Spiral includes a set of tools that makes it easier to manage dependencies and create objects in your code. One of the main tools is the container, which helps you handle class dependencies and automatically "injects" them into the class. This means that instead of creating objects and setting up dependencies manually, the container takes care of it for you.
The Spiral container also follows a set of PSR-11 Container standards, which ensures compatibility with other libraries.
In your code, you can access the container by asking for the Psr\Container\ContainerInterface
.
final class UserController
{
public function __construct(
private readonly \Psr\Container\ContainerInterface $container
) {}
public function show(string $id): void
{
$repository = $this->container->get(UserRepository::class);
// ...
}
}
The Spiral container allows you to use both constructor and method injections for your classes. This means that you can have dependencies automatically injected into the class through the constructor, or through a specific method.
For example, in the UserController
class, the UserRepository
dependency is injected through the __construct()
method. This means that the container will automatically create and deliver the UserRepository object when the method is
called.
use Psr\Container\ContainerInterface;
final class UserController
{
public function __construct(
private readonly UserRepository $users
) {}
public function show(string $id): void
{
$user = $this->users->findOrFail($id);
// ...
}
}
Note
This feature is available for classes like controllers, console commands, and queue jobs. Additionally, the container also supports advanced features like union types, variadic arguments, referenced parameters and default object values for the auto-wiring.
The Spiral container allows you to configure it by creating bindings between interfaces or aliases to specific implementations. You can use Bootloaders to define these bindings.
There are two ways to configure the container, either by using the Spiral\Core\BinderInterface
or
the Spiral\Core\Container
.
To bind an interface to a concrete implementation, you can use the following code snippet:
use Spiral\Core\BinderInterface;
public function boot(BinderInterface $binder): void
{
$binder->bind(
UserRepositoryInterface::class,
CycleUserRepository::class
);
}
To bind a singleton, you can use the following code snippet:
use Spiral\Core\BinderInterface;
public function boot(BinderInterface $binder): void
{
$binder->bindSingleton(
UserRepositoryInterface::class,
CycleUserRepository::class
);
}
You can also bind with specific parameters by using the Autowire
class like this:
use Spiral\Core\BinderInterface;
use Spiral\Core\Container\Autowire;
public function boot(BinderInterface $binder): void
{
$binder->bindSingleton(
UserRepositoryInterface::class,
new Autowire(CycleUserRepository::class, ['table' => 'users'])
);
}
Lastly, you can use closures to configure your class automatically by passing a closure to the bind or bindSingleton
method like this:
use Spiral\Core\BinderInterface;
public function boot(BinderInterface $binder): void
{
$binder->bindSingleton(
UserRepositoryInterface::class,
static fn() => new CycleUserRepository(table: users)
);
}
Closures also support dependencies:
use Spiral\Core\BinderInterface;
use Spiral\Core\Container\Autowire;
public function boot(BinderInterface $binder): void
{
$binder->bindSingleton(
UserRepositoryInterface::class,
static fn(UserConfig $config) => new CycleUserRepository(table: $config->getTable())
);
}
When this closure is executed, the container will automatically resolve an instance of UserConfig
and pass it as an
argument to the closure. This allows you to easily configure your classes with dependencies without having to manually
instantiate and manage them.
To check if a container has binding use:
use Spiral\Core\Container;
public function boot(Container $container): void
{
$container->has(UserRepositoryInterface::class)
}
To remove the container binding:
use Spiral\Core\BinderInterface;
public function boot(BinderInterface $binder): void
{
$binder->removeBinding(UserRepositoryInterface::class)
}
Container supports WeakReference
binding:
use Spiral\Core\Container;
use WeakReference;
public function boot(Container $container): void
{
$object = new stdClass();
$hash = \spl_object_hash($object);
$reference = WeakReference::create($object);
$container->bind('test-alias', $reference);
dump($hash === \spl_object_hash($container->get('test-alias'))); // true
unset($object);
// New object can't be created because classname has not been stored
dump($container->get('test-alias')); // null
}
Starting from version 3.8.0 of the Spiral Framework we have replaced the previous array-based structure for storing information about bindings within the container. The new approach employs Data Transfer Objects (DTO), providing a more structured and organized way to store binding information. With this change, developers now can easily configure container bindings using these objects.
