From a personal blog post:
By default, JavaScript knows two types of scopes: global and local.
var a = 1;
function b(x) {
var c = 2;
return x * c;
}
In the above code, variable a and function b are available from anywhere in the code (that is, globally). Variable c
is only available within the b
function scope (that is, local). Most software developers won't be happy with this lack of scope flexibility, especially in large programs.
JavaScript closures help solving that issue by tying a function with a context:
function a(x) {
return function b(y) {
return x + y;
}
}
Here, function a
returns a function called b
. Since b
is defined within a
, it automatically has access to whatever is defined in a
, that is, x
in this example. This is why b
can return x
+ y
without declaring x
.
var c = a(3);
Variable c
is assigned the result of a call to a with parameter 3. That is, an instance of function b
where x
= 3. In other words, c
is now a function equivalent to:
var c = function b(y) {
return 3 + y;
}
Function b
remembers that x
= 3 in its context. Therefore:
var d = c(4);
will assign the value 3 + 4 to d
, that is 7.
Remark: If someone modifies the value of x
(say x
= 22) after the instance of function b
has been created, this will be reflected in b
too. Hence a later call to c
(4) would return 22 + 4, that is 26.
Closures can also be used to limit the scope of variables and methods declared globally:
(function () {
var f = "Some message";
alert(f);
})();
The above is a closure where the function has no name, no argument and is called immediately. The highlighted code, which declares a global variable f
, limits the scopes of f
to the closure.
Now, there is a common JavaScript caveat where closures can help:
var a = new Array();
for (var i=0; i<2; i++) {
a[i]= function(x) { return x + i ; }
}
From the above, most would assume that array a
would be initialized as follows:
a[0] = function (x) { return x + 0 ; }
a[1] = function (x) { return x + 1 ; }
a[2] = function (x) { return x + 2 ; }
In reality, this is how a is initialized, since the last value of i
in the context is 2:
a[0] = function (x) { return x + 2 ; }
a[1] = function (x) { return x + 2 ; }
a[2] = function (x) { return x + 2 ; }
The solution is:
var a = new Array();
for (var i=0; i<2; i++) {
a[i]= function(tmp) {
return function (x) { return x + tmp ; }
} (i);
}
The argument/variable tmp
holds a local copy of the changing value of i
when creating function instances.