Marionette Modules allow you to create modular encapsulated logic. They can be used to split apart large applications into multiple files, and to build individual components of your app.
A module is defined directly from an Application object. To create a module all you need to do is give it a name.
var MyApp = new Backbone.Marionette.Application();
// Creates a new module named "MyModule"
var myModule = MyApp.module("MyModule");
MyApp.MyModule; // => a new Marionette.Module object
myModule === MyApp.MyModule; // => true
Modules cannot be overwritten once they are created. Subsequent
calls to module
with the same name argument will not create
a new module, but instead return the already-created instance.
var MyApp = new Backbone.Marionette.Application();
// Instantiates a new Marionette.Module
var myModule = MyApp.module("MyModule");
// Returns the module you just created
var theSameModule = MyApp.module("MyModule");
You can provide a definition for your module when you instantiate it. Definitions can either be a callback function or an object literal.
The callback function definition will be invoked immediately on calling
the module
method.
It will receive 6 parameters, in this order:
Within the callback you can attach both private and public functions and data directly to your module.
MyApp.module("MyModule", function(MyModule, MyApp, Backbone, Marionette, $, _){
// The context of the function is also the module itself
this === MyModule; // => true
// Private Data And Functions
// --------------------------
var myData = "this is private data";
var myFunction = function(){
console.log(myData);
}
// Public Data And Functions
// -------------------------
MyModule.someData = "public data";
MyModule.someFunction = function(){
console.log(MyModule.someData);
}
});
console.log(MyApp.MyModule.someData); //=> public data
MyApp.MyModule.someFunction(); //=> public data
You can provide additional arguments to the definition function, allowing you to import 3rd party libraries and other resources that you want to have locally scoped to your module.
Pass the additional arguments after the
definition itself in the call to module
.
MyApp.module("MyModule", function(MyModule, MyApp, Backbone, Marionette, $, _, Lib1, Lib2, LibEtc){
// Lib1 === LibraryNumber1;
// Lib2 === LibraryNumber2;
// LibEtc === LibraryNumberEtc;
}, LibraryNumber1, LibraryNumber2, LibraryNumberEtc);
Sometimes a module definition can become quite long. You can split
apart the definition by making subsequent calls to the module
function.
This can used to split the definition of your module across multiple files.
MyApp.module("MyModule", function(MyModule){
MyModule.definition1 = true;
});
// The following could be in a separate file
MyApp.module("MyModule", function(MyModule){
MyModule.definition2 = true;
});
MyApp.MyModule.definition1; //=> true
MyApp.MyModule.definition2; //=> true
The object literal definition of a module allows for more flexibility than the callback method. It allows you to, for instance, specify a custom class for your module.
Through the object literal definition you can still set a definition
function through the define
property.
MyApp.module("MyModule", {
define: function(MyModule, MyApp, Backbone, Marionette, $, _) {
// Define your module here
}
});
One of the more useful features of the object literal definition is specifying a custom module class. You can make a new class using the extend function.
var CustomModule = Marionette.Module.extend({
// Custom module properties
});
MyApp.module("Foo", {
moduleClass: CustomModule,
define: function() {} // You can still use the definition function on custom modules
});
When moduleClass
is omitted Marionette will default to instantiating a new Marionette.Module
.
Modules have an initialize
function which is immediately called when the Module is invoked. You can think of the initialize
function as an extension of the constructor.
The initialize function is only available through the object literal definition of a Module.
MyApp.module("Foo", {
startWithParent: false,
initialize: function( options, moduleName, app ) {
this.someProperty = 'someValue';
},
// You can still set a define function
define: function( Foo ) {
console.log( this.someProperty ); // Logs 'someValue'
}
});
The initialize
function is passed three arguments.
MyApp.module("Foo", {
initialize: function( options, moduleName, app ) {
console.log( options.someVar ); // Logs 'someString'
},
someVar: 'someString'
});
The initialize function is distinct from the define
function. The primary difference between the two is that initialize
is on the prototype chain, whereas define
is not. What this means is that initialize
can be inherited.
var CustomModule = Marionette.Module.extend({
define: function() {}, // This is not inherited and will never be called
initialize: function() {} // This, on the other hand, will be inherited
});
Module classes can be used as an alternative to the define pattern.
The extend function of a Module is identical to the extend functions on other Backbone and Marionette classes. This allows module lifecyle events like onStart
and onStop
to be called directly.
var FooModule = Marionette.Module.extend({
startWithParent: false,
constructor: function(moduleName, app, options) {
},
initialize: function(options, moduleName, app) {
},
onStart: function(options) {
},
onStop: function(options) {
},
});
MyApp.module("Foo", FooModule);
If all of the module's functionality is defined inside its class, then the class can be passed in directly. MyApp.module("Foo", FooModule)
Sub-Modules (or 'child' Modules) can be defined in a single call by passing a period-separated list of Modules to be created.