To demonstrate the enhanced container functionality, here's an example showcasing the new binding configuration:
use Spiral\Core\Config\Factory;
$container->bind(LoggerInterface::class, new Factory(
callable: static function() {
return new Logger(....);
},
singleton: true
))
Here are the available binding DTOs:
This simplified DTO allows you to create a link to another binding within the container.
use Spiral\Core\Config\Alias;
$container->bind(
\DatetimeImmutable::class,
static fn() => new \DatetimeImmutable()
);
$container->bind(
'now',
new Alias(alias: \DatetimeImmutable::class)
);
In this example, we first bind the \DatetimeImmutable
class to a factory function that creates a new instance
of \DatetimeImmutable
every time it's requested. Then, we create an Alias binding named now and associate it with
the \DatetimeImmutable
class binding.
Now you can request \DatetimeImmutable
class from the container by alias $container->get('now')
The Alias also provides a second argument - singleton
. By setting singleton to true
, the aliased class becomes a
singleton. This means that whenever you request $container->get('now')
from the container, it will return the same
instance every time. On the other hand, calling $container->get(\DatetimeImmutable::class)
will return a new instance
of \DatetimeImmutable
with the current time on each request.
The Spiral\Core\Config\Autowire
binding serves as a wrapper for the Spiral\Core\Container\Autowire
class, providing
an automated way to resolve and instantiate classes by injecting their dependencies.
use Spiral\Core\Config\Autowire;
use Spiral\Core\Container\Autowire as AutowireAlias;
$container->bind(MyClass::class, new Autowire(
autowire: new AutowireAlias(MyClass::class, ['foo' => 'bar']),
singleton: true
));
The singleton
argument, set to true in this example, indicates that the container should treat MyClass
as a
singleton. When you request an instance of MyClass from the container $container->get(MyClass::class)
, it will return
the same instance every time.
The Spiral\Core\Config\Factory
binding serves as a simple factory for creating mixed types using a closure.
use Spiral\Core\Config\Factory;
$container->bind('time', new Factory(
callable: static fn() => time(),
));
Every time when you request current time from the container $container->get('time')
it will return current timestamp.
Additionally, the Factory
binding can be configured as a singleton:
$container->bind('time', new Factory(
callable: static fn() => time(),
singleton: true,
));
By setting the singleton
argument to true
. This means that whenever you request the time value from the
container $container->get('time')
, it will return the same value across multiple invocations.
The Spiral\Core\Config\DeferredFactory
binding enables you to bind deferred factory to the container using a
special array callable.
use Spiral\Core\Config\DeferredFactory;
$container->bind('some-binding', new DeferredFactory(
factory: [MyClass::class, 'handle'],
));
In the example above, we bind the key some-binding to a DeferredFactory
instance. The factory property is set
to [MyClass::class, 'handle']
. When the some-binding key is requested from the
container $container->get('some-binding')
, the DeferredFactory
will resolve an instance of MyClass
and then invoke
the handle method on that instance to produce the required value.
Additionally, binding can be configured as a singleton:
$container->bind('some-binding', new DeferredFactory(
factory: ...,
singleton: true
));
The Scalar binding is a new functionality introduced for the container. It provides a convenient way to store and retrieve static scalar values within the container. It can be useful for configuring paths, constants, or any other scalar values needed by your application.
use Spiral\Core\Config\Scalar;
$container->bind('app-path', new Scalar(value: '/var/www/my-app'));
The Shared binding allows you to bind a persistent object to a key in the container. Once the object is created, it will be reused every time the key is requested, and custom arguments cannot be provided during subsequent requests.
use Spiral\Core\Config\Shared;
$container->bind(MyClass::class, new Shared(value: new MyClass(...)));
It's important to note that with the Shared
binding, custom arguments cannot be provided during subsequent requests.
The object will be created with the initial arguments and reused as is.
It is particularly useful when you want to ensure that the same instance of an object is used throughout the application. It provides persistence and prevents the creation of multiple instances with different arguments.
