this is the particular instance of the object.
Let me give you a more comprehensive answer that I learned during a JavaScript training course.
Most answers mentioned the difference already, i.e. when prototyping the function is shared with all (future) instances. Whereas declaring the function in the class will create a copy for each instance.
In general there is no right or wrong, it's more a matter of taste or a design decision depending on your requirements. The prototype however is the technique that is used to develop in an object oriented manner, as I hope you'll see at the end of this answer.
You showed two patterns in your question. I will try to explain two more and try to explain the differences if relevant. Feel free to edit/extend.
In all examples it is about a car object that has a location and can move.
Object Decorator pattern
Not sure if this pattern is still relevant nowadays, but it exists. And it is good to know about it.
You simply pass an object and a property to the decorator function. The decorator returns the object with property and method.
var carlike = function(obj, loc) {
obj.loc = loc;
obj.move = function() {
obj.loc++;
};
return obj;
};
var amy = carlike({}, 1);
amy.move();
var ben = carlike({}, 9);
ben.move();
Functional Classes
A function in JavaScript is a specialised object. In addition to being invoked, a function can store properties like any other object.
In this case Car is a function (also think object) that can be invoked as you are used to do. It has a property methods (which is an object with a move function). When Car is invoked the extend function is called, which does some magic, and extends the Car function (think object) with the methods defined within methods.
This example, though different, comes closest to the first example in the question.
var Car = function(loc) {
var obj = {loc: loc};
extend(obj, Car.methods);
return obj;
};
Car.methods = {
move : function() {
this.loc++;
}
};
var amy = Car(1);
amy.move();
var ben = Car(9);
ben.move();
Prototypal Classes
The first two patterns allow a discussion of using techniques to define shared methods or using methods that are defined inline in the body of the constructor. In both cases every instance has its own move function.
The prototypal pattern does not lend itself well to the same examination, because function sharing via a prototype delegation is the very goal for the prototypal pattern. As others pointed out, it is expected to have a better memory footprint.
However there is one point interesting to know:
Every prototype object has has a convenience property constructor, which points back to the function (think object) it came attached to.
Concerning the last three lines:
In this example Car links to the prototype object, which links via constructor to Car itself, i.e. Car.prototype.constructor is Car itself. This allows you to figure out which constructor function built a certain object.
amy.constructor's lookup fails and thus is delegated to Car.prototype, which does have the constructor property. And so amy.constructor is Car.
Furthermore, amy is an instanceof Car. The instanceof operator works by seeing if the right operand's prototype object (Car) can be found anywhere in the left operand's prototype (amy) chain.
var Car = function(loc) {
var obj = Object.create(Car.prototype);
obj.loc = loc;
return obj;
};
Car.prototype.move = function() {
this.loc++;
};
var amy = Car(1);
amy.move();
var ben = Car(9);
ben.move();
console.log(Car.prototype.constructor);
console.log(amy.constructor);
console.log(amy instanceof Car);
Some developers can be confused in the beginning. See below example:
var Dog = function() {
return {legs: 4, bark: alert};
};
var fido = Dog();
console.log(fido instanceof Dog);
The instanceof operator returns false, because Dog's prototype cannot be found anywhere in fido's prototype chain. fido is a simple object that is created with an object literal, i.e. it just delegates to Object.prototype.
Pseudoclassical patterns
This is really just another form of the prototypal pattern in simplified form and more familiar to do those who program in Java for example, since it uses the new constructor.
It does the same as in the prototypal pattern really, it is just syntactic sugar overtop of the prototypal pattern.
However, the primary difference is that there are optimizations implemented in JavaScript engines that only apply when using the pseudoclassical pattern. Think of the pseudoclassical pattern a probably faster version of the prototypal pattern; the object relations in both examples are the same.
var Car = function(loc) {
this.loc = loc;
};
Car.prototype.move = function() {
this.loc++;
};
var amy = new Car(1);
amy.move();
var ben = new Car(9);
ben.move();
Finally, it should not be too difficult to realize how object oriented programming can be done. There are two sections.
