string. There are also
objects. All objects have properties.
Every lowercase-o object was created from a constructor. In the case of object literal notation, the constructor was an implicit
Object. Arrays are objects too, but rather than being created with the
Object constructor, they're created with the
Array constructor. Functions are objects too, which have the
When you see an array, you likely think of it as having numbered elements; 0, 1, 2, etc. In reality, an array is just another object, except that rather than using alphabetic property names, it uses numeric property names, and you don't use
. to access the elements.
In reality, arrays have some optimizations by browsers to make them faster than if you were using a different kind of object, but such optimizations will still retain the semantics described here.
The odd behavior with strings is because strings aren't objects, but there's some quirky boxing behavior that makes
someString.property = value not an error. Only objects can have properties and methods per se; but we all know that
someNumber.toString() is not an error. What's up there?
It turns out that in some cases, when you try to use a primitive as if it were an object, it will box up that primitive into an object. For example, when I call
someNumber.toString(), it will create an object with the
Number constructor, distinct from the primitive number. Then it looks up
toString in the normal way, executing it with
this set to the object.
When you set the property on the string, it was implicitly converted to a
String-constructor object for the purposes of that operation. It set the property on the
String object just fine; it's just that the boxing was temporary; the boxing does not persist in the variable holding the primitive string.
It's true that we rarely use
new Function, but if you do use it, it does exactly what it sounds like it does: it creates a new function. You can pass it a string, and that will be the body of the function. If you create a new function with a string body and then call it, that's not too far from
evaling code. That's why JSLint marks it as an
When you log an object to the console, developer tools will usually show you the properties since that's usually the most important part of the object. Functions usually aren't assigned custom properties, so developer tools just go with the plain string representation, which usually just shows the function arguments and body. The string representation of a function isn't that unusual in not showing properties —
toString of a plain
Object will just return
The prototype chain
Surely this information clarifies many things, but it still doesn't explain this:
console.log(new Array() instanceof Object); // => true
Wha? The constructor of the array is
Object! This is because of something called the prototype chain. It is what controls inheritance.
Every object has an internal property called
[[Prototype]]. There is no standard way to access it, although many browsers have a non-standard
__proto__ property to access it. When you use
new to create an object,
[[Prototype]] is set to the
prototype property of the function used to create the object.
Let's say we have an object
foo that had a constructor of
Foo. When we access a property
foo.bar, it first looks up
foo's own properties. If it's not found there or undefined, it will look up
[[Prototype]]'s own properties. If not found there, it will look up
[[Prototype]], on and on, until it gets to a
[[Prototype]]. This is the functionality that allows inheritance.
In order to determine whether an object is an instance,
isinstance goes through the prototype chain to see if any of the
[[Prototype]]s match the
prototype of the function. It just turns out that if you traverse the prototype chain of an array, you'll hit
Object's prototype, and then
isinstance will yield
new Array() instanceof Object.
You may be interested in the annotated ECMAScript 5 specification, which defines the language, and of course covers some of the specific algorithms used in detail. It won't lay everything out for you; some very insightful things are not explicitly described, but require piecing several bits together on your own. For that reason, you probably don't want to read it straight through unless you're trying to implement it yourself, but rather reference sections of it whenever there's some behavior you're curious about.