MyApp.module("Parent.Child.GrandChild");
MyApp.Parent; // => a valid module object
MyApp.Parent.Child; // => a valid module object
MyApp.Parent.Child.GrandChild; // => a valid module object
When defining sub-modules using the dot-notation, the parent modules do not need to exist; they'll be created for you. If a parent has already been instantiated then that instance will be used.
Modules can be started and stopped independently of the application and of each other. This allows them to be loaded asynchronously, and also allows them to be shut down when they are no longer needed.
This also facilitates unit testing of modules as you can start only the module that you need in your tests.
Modules will, by default, start with the parent application. They also have a
.start
function that can be used to start a stopped module, or a module that's
been configured to start independently from its parent.
In this example, the module will exhibit the default behavior and start automatically
with the parent application object's start
call:
MyApp = new Backbone.Marionette.Application();
MyApp.module("Foo", function(){
// module code goes here
});
MyApp.start();
Note that modules loaded after the MyApp.start()
call will be
immediately started.
Modules, like Application
objects, can be configured to have initializers. And just like
an Application's initializers, module's initializers are run anytime that
the module is started. Further, there is no limit to the number of initializers it can have.
Initializers can be added in the module's definition function.
MyApp.module("Foo", function(Foo){
Foo.addInitializer(function(){
// Do things once the module has started
});
Foo.addInitializer(function(){
// You can have more than one initializer
});
});
When starting a module, a "before:start" event will be triggered prior to any of the initializers being run. A "start" event will then be triggered after they have been run.
var mod = MyApp.module("MyMod");
mod.on("before:start", function(){
// do stuff before the module is started
});
mod.on("start", function(){
// do stuff after the module has been started
});
.start
takes a single options
parameter that will be passed to start events and their equivalent methods (onStart
and onBeforeStart
.)
var mod = MyApp.module("MyMod");
mod.on("before:start", function(options){
// do stuff before the module is started
});
mod.on("start", function(options){
// do stuff after the module has been started
});
var options = {
// any data
};
mod.start(options);
The default behavior of modules is that they start with the application.
If you wish to manually start a module instead, you can change this behavior
with the startWithParent
property.
var fooModule = MyApp.module("Foo", function(){
// prevent starting with parent
this.startWithParent = false;
// ... module code goes here
});
// start the app without starting the module
MyApp.start();
// later, start the module
fooModule.start();
The same behavior can be accomplished with the object literal definition:
var fooModule = MyApp.module("Foo", {
startWithParent: false
});
When splitting a module across multiple files, it is recommended that you set
startWithParent
to be false.
As you might expect, submodules default to starting with their parent module.
The starting of sub-modules is done in a depth-first hierarchy traversal.
That is, a hierarchy of Foo.Bar.Baz
will start Baz
first, then Bar
,
and finally Foo
.
MyApp.module("Foo", function(){...});
MyApp.module("Foo.Bar", function(){...});
MyApp.start();
In this example, the "Foo.Bar" module will be started with the call to
MyApp.start()
because the parent module, "Foo" is (by default) set to start
with the app.
A sub-module can override this behavior by setting its startWithParent
to false. This prevents it from being started by the parent's start
call.
MyApp.module("Foo", function(){...});
MyApp.module("Foo.Bar", function(){
this.startWithParent = false;
})
MyApp.start();
Now the module "Foo" will be started, but the sub-module "Foo.Bar" will not be started.
A sub-module can still be started manually, with this configuration:
MyApp.module("Foo.Bar").start();
A module can be stopped, or shut down, to clear memory and resources when
the module is no longer needed. Like the starting of modules, stopping is done
in a depth-first hierarchy traversal. That is, a hierarchy of modules like
Foo.Bar.Baz
will stop Baz
first, then Bar
, and finally Foo
.
To stop a module and its children, call the stop
method of a module.
MyApp.module("Foo").stop();
Modules are not automatically stopped by the application. If you wish to
stop one you must call the stop
method on it, or stop its parent module.
When you stop any parent module, all of its children will be stopped as well.
MyApp.module("Foo.Bar.Baz");
MyApp.module("Foo").stop();
This call to stop
causes the Bar
and Baz
modules to both be stopped
as they are sub-modules of Foo
. For more information on defining
sub-modules, see the section "Defining Sub-Modules".
Modules also have finalizers that work in an opposite manner to
initializers: they are called whenever a module is stopped via the stop
method.
You can have as many finalizers as you'd like.
MyApp.module("Foo", function(Foo){
Foo.addFinalizer(function(){
// Tear down, shut down and clean up the module in here
});
Foo.addFinalizer(function(){
// Do more things
});
});
When stopping a module, a "before:stop" event will be triggered prior to any of the finalizers being run. A "stop" event will then be triggered after they have been run.
var mod = MyApp.module("MyMod");
mod.on("before:stop", function(){
// do stuff before the module is stopped
});
mod.on("stop", function(){
// do stuff after the module has been stopped
});