One section that defines common properties/methods in the prototype (chain).
And another section where you put the definitions that distinguish the objects from each other (loc variable in the examples).
This is what allows us to apply concepts like superclass or subclass in JavaScript.
Feel free to add or edit. Once more complete I could make this a community wiki maybe.
I believe that #Matthew Crumley is right. They are functionally, if not structurally, equivalent. If you use Firebug to look at the objects that are created using new, you can see that they are the same. However, my preference would be the following. I'm guessing that it just seems more like what I'm used to in C#/Java. That is, define the class, define the fields, constructor, and methods.
var A = function() {};
A.prototype = {
_instance_var: 0,
initialize: function(v) { this._instance_var = v; },
x: function() { alert(this._instance_var); }
};
EDIT Didn't mean to imply that the scope of the variable was private, I was just trying to illustrate how I define my classes in javascript. Variable name has been changed to reflect this.
As discussed in other answers, it's really a performance consideration because the function in the prototype is shared with all of the instantiations - rather than the function being created for each instantiation.
I put together a jsperf to show this. There is a dramatic difference in the time it takes to instantiate the class, although it is really only relevant if you are making many instances.
http://jsperf.com/functions-in-constructor-vs-prototype
Think about statically typed language, things on prototype are static and things on this are instance related.
When you use prototype, the function will only be loaded only once into memory (independently on the amount of objects you create) and you can override the function whenever you want.
It is my understanding that when you change the function prototype of a function to point to a different object the constructor of the new prototype will point to the new object's prototype constructor.
From https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Operators/new:
When the code new Foo(...) is executed, the following things happen:
1) A new object is created, inheriting from Foo.prototype.
2) The constructor function Foo is called with the specified arguments,
and with this bound to the newly created object. new Foo is equivalent
to new Foo(), i.e. if no argument list is specified, Foo is called
without arguments.
3) The object returned by the constructor function becomes the result of
the whole new expression. If the constructor function doesn't
explicitly return an object, the object created in step 1 is used
instead. (Normally constructors don't return a value, but they can
choose to do so if they want to override the normal object creation
process.)
Furthermore, from https://developer.mozilla.org/en-US/docs/Learn/JavaScript/Objects/Inheritance:
We need to do one more thing before we move on. After adding the last
line, Teacher.prototype's constructor property is now equal to
Person(), because we just set Teacher.prototype to reference an object
that inherits its properties from Person.prototype! Try saving your
code, loading the page in a browser, and entering
Teacher.prototype.constructor into the console to verify.
In my example below customPrototype inherits its properties from Object.prototype as far as I can tell and so once I reassign Person.prototype to that it should change the constructor as well. And logging it I see that the constructor does change!
// Some custom object to inherit
var customPrototype = {
name: "XYZ"
};
// Person has its prototype object pointing to Object.prototype
var Person = function() {
this.name = "Not XYZ";
};
// Prints function() {this.name = "Not XYZ";}
console.log(Person.prototype.constructor);
// Change Person prototype to point to the custom prototype object
Person.prototype = customPrototype;
// Prints function Object() { [native code] }
console.log(Person.prototype.constructor);
var p = new Person();
// Prints Not XYZ
console.log(p.name);
Given the example above I expected the last name to print XYZ because nothing would be overwritten from the customPrototype object.
What am I missing? Why does it still call the Person function when (I think) it should be calling the Object.prototype.constructor?