An inflector allows you to manipulate an object after creating it in the container. This is particularly useful for applying common modifications or injections to objects of a specific type.
use Spiral\Core\Config\Inflector;
$container->bind(LoggerAwareInterface::class, new Inflector(
inflector: static function (LoggerAwareInterface $obj, LoggerInterface $logger): LoggerAwareInterface {
$obj->setLogger($logger);
return $obj;
}
));
In this case, any object implementing LoggerAwareInterface
will have its logger set based on the specified configuration.
The Inflector binding is a powerful tool for applying common modifications or injections consistently across objects in your application. It simplifies the process of configuring and customizing objects retrieved from the container.
The WeakReference feature allows you to work with weak reference objects within the container. Weak references are references to an object that do not prevent the object from being garbage-collected when there are no strong references to it.
se Spiral\Core\Config\WeakReference;
$obj = new MyClass();
$container->bind(MyClass::class, new WeakReference(
reference: new \WeakReference($obj)
));
$obj === $container->get(MyClass::class); // true
unset($obj);
$obj1 = $container->get(MyClass::class); // A new object will be created
$obj1 === $container->get(MyClass::class); // true
When you retrieve MyClass from the container $container->get(MyClass::class)
, the container returns the original
object because it still exists. However, when you unset the $obj
variable, removing the strong reference to the
object, it becomes eligible for garbage collection. Subsequent calls to $container->get(MyClass::class)
will create a
new instance of MyClass
because the original object has been garbage-collected.
Using weak references can be beneficial in certain scenarios where you want to have control over the object's lifecycle and allow it to be garbage-collected when there are no more strong references to it.
The framework also allows you to use "lazy singletons" which are classes that are automatically treated as singletons by the container without the need to explicitly bind them as such.
Spiral\Core\Attribute\Singleton
allows you to mark a class as a singleton. By applying this attribute to a class, you
indicate that only a single instance of the class should be created and shared across the application. This attribute
can be used as an alternative to interfaces for specifying singleton behavior.
use Spiral\Core\Attribute\Singleton;
#[Singleton]
final class UserService
{
public function store(User $user): void
{
//...
}
}
Now, the container will automatically treat this class as a singleton and only create one instance of it for the entire application, regardless of how many times it is requested.
protected function index(UserService $service): void
{
dump($this->container->get(UserService::class) === $service);
}
The framework also provides a Spiral\Core\FactoryInterface
that you can use to construct a class without resolving
all of its constructor dependencies. This can be useful in situations where you only need a specific subset of a class's
dependencies or if you want to pass in specific values for some of the dependencies.
public function makeClass(FactoryInterface $factory): MyClass
{
return $factory->make(UserService::class, [
'table' => 'users'
]);
}
In the example above, the make()
method is used to create an instance of UserService
and pass in the value table
for the parameter constructor dependency. The other constructor dependencies will be resolved automatically by the
container.
This allows you to have more control over the construction of your classes, and can be particularly useful in situations where you need to create multiple instances of a class with different constructor dependencies.
The framework also provides the Spiral\Core\ResolverInterface
that you can use to resolve method arguments to
dynamic targets, such as controller methods. This can be useful in situations where you want to invoke a method and need
to resolve its dependencies at runtime.
abstract class Handler
{
public function __construct(
protected readonly ResolverInterface $resolver
) {
}
public function run(array $params): bool
{
$method = new \ReflectionMethod($this, 'do');
return $method->invokeArgs(
$this,
$this->resolver->resolveArguments($method, $params) // resolve missing arguments
);
}
}
The run()
method uses the ResolverInterface
to invoke the do
method with method injection. Now, the do
method
can request method injection:
class UserStoreHandler extends Handler
{
public function do(UserService $service): bool
{
// Store user
}
}
This way, you can easily resolve the dependencies of a method at runtime and invoke it with the required arguments, regardless of whether the dependencies are passed in as parameters or if they need to be resolved by the container.
