@Retention(RUNTIME)
@Target(TYPE)
public @interface Contract {
}
Writing HK2 Components DRAFT |
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The Hundred-Kilobyte Kernel (HK2) is the lightweight and extensible kernel of GlassFish Server. To interact with GlassFish Server, add-on components plug in to this kernel. In the HK2 component model, the functions of an add-on component are declared through a contract-service implementation paradigm. An HK2 contract identifies and describes the building blocks or the extension points of an application. An HK2 service implements an HK2 contract.
The following topics are addressed here:
The Hundred-Kilobyte Kernel (HK2) provides a module system and component model for building complex software systems. HK2 forms the core of GlassFish Server’s architecture.
The module system is responsible for instantiating classes that constitute the application functionality. The HK2 runtime complements the module system by creating objects. It configures such objects by:
Injecting other objects that are needed by a newly instantiated object
Injecting configuration information needed for that object
Making newly created objects available, so that they can then be injected to other objects that need it
An HK2 service identifies the building blocks or the extension points of an application. A service is a plain-old Java object (POJO) with the following characteristics:
The object implements an interface.
The object is declared in a JAR file with the META-INF/services
file.
To clearly separate the contract interface and its implementation, the HK2 runtime requires the following information:
Which interfaces are contracts
Which implementations of such interfaces are services
Interfaces that define a contract are identified by the
org.jvnet.hk2.annotations.Contract
annotation.
@Retention(RUNTIME)
@Target(TYPE)
public @interface Contract {
}
Implementations of such contracts should be identified with an
org.jvnet.hk2.annotations.Service
annotation so that the HK2 runtime
can recognize them as @Contract
implementations.
@Retention(RUNTIME)
@Target(TYPE)
public @interface Service {
...
}
For more information, see
Service
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/annotations/Service.html
).
Once Services are defined, the HK2 runtime can be used to instantiate or retrieve instances of services. Each service instance has a scope, specified as singleton, per thread, per application, or a custom scope.
You can specify the scope of a service by adding an
org.jvnet.hk2.annotations.Scoped
annotation to the class-level of your
@Service
implementation class. Scopes are also services, so they can
be custom defined and added to the HK2 runtime before being used by
other services. Each scope is responsible for storing the service
instances to which it is tied; therefore, the HK2 runtime does not rely
on predefined scopes (although it comes with a few predefined ones).
@Contract
public abstract class Scope {
public abstract ScopeInstance current();
}
The following code fragment shows how to set the scope for a service to
the predefined Singleton
scope:
@Service
public Singleton implements Scope {
...
}
@Scope(Singleton.class)
@Service
public class SingletonService implements RandomContract {
...
}
You can define a new Scope
implementation and use that scope on your
@Service
implementations. You will see that the HK2 runtime uses the
Scope
instance to store and retrieve service instances tied to that
scope.
Do not call the new
method to instantiate components. Instead,
retrieve components by using the Habitat
instance. The simplest way to
use the Habitat
instance is through a getComponent(Class`T
`contract)
call:
public <T> T getComponent(Class<T> clazz) throws ComponentException;
More APIs are available at
Habitat
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/component/Habitat.html
).
Components can attach behaviors to their construction and destruction
events by implementing the
org.jvnet.hk2.component.PostConstruct
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/component/PostConstruct.html
)
interface, the
org.jvnet.hk2.component.PreDestroy
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/component/PreDestroy.html
)
interface, or both. These are interfaces rather than annotations for
performance reasons.
The PostConstruct
interface defines a single method, postConstruct
,
which is called after a component has been initialized and all its
dependencies have been injected.
The PreDestroy
interface defines a single method, preDestroy
, which
is called just before a component is removed from the system.
Example 2-1 Example Implementation of PostContruct
and PreDestroy
@Service(name="com.example.container.MyContainer")
public class MyContainer implements Container, PostConstruct, PreDestroy {
@Inject
Logger logger;
...
public void postConstruct() {
logger.info("Starting up.");
}
public void preDestroy() {
logger.info("Shutting down.");
}
}
Inversion of control (IoC) refers to a style of software architecture where the behavior of a system is determined by the runtime capabilities of the individual, discrete components that make up the system. This architecture is different from traditional styles of software architecture, where all the components of a system are specified at design-time. With IoC, discrete components respond to high-level events to perform actions. While performing these actions, the components typically rely on other components to provide other actions. In an IoC system, components use injection to gain access to other components.