Prototype.constructor have nothing to do with object initialization. When you want to create an object, you call new Person(), which actually calls the Person function, passes the object as the context (this) into the function and returns that object. Person function is called, no matter what prototype you have for it. And because in this function you have a property name set to Not XYZ, it will have that value. It shadows the prototype property with the same name. If you will delete this property from the object and try to again access name, you will get the prototypes one.
var customPrototype = {
name: "XYZ"
};
var Person = function() {
this.name = "Not XYZ";
};
Person.prototype = customPrototype;
var p = new Person();
console.log(p.name);
delete p.name;
console.log(p.name);
We set the prototype.constructor to keep the precise construction of the object and if we want to have some checkings based on which type of the object is.
Implementing copy logic for the objects of the type Person.
function Person(name) {
this.name = name;
};
Person.prototype.copy = function() {
return new this.constructor(this.name); // Access by `constructor` property, it is not necessary to call directly `Person`
}
const person = new Person('Bob');
console.log(person.name);
const secondPerson = person.copy();
console.log(secondPerson.name);
console.log(person === secondPerson);
First of all, this question is really similar to several others on this site. I have read them, but still have questions
These two helped, but didn't get me all the way:
How does proto differ from constructor.prototype?
_proto__ VS. prototype in JavaScript
I have this basic setup of a javascript framework/library:
(function(global){
var TMath = function() {
return new TMath.init();
}
TMath.prototype = {
add: function(a, b) {
return a+b;
}
};
TMath.init = function(){};
TMath.init.prototype = TMath.prototype;
global.TMath = global.$$ = TMath;
})(window);
When I run it like so:
var test = $$()
console.log(test);
I see the following in my console:
What I don't understand is:
If I console.log out test.__proto__, I get Object{}.
Shouldn't I get TMath.Init.prototype, since that's the function constructor my test instance was created with?
Here is an example where this does happen:
function Person(name){
this.dob = dob
};
var person = new Person("name");
console.log(person.__proto__);
This outputs Person{}, and not Object{}
Let's walk through your code piece by piece and see what we end up with.
In the following image(s), this is the nomenclature:
Elipse = function
Rectangle = object
Arrow = property
p = .prototype
c = .constructor
P = .__proto__ or [[Prototype]]
All anonymous items are empty shapes and all named items contain the name
1) Create a function TMath
When a function is created, JS engine also creates an anonymous object and binds the two using .prototype and .constructor properties as follows:
function foo(){}
/* performed by JS engine */
// foo.prototype = {};
// foo.prototype.constructor = foo;
var TMath = function() {
return new TMath.init();
}
2) Replace a function's prototype with another object
We are re-assigning the link TMath.prototype, so that it now points to the new object.
This new object also has an anonymous function in it, referenced by .add().
And the said function comes with its own default .prototype object.
TMath.prototype = {
add: function(a, b) {
return a+b;
}
};
3) Add a property to an object or a function
This one is simple.
Just add a new link to the object/function to which the new property is added.
In our case, the link is .init() and the property is an anonymous function.
TMath.init = function(){};
4) Replace a function's prototype with another object
Just like step 2, we re-assign the link TMath.prototype.
But rather than creating a new object, we point it to an existing object.
TMath.init.prototype = TMath.prototype;
Let's clear up the drawings a bit.
5) instantiation
Still with me?
Good! Becaue this is where the magic happens.
When you do var test = $$(), you are actually doing var test = TMath(), which is just var test = new TMath.init()
We can even say that this is the exact same as
var test = new <function referenced by TMath.init>().
When using new while invoking the function, the following rule applies:
If new is used in assignment, the returned object is provided with the property .__proto__
(or [[Prototype]]), which is a reference to the object referenced by
constructor-function's .prototype
Therefore, the created object (in this case test) has a property __proto__ that points to the TMath.init.prototype.
And you can confirm all this by doing the following:
console.log(test.__proto__ === TMath.init.prototype) // true
console.log(test.__proto__ === TMath.prototype) // true
Conclusion
Indeed what you originally thought is correct
If I console.log out test.\_\_proto\_\_, I get Object{}.
Shouldn't I get TMath.Init.prototype, since that's the function constructor my test instance was created with?