The default implementation of ResolverInterface
supports Union types. One of the available dependencies of
the needed type will be passed:
use Doctrine\Common\Annotations\Reader;
use Spiral\Attributes\ReaderInterface;
final class Entities
{
public function __construct(
private Reader|ReaderInterface $reader
) {
}
}
$resolver = $this->container->get(ResolverInterface::class);
$function = static fn(int ...$bar) => $bar;
// array passed by parameter name
$args = $resolver->resolveArguments(
new \ReflectionFunction($function),
['bar' => [1, 2]]
);
dump($args); // [1, 2]
// array passed by parameter name with named arguments inside
$args = $resolver->resolveArguments(
new \ReflectionFunction($function),
['bar' => ['ab' => 1, 'bc' => 2]]
);
dump($args); // ['ab' => 1 'bc' => 2]
// value passed by parameter name
$args = $resolver->resolveArguments(
new \ReflectionFunction($function),
['bar' => 1]
);
dump($args); // [1]
$resolver = $this->container->get(ResolverInterface::class);
$function = static fn(int $bar) => $bar;
$bar = 1;
$args = $resolver->resolveArguments(
new \ReflectionFunction($function),
['bar' => &$bar]
);
$bar = 42;
dump($args); // [42]
$resolver = $this->container->get(ResolverInterface::class);
$function = static fn(stdClass $std = new \stdClass()) => $std;
$args = $resolver->resolveArguments(new \ReflectionFunction($function));
dump($args);
// array(1) {
// [0] =>
// class stdClass#369 (0) {
// }
// }
In some cases, you may want to validate a function or method arguments. To do this, you can use the public
validateArguments
method, in which you need to pass ReflectionMethod
or ReflectionFunction
and
array of arguments
. If you received the arguments using the resolveArguments
method and didn't pass false
in the
$validate
parameter, they don't need additional validation. They will be checked automatically.
If the arguments are not valid, Spiral\Core\Exception\Resolver\InvalidArgumentException
will be thrown.
$resolver = $this->container->get(ResolverInterface::class);
$function = static fn(int $bar) => $bar;
$resolver->validateArguments(new \ReflectionFunction($function), [42]);
The framework also provides the Spiral\Core\InvokerInterface
that you can use to invoke a desired method with
automatic resolution of its dependencies. This can be useful in situations where you want to invoke a method on an
object and need to resolve its dependencies at runtime.
The InvokerInterface has a invoke()
method that you can use to invoke a method on an object and pass in specific
values for its dependencies.
Here is an example of how you can use it:
use Spiral\Core\InvokerInterface;
abstract class Handler
{
public function __construct(
protected readonly InvokerInterface $invoker
) {
}
public function run(array $params): bool
{
return $this->invoker->invoke([$this, 'do'], $params)
}
}
if you pass as first callable array value a string ['user-service', 'store']
, it (user-service
) will be requested
from the container.
$container->bind('user-service', UserService::class);
// ...
$invoker->invoke(
['user-service', 'store'],
$params
);
The container will resolve the class user-service
and call the method store
on it.
This allows you to easily invoke methods on classes that are managed by the container without having to manually instantiate them. This is particularly useful in situations where you want to use a class as a service and invoke its methods from multiple parts of your codebase.
Note
A method can have any visibility (public, protected, or private) and still be invoked.
The InvokerInterface
can also be used to invoke closures and automatically resolve their dependencies.
$invoker->invoke(
function (MyClass $class, string $parameter) {
return new MyClassService($class);
},
[
'parameter' => 'value',
]
);
This allows you to easily invoke closures with the required dependencies, regardless of whether the dependencies are passed in as parameters or if they need to be resolved by the container.
Spiral provides a set of attributes that can be used to provide additional control over dependency resolution:
Using the #[Singleton]
attribute can be handy in situations where we want to ensure that only one instance of a class
is created and used throughout the application, such as with configuration managers, database connections, or loggers.
Suppose you have a configuration manager in your application that reads from a configuration file and provides access to various configuration settings. It would be wasteful to reload and parse the configuration file every time you need to access a setting. Using the #[Singleton] attribute ensures that once the configuration file is loaded and parsed, it remains in memory for the duration of the application's lifetime.
use Spiral\Core\Attribute\Singleton;
#[Singleton]
final class ConfigurationManager
{
private readonly array $config;
public function __construct()
{
$this->config = parse_ini_file('config.ini');
}
public function get(string $key)
{
return $this->config[$key] ?? null;
}
}
Allows you to set a specific scope in which a dependency can be resolved. If the dependency is attempted to be resolved in a different scope, an exception will be thrown, indicating a scope mismatch. This attribute helps enforce strict scoping rules and prevents dependencies from being mistakenly resolved in unintended scopes.
