Resin 4 CDI Dependency Injection Binding Examples
From Resin 4.0 Wiki
Contents |
CanDI (Java Injection) Pattern Tutorial
Four of the primary Java Injection patterns.
Overview
The four main CanDI patterns share a common goal: improve code with a declarative injection style. When Java classes cleanly describe their dependencies, their lifecycles, and their exports, they are self-documenting. You can read the classes and understand how they will behave, i.e. you don't need to read the code side-by-side with XML configuration to understand the system's behavior.
The custom, typesafe binding annotations are key to CanDI's self-documentation, because injection points clearly describe the resources or services they expect with adjective-oriented annotations. Because the annotations are true Java classes, they are documented in JavaDoc and verified by the compiler. The small number of meaningful adjectives means they don't impose a significant coding burden, and are well worth the small extra development time.
<deftable title="CanDI Application Patterns"> <tr>
<th>Pattern</th> <th>Description</th>
</tr> <tr>
<td>Service Pattern</td> <td>Organize the application as a collection of services.</td>
</tr> <tr>
<td>Resource Configuration Pattern</td> <td>Bind and resources with declarative annotations and configure with XML.</td>
</tr> <tr>
<td>Startup Pattern</td> <td>Use @Startup beans to initialize application state.</td>
</tr> <tr>
<td>Plugin/Extension Pattern</td> <td>Discover plugin/extension classes for a service.</td>
</tr> </table>
This tutorial describes four main CanDI design patterns: services, resources, startup and extensions. Services center an application's design by encapsulating management and data. Resources are the configurable interface between the user and the application. Startup initializes the application. And extensions allow sophisticated applications to tailor their behavior to the user's needs.
Tutorial Architecture
<figure src="ioc-binding.png" alt="(@Blue BlueResourceBean, @Red RedResourceBean) -> (SetServlet @Inject MyService, GetServlet @Inject MyService) <- MyServiceBean" />
Since the purpose of the service pattern is encapsulating state and
managment for multiple clients, the tutorial shows a single service
used by multiple servlets and by PHP and JSP scripts. Services are
typically singletons in the application and use @Inject
to mark the binding.
The resource pattern configures a driver class and properties in
XML for an application resource.
The resource tutorial uses MyResource as a general resource API,
like DataSource or EntityManager, and
application specific bindings @Red and
@Blue.
Because resource APIs are general, they
need an application-specific description to document their purpose in
the code. Binding annotations are simple, clear adjectives, and
typically only a small number are needed. The
driver classes like BlueResourceBean are typically selected
and configured in an XML, like selecting and configuring a
database.
Startup initialization is needed by most applications, and can use
the CanDI startup pattern to document the startup classes and avoid
unnecessary XML. Because CanDI discovers
beans through classpath scanning, you can create startup beans with
just a @Startup annotation and a
@PostConstruct method.
A plugin or extension capability can improve the flexibility of
many applications, even if designed for internal use. The plugin pattern
uses CanDI's discovery process for the plugin capability without
requiring a new infrastructure.
The tutorial reuses the MyResource API as a plugin
API and grab all implementations using the CanDI Instance
interface and the @Any annotation.
Java Injection API
The most important CanDI classes are just three annotations:
@Inject, @Qualifier
and @Singleton, because many applications will
primarily use the service and resource patterns. By using these three
annotations effectively, you can improve the readability and
maintainability of your application's services and resources.
<deftable title="Service and Resource Pattern CanDI classes" > <tr>
<th>Annotation/Class</th> <th>Description</th>
</tr> <tr>
<td>@Singleton</td> <td>scope annotation marking the service as a singleton</td>
</tr> <tr>
<td>@Qualifier</td> <td>descriptive application bindings are marked with this meta-annotation</td>
</tr> <tr>
<td>@Inject</td> <td>Default binding for unique beans (service pattern).</td>
</tr> </table>
Applications which provide scripting access to services or
resources will use the @Named annotation to provide a
scripting name for the beans.
<deftable title="Scripting Support CanDI classes" > <tr>
<th>Annotation/Class</th> <th>Description</th>
</tr> <tr>
<td>Named</td> <td>Scriping and JSP/JSF EL access to CanDI beans (service pattern)</td>
</tr> </table>
The startup pattern uses two additional annotations,
@Startup to mark the bean as needing creation on
container start, and @PostConstruct marking a method to
be initialized.