To gain command over these core concepts of JS, I highly recommend reading http://www.javascripttutorial.net/javascript-prototype/
function Person(firstName, lastName, age)
{
this.firstName = firstName;
this.lastName = lastName;
this.age = age;
}
var family = {};
family.mother = new Person("Susan", "Doyle", 32);
…
Do we have to use "this" here? and why?
function …
{
firstName = firstName;
lastName = lastName;
age = age;
}
I wonder if this question is too simple …
in javascript the this word is a reference to the object of invocation.
So if we have a global function
function () {console.log(this);} // Window
We get the global object or window.
if we have a deeper function in an object
var obj = {f: function (){console.log(this);}};
obj.f(); // Object {f: function} we get the object that wraps the function.
This rule is broken if we use the apply invocation pattern
obj.f.apply(window); // window is now bound to this.
In your example if you were to just call
Person(); // in global scope
you would effectively be assigning
window.firstName = // ...
window.lastName = // ...
window.age = //...
Because the this keyword is bound to the window object when called from global scope
You basically created a Constructor that should be called with the new operator. The new operator wraps your function with one that creates an object and calls your function using the apply method with the object as the this parameter.
var bob = Person("bob"); // bob is undefined but you changed the window object
var sue = new Person("sue"); // sue is an object like you expect.
Examine your code
var family = {}; // make an object
family.mother = new Person("Susan", "Doyle", 32);
because you used new before you function executes js makes a new object for you and uses the apply pattern to that object. This is what happens under the hood
family.mother = {};
Person.apply(family.mother, ["Susan", "Doyle", 32]);
Here this is required to referring the current object's value.
If you don't use the this keyword the local variables get shadowed down by function parameter.
In your Person() function scope - the function parameter get higher priority than the local variable. That means inside your Person() function the by default the firstName is considered as the function parameter even though there is some field by the same name. In this case to reference the field the this keyword is used.
This is the correct way to define an object constructor. you can get reference here
The this Keyword
In JavaScript, the thing called this, is the object that "owns" the JavaScript code.
The value of this, when used in a function, is the object that "owns" the function.
The value of this, when used in an object, is the object itself.
The this keyword in an object constructor does not have a value. It is only a substitute for the new object.
The value of this will become the new object when the constructor is used to create an object.
Note that this is not a variable. It is a keyword. You cannot change the value of this.
What's difference of this in the following two cases?
Case 1
var Person = function() { this.name="Allen Kim" }
Person.name; //undefined
Case 2
var Person = function() { this.name="Allen Kim" }
var me = new Person();
me.name // Allen Kim
Just wanted to understand how this scope works on both cases.
Every function in JavaScript is itself an object. So Person.name retrieves the name property from the function itself, which was never set; hence undefined.
You can try this my setting it directly:
Person.name = "John";
Person.name; // "John"
When assigning a property from within the constructor via
this.name = "Allen Kim";
you're setting the property on that instance. When you then instantiate an object with:
var me = new Person();
your constructor will add the name property to me, since this referes to the object being created.
Here are the basic steps taken by the JavaScript engine when calling a constructor function with the new keyword:
Calls the constructor with this set to a new clean object.
Sets the internal [[Prototype]] property of your new object to the constructor's prototype (which, in some implementations, is then available through __proto__).
Sets up the constructor property of your new object as a reference to the constructor function (so instead of the non-standard me.__proto__, you could access the prototype via me.constructor.prototype).
Returns said object.
Note that this is a very basic explanation. There are many other things not included here, but this should give you the gist of it.
On the first case you are looking for a static property on the function itself.
The second case you are returning an instance of an object that has the property by calling a constructor function. Its not really a matter of scope.
var Person = function() { this.name="Allen Kim" }
Person.name; //undefined due to the fact that there is no Person object.
var Person = function() { this.name="Allen Kim" }
var me = new Person();
me.name // Allen Kim --> Person `me`'s name