Consider an application where certain resources or operations are restricted to authenticated users. For such resources, you'd want to:
This class holds information about the authenticated user. This data is only meant to be available and resolved when the user is authenticated (i.e., within an auth scope).
use Spiral\Core\Attribute\Scope;
#[Scope('auth')]
final readonly class AuthenticatedUser
{
public function __construct(
private int $id,
private string $name,
private string $email,
) {
}
}
The middleware checks if the user is authenticated. If they are, it sets up an auth scope in the IoC container and binds the authenticated user's data to the AuthenticatedUser class.
use Psr\Http\Server\MiddlewareInterface;
use Psr\Http\Message\ResponseInterface as Response;
use Psr\Http\Message\ServerRequestInterface as Request;
use Psr\Http\Server\RequestHandlerInterface as Handler;
final class AuthMiddleware implements MiddlewareInterface
{
public function __construct(
private readonly ContainerInterface $container
) {
}
public function process(Request $request, Handler $handler): Response
{
// This is a simplified authentication check.
// In a real application, this might involve checking session data, JWT tokens, etc.
if ($request->hasHeader('Authorization')) {
// Fetch user data based on the authorization header.
// For simplicity, we're hardcoding user data here.
$user = new AuthenticatedUser(1, 'John Doe', 'john.doe@example.com');
// Set up the auth scope
return $this->container->runScoped(
closure: function (ContainerInterface $container) use ($next, $request) {
// Now, within this scope, you can get the authenticated user instance.
$authenticatedUser = $container->get(AuthenticatedUser::class);
// Continue processing the request.
return $handler($request);
},
bindings: [AuthenticatedUser::class => $user],
name: 'auth'
);
} else {
// No authentication header found.
// Return an unauthorized response or simply continue processing.
return $handler($request);
}
}
}
Let's say we have a controller or service that requires the authenticated user's data. By attempting to resolve the
AuthenticatedUser
class from the container, we can be sure we are either getting the authenticated user or that we are
within the auth scope (thanks to the #[Scope('auth')] attribute).
final class UserProfileController
{
public function getProfile(AuthenticatedUser $user)
{
// Use the $user data to fetch and return the profile.
}
}
Note
Read more about container scopes in the Framework — IoC Scopes section.
Allows you to define a finalize method for a class. When a dependency is resolved within a scope, and that scope is destroyed, the finalize method specified by this attribute will be called. The purpose of the finalize method is to perform any necessary cleanup or finalization actions before the scope is destroyed. This attribute provides a convenient way to handle resource cleanup and ensure proper destruction of objects when a scope is no longer needed.
Consider you're working with a database connection. Once you're done with it, especially within a specific scope, you might want to close the connection or release other resources.
use Spiral\Core\Attribute\Finalize;
#[Finalize(method: 'closeConnection')]
final class DatabaseConnection
{
private $connection;
public function __construct()
{
// Initialize the database connection
}
public function query($sql)
{
// Execute the query on the database
}
public function closeConnection(): void
{
// Close the connection
}
}
When using this class within a scope, once the scope ends, the closeConnection method will be invoked, ensuring that resources are released:
$container->runScoped(
closure: function (DatabaseConnection $db) {
// Execute some database operations
$users = $db->query('SELECT * FROM users');
// ...
},
bindings: [DatabaseConnection::class => new DatabaseConnection()],
);
// Once the scope is destroyed, the connection is automatically closed.
Warning
The object can be leaked but finalized. You should avoid such situations.
$root = new Container();
$obj = $root->get(Foo::class);
unset($root); // The Foo finalizer will be called
// Here we have a leaked finalized object. It is `$obj`.
All the attributes — #[Finalize]
, #[Singleton]
, and #[Scope]
— are fully compatible with each other. This means
that you can use these attributes simultaneously on the same class, allowing for fine-grained control over the behavior
and lifecycle of your dependencies.