<deftable title="Startup Pattern CanDI classes" > <tr>
<th>Annotation/Class</th> <th>Description</th>
</tr> <tr>
<td>@Startup</td> <td>Starts a bean when the container starts.</td>
</tr> <tr>
<td>@PostConstruct</td> <td>Calls an initialization method the bean is created.</td>
</tr> </table>
A plugin or extension architecture uses two
additional CanDI classes to easily find plugins discovered during
CanDI's classpath scanning. Instance<T> provides an
iterator over all the discovered and configured beans, and
@Any selects all beans independent of their
@Qualifier.
<deftable title="Plugin/Extension Pattern CanDI classes" > <tr>
<th>Annotation/Class</th> <th>Description</th>
</tr> <tr>
<td>Instance<T></td> <td>Programmatic access to all implementations of an interface.</td>
</tr> <tr>
<td>@Any</td> <td>Selects all matching beans for an interface.</td>
</tr> </table>
Files in this tutorial" web-only='true
<deftable title="Files: Service Pattern"> <tr>
<th>File</th> <th>Description</th>
</tr> <tr>
<td>WEB-INF/classes/example/MyServiceBean.java</td>
<td>Implementation of the MyService service bean.</td>
</tr> <tr>
<td>WEB-INF/classes/example/MyService.java</td>
<td>Service interface for the resource pattern.</td>
</tr> <tr>
<td>WEB-INF/classes/example/GetServlet.java</td>
<td>Demonstration of four CanDI patterns.</td>
</tr> <tr>
<td>WEB-INF/classes/example/SetServlet.java</td>
<td>Demonstration of four CanDI patterns.</td>
</tr> <tr>
<td>test.php</td>
<td>PHP using a service with java_bean() and the @Named annotation.</td>
</tr> <tr>
<td>test.jsp</td>
<td>JSP using a service with java_bean() and the @Named annotation.</td>
</tr> <tr>
<td>WEB-INF/beans.xml</td>
<td>CanDI beans.xml triggering classpath scanning.</td>
</tr> </table>
<deftable title="Files: Configuration and Plugin Pattern"> <tr>
<th>File</th> <th>Description</th>
</tr> <tr>
<td>WEB-INF/resin-web.xml</td>
<td>Configuration of custom resources.</td>
</tr> <tr>
<td>WEB-INF/classes/example/Blue.java</td>
<td>Binding Type annotation for the @Blue resource.</td>
</tr> <tr>
<td>WEB-INF/classes/example/BlueResourceBean.java</td>
<td>Implementation of the @Blue bean.</td>
</tr> <tr>
<td>WEB-INF/classes/example/MyResource.java</td>
<td>Resource interface for the resource pattern.</td>
</tr> <tr>
<td>WEB-INF/classes/example/SetServlet.java</td>
<td>Demonstration of four CanDI patterns.</td>
</tr> </table>
<deftable title="Files: Startup Pattern"> <tr>
<th>File</th> <th>Description</th>
</tr> <tr>
<td>WEB-INF/classes/example/MyStartupBean.java</td>
<td>Startup bean to configure other resources on web-app initialization.</td>
</tr> </table>
Service Pattern
Because services are often unique in an application, the service
interface is generally enough to uniquely identify
the service. In CanDI, the @Inject annotation injects a
unique service to a client class. A declarative style applies to both
the service declaration and the service use, by annotating the service
scope as @Singleton, and annotating the client
injection as @Inject. By describing the function on the
class itself, CanDI's annotations improve the readability and
maintainability of service classes.
Example: GetServlet.java
package example;
import javax.inject.Inject;
...
public class GetServlet extends HttpServlet {
private @Inject MyService _service;
...
}
Users of the service will access it through an interface
like MyService. The implementation will be a concrete
class like MyServiceBean. The interface API
in CanDI is a plain Java interface with no CanDI-specific annotations
or references.
Example: MyService.java
package example;
public interface MyService {
public void setMessage(String message);
public String getMessage();
}
All the information relevant to the class deployment is
on the class itself, because the service implementation is discovered
through CanDI's classpath scanning. In other words, The service's
deployment is self-documenting. Since services are generally
singletons, they will typically have the
@Singleton
annotation. Other annotations are optional and describe the service
registration or behavior. For example, the tutorial uses
the @Named tag, because the test.jsp and
test.php need a named reference.
Scripting beans use the @Named annotation on a CanDI
bean for integration with the JSP EL expression language and with PHP.
Nonscripting beans do not declare a @Named annotation
because CanDI uses the service type and binding annotations for matching.
