Facades
Introduction
Facades provide a "static" interface to classes that are available in the application's service container. Laravel ships with many facades which provide access to almost all of Laravel's features. Laravel facades serve as "static proxies" to underlying classes in the service container, providing the benefit of a terse, expressive syntax while maintaining more testability and flexibility than traditional static methods.
All of Laravel's facades are defined in the Illuminate\Support\Facades
namespace. So, we can easily access a facade like so:
use Illuminate\Support\Facades\Cache; Route::get('/cache', function () { return Cache::get('key');});
Throughout the Laravel documentation, many of the examples will use facades to demonstrate various features of the framework.
When To Use Facades
Facades have many benefits. They provide a terse, memorable syntax that allows you to use Laravel's features without remembering long class names that must be injected or configured manually. Furthermore, because of their unique usage of PHP's dynamic methods, they are easy to test.
However, some care must be taken when using facades. The primary danger of facades is class scope creep. Since facades are so easy to use and do not require injection, it can be easy to let your classes continue to grow and use many facades in a single class. Using dependency injection, this potential is mitigated by the visual feedback a large constructor gives you that your class is growing too large. So, when using facades, pay special attention to the size of your class so that its scope of responsibility stays narrow.
When building a third-party package that interacts with Laravel, it's better to inject Laravel contracts instead of using facades. Since packages are built outside of Laravel itself, you will not have access to Laravel's facade testing helpers.
Facades Vs. Dependency Injection
One of the primary benefits of dependency injection is the ability to swap implementations of the injected class. This is useful during testing since you can inject a mock or stub and assert that various methods were called on the stub.
Typically, it would not be possible to mock or stub a truly static class method. However, since facades use dynamic methods to proxy method calls to objects resolved from the service container, we actually can test facades just as we would test an injected class instance. For example, given the following route:
use Illuminate\Support\Facades\Cache; Route::get('/cache', function () { return Cache::get('key');});
We can write the following test to verify that the Cache::get
method was called with the argument we expected:
use Illuminate\Support\Facades\Cache; /** * A basic functional test example. * * @return void */public function testBasicExample(){ Cache::shouldReceive('get') ->with('key') ->andReturn('value'); $this->visit('/cache') ->see('value');}
Facades Vs. Helper Functions
In addition to facades, Laravel includes a variety of "helper" functions which can perform common tasks like generating views, firing events, dispatching jobs, or sending HTTP responses. Many of these helper functions perform the same function as a corresponding facade. For example, this facade call and helper call are equivalent:
return View::make('profile'); return view('profile');
There is absolutely no practical difference between facades and helper functions. When using helper functions, you may still test them exactly as you would the corresponding facade. For example, given the following route:
Route::get('/cache', function () { return cache('key');});
Under the hood, the cache
helper is going to call the get
method on the class underlying the Cache
facade. So, even though we are using the helper function, we can write the following test to verify that the method was called with the argument we expected:
use Illuminate\Support\Facades\Cache; /** * A basic functional test example. * * @return void */public function testBasicExample(){ Cache::shouldReceive('get') ->with('key') ->andReturn('value'); $this->visit('/cache') ->see('value');}
How Facades Work
In a Laravel application, a facade is a class that provides access to an object from the container. The machinery that makes this work is in the Facade
class. Laravel's facades, and any custom facades you create, will extend the base Illuminate\Support\Facades\Facade
class.
The Facade
base class makes use of the __callStatic()
magic-method to defer calls from your facade to an object resolved from the container. In the example below, a call is made to the Laravel cache system. By glancing at this code, one might assume that the static method get
is being called on the Cache
class:
<?php namespace App\Http\Controllers; use App\Http\Controllers\Controller;use Illuminate\Support\Facades\Cache; class UserController extends Controller{ /** * Show the profile for the given user. * * @param int $id * @return Response */ public function showProfile($id) { $user = Cache::get('user:'.$id); return view('profile', ['user' => $user]); }}
Notice that near the top of the file we are "importing" the Cache
facade. This facade serves as a proxy to accessing the underlying implementation of the Illuminate\Contracts\Cache\Factory
interface. Any calls we make using the facade will be passed to the underlying instance of Laravel's cache service.
If we look at that Illuminate\Support\Facades\Cache
class, you'll see that there is no static method get
:
class Cache extends Facade{ /** * Get the registered name of the component. * * @return string */ protected static function getFacadeAccessor() { return 'cache'; }}
Instead, the Cache
facade extends the base Facade
class and defines the method getFacadeAccessor()
. This method's job is to return the name of a service container binding. When a user references any static method on the Cache
facade, Laravel resolves the cache
binding from the service container and runs the requested method (in this case, get
) against that object.
Facade Class Reference
Below you will find every facade and its underlying class. This is a useful tool for quickly digging into the API documentation for a given facade root. The service container binding key is also included where applicable.