Services usually rely on other services to perform their tasks. The HK2
runtime identifies the @Contract
implementations required by a service
by using the
org.jvnet.hk2.annotations.Inject
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/annotations/Inject.html
)
annotation. Inject
can be placed on fields or setter methods of any
service instantiated by the HK2 runtime. The target service is retrieved
and injected during the calling service’s instantiation by the component
manager.
The following example shows how to use @Inject
at the field level:
@Inject
ConfigService config;
The following example shows how to use @Inject
at the setter level:
@Inject
public void set(ConfigService svc) {...}
Injection can further qualify the intended injected service implementation by using a name and scope from which the service should be available:
@Inject(Scope=Singleton.class, name="deploy")
AdminCommand deployCommand;
Injection of instances that have not been already instantiated triggers
more instantiation. You can see this as a component instantiation
cascade where some code requests for a high-level service will, by using
the @Inject
annotation, require more injection and instantiation of
lower level services. This cascading feature keeps the implementation as
private as possible while relying on interfaces and the separation of
contracts and providers.
Example 2-2 Example of Instantiation Cascading
The following example shows how the instantiation of DeploymentService
as a Startup
contract implementation will trigger the instantiation of
the ConfigService
.
@Contract
public interface Startup {...}
Iterable<Startup> startups;
startups = habitat.getComponents(Startup.class);
@Service
public class DeploymentService implements Startup {
@Inject
ConfigService config;
}
@Service
public Class ConfigService implements ... {...}
GlassFish Server discovers add-on components by identifying Java
programming language classes that are annotated with the
org.jvnet.hk2.annotation.Service
annotation.
To identify a class as an implementation of an GlassFish Server service,
add the org.jvnet.hk2.annotations.Service
annotation at the
class-definition level of your Java programming language class.
@Service
public class SamplePlugin implements ConsoleProvider {
...
}
The @Service
annotation has the following elements. All elements are
optional.
name
The name of the service. The default value is an empty string.
scope
The scope to which this service implementation is tied. The default
value is org.glassfish.hk2.scopes.PerLookup.class
.
factory
The factory class for the service implementation, if the service is
created by a factory class rather than by calling the default
constructor. If this element is specified, the factory component is
activated, and Factory.getObject
is used instead of the default
constructor. The default value of the factory
element is
org.jvnet.hk2.component.Factory.class
.
Example 2-3 Example of the Optional Elements of the @Service
Annotation
The following example shows how to use the optional elements of the
@Service
annotation:
@Service (name="MyService",
scope=com.example.PerRequest.class,
factory=com.example.MyCustomFactory)
public class SamplePlugin implements ConsoleProvider {
...
}
If you are using Maven 2 to build HK2 components, invoke the
auto-depends
plug-in for Maven so that the META-INF/services
files
are generated automatically during build time.
Example 2-4 Example of the Maven Plug-In Configuration
<plugin>
<groupId>org.glassfish.hk2</groupId>
<artifactId>hk2-maven-plugin</artifactId>
<configuration>
<includes>
<include>com/example/**</include>
</includes>
</configuration>
</plugin>
Example 2-5 Example of META-INF/services
File Generation
This example shows how to use
@Contract
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/annotations/Contract.html
)
and
@Service
(http://hk2.java.net/auto-depends/apidocs/org/jvnet/hk2/annotations/Service.html
)
and the resulting META-INF/services
files.
The interfaces and classes in this example are as follows:
package com.example.wallaby.annotations;
@Contract
public interface Startup {...}
package com.example.wombat;
@Contract
public interface RandomContract {...}
package com.example.wallaby;
@Service
public class MyService implements Startup, RandomContract, PropertyChangeListener {
...
}
These interfaces and classes generate this META-INF/services
file with
the MyService
content:
com.example.wallaby.annotations.Startup
com.example.wombat.RandomContract
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