Imagine you have a caching service where:
namespace App\Services;
use Psr\Log\LoggerInterface;
use Spiral\Core\Attribute\Finalize;
use Spiral\Core\Attribute\Scope;
use Spiral\Core\Attribute\Singleton;
#[Singleton]
#[Scope('http')]
#[Finalize(method: 'shutdown')]
final class CacheService
{
private array $cache = [];
public function __construct(
private readonly LoggerInterface $logger,
) {
}
public function get(string $key): ?string
{
return $this->cache[$key] ?? null;
}
public function set(string $key, string $value): void
{
$this->cache[$key] = $value;
}
public function shutdown(): void
{
$this->logger->info("CacheService is finalizing.");
// Flush the cache to a persistent storage, close any resources, etc.
$this->cache = [];
}
}
Spiral attempts to hide container implementation and configuration from your domain layer by providing rich auto-wiring functionality. Though auto-wiring rules are straightforward, it's essential to learn them to avoid framework misbehavior.
A framework container can automatically resolve the constructor or method dependencies by providing instances of concrete classes.
class MyController
{
public function __construct(
OtherClass $class,
SomeInterface $some
) {
}
}
In the provided example, the container will attempt to give the instance of OtherClass
by automatically constructing
it. However, SomeInterface
would not be resolved unless you have proper binding in your container.
$container->bind(SomeInterface::class, SomeClass::class);
Please note that the container will try to resolve all constructor dependencies (unless you manually provide some values). It means that all class dependencies must be available, or parameter must be declared as optional:
// will fail if `value` dependency not provided
__construct(OtherClass $class, $value)
// will use `null` as `value` if no other value provided
__construct(OtherClass $class, $value = null)
// will fail if SomeInterface does not point to the concrete implementation
__construct(OtherClass $class, SomeInterface $some)
// will use null as value of `some` if no concrete implementation is provided
__construct(OtherClass $class, SomeInterface $some = null)
The Spiral\Core\Container\Autowire
class allows you to delegate options to the container and pass specific
configuration values to your classes without hardcoding them. This can be useful for keeping your configuration separate
from your code and for making it easier to modify your application's behavior without changing the code itself.
use Spiral\Core\Container\Autowire;
use Spiral\Session\Handler\FileHandler;
return [
// ...
'handler' => new Autowire(
FileHandler::class,
[
'directory' => directory('runtime') . 'session',
'lifetime' => (int)env('SESSION_LIFETIME', 86400),
]
),
];
When the container tries to resolve the Autowire
, it will automatically create an instance of the FileHandler
class and pass the directory
and lifetime
options to the constructor.
This allows you to easily configure your classes and pass in specific options without having to hardcode them in your code, and can be particularly useful for configuring classes that have many options or that are used in multiple parts of your codebase.
In addition to regular method injections, a container can resolve the injection context automatically. Such a technique provides us with an ability to request multiple databases using the following statement:
protected function index(Database $primary, Database $secondary): void
{
dump($primary);
dump($secondary);
}
Where primary
and secondary
are database names.
See more
Read more about injectors in the Advanced — Injectors section.
By keeping your services in memory between requests, you can avoid doing some complex initializations and computations over and over. However, you must remember that your services must be designed in stateless fashion and do not contain any user data.
You can not:
Spiral\Http\Request\InputManager
instead)Spiral\Session\SessionScope
instead)Spiral\Security\GuardScope
instead)You are allowed to store data in services that can not change between user requests. For example, if your application relies on heavy XML as configuration source:
class Service implements SingletonService
{
private ?array $configCache = null;
public function getConfig(): array
{
if ($this->configCache !== null) {
return $this->configCache;
}
$this->configCache = $this->readConfig(); // heavy operation
return $this->configCache;
}
}
Using such an approach, you can perform complex computations only once and rely on RAM cache on later user requests.
In some cases, you might want to replace a container instance in the application. You can do this when you create an application instance.
use Spiral\Core\Container;
use App\Application\Kernel;
$container = new Container();
$container->bind(...);
$app = Kernel::create(
directories: ['root' => __DIR__],
container: $container
)
The container supports PHP 8.2 fibers. The static class \Spiral\Core\ContainerScope::getContainer()
will return the
correct container instance for the current fiber and scope, enabling seamless integration with fibers.