Example: MyServiceBean.java
package example;
import javax.inject.Singleton;
import javax.inject.Named;
import javax.enterprise.inject.Default;
@Singleton
@Named("myService")
@Default
public class MyServiceBean implements MyService {
private String _message = "default";
public void setMessage(String message)
{
_message = message;
}
public String getMessage()
{
return _message;
}
}
Using Services from PHP and JSP
CanDI is designed to integrate closely with scripting languages
like PHP and JSP. The scripting languages locate a CanDI service or
resource using a string, because scripting lacks the strong typing
needed for full dependency injection. As mentioned above, the name of
a CanDI service is declared by the @Named anntation on
the bean itself. The PHP or JSP code will use the name to obtain a
reference to the bean. For PHP, the function call is
java_bean as follows:
Example: test.php
<?php
$myService = java_bean("myService");
echo $myService->getMessage();
?>
While PHP has a function access to the CanDI service or resource,
JSP and JSF grab the CanDI bean with using the JSP expression
language. Any CanDI bean with a @Named annotation
automatically becomes available to EL expressions as follows:
Example: test.jsp
message: ${myService.message}
Resource XML Configuration Pattern
Resources like databases, and queues fit multiple roles in an
application and need configuration and description
beyond their generic DataSource and
BlockingQueue APIs. While services are generally unique
and can use the @Inject qualifier, resources will
generally create custom @Qualifier annotations to
identify and document the resource.
CanDI encourages a small number of binding
annotations used as adjectives to describe resources. A typical
medium application like a mail list manager might use half a dozen
custom binding adjectives, and may need fewer or more depending on
the number of unique resources. Each database, queue,
mail, and JPA EntityManager will generally have a unique name. If
users need customization and configuration of internal resources, you
may need additional binding types. If the application has a
single database, it might only have one binding annotation, or might even
use @Inject.
The purpose of the binding annotation is to self-document the
resource in the client code. If the application uses
@ShoppingCart database and a @ProductCatalog
database, the client code will bind by their description.
The code declares its dependencies in a readable way, and lets CanDI and the
configuration provide the resource it needs.
The tutorial has @Red resource, configured in XML
because the user might need to customize the configuration.
The resource client, SetServlet, uses the
adjective annotation in the field declaration as follows:
Example: SetServlet.java
public class SetServlet extends HttpServlet {
private @Red MyResource _red;
private @Blue MyResource _blue;
...
}
The XML is short and meaningful, because it's only required for
customization, not for wiring and binding. Databases and JMS queues will
need to configure the database driver and add the binding
adjective. Applications resources can also be configured in XML if
exposing the configuration is useful to your users, but unique
internal classes like most services will stay out of the XML.
In our example, we let the users configure the data field
of the resource and let them choose the
implementation class.
The XML configuration for a bean needs three pieces of data: the
driver class, the descriptive binding annotation, and any customization data.
Because the driver is the most important, CanDI uses the class as the
XML tag and uses the package as the XML namespace.
While scanning the XML, the driver class is top and prominent,
reflecting its importance. In the
example, <example:BlueResourceBean>
is the driver class.
Example: BlueResourceBean instance configuration
<example:BlueResourceBean xmlns:example="urn:java:example"> ... </example:BlueResourceBean>
In CanDI, the binding annotation is also an XML tag, represented by its classname and package. In CanDI, classes and annotations get XML tags with camel-case names matching the classname, and XML for properties are lower case. The case distinguishes annotations from properties in the XML, improving XML readability.
Example: @Blue annotation configuration
<example:Blue xmlns:example="urn:java:example"/>
Properties of a resource use the standard beans-style names, so
<example:data> sets the bean's setData
property. CanDI converts the XML string value to the property's
actual value. In this case, the conversion is trivial, but CanDI can
convert to integers, doubles, enumerations, classes, URLs, etc.
Beans have all the configuration capabilities as Resin beans in the
resin.xml and resin-web.xml, because Resin uses CanDI for its own
internal configuration.
Example: resin-web.xml
<web-app xmlns="http://caucho.com/ns/resin"
xmlns:example="urn:java:example">
<example:BlueResourceBean>
<example:Blue/>
<example:data>blue resource</example:data>
</example:BlueResourceBean>
<example:RedResourceBean>
<example:Red/>
<example:data>red resource</example:data>
</example:RedResourceBean>
</web-app>
Binding types should generally be descriptive adjectives, so it can
describe the injection clearly. Anyone reading code should
understand immediately which resource it's using. The tutorial's
@Blue binding annotation itself is a normal Java
annotation marked by a CanDI @Qualifier annotation.
Because
of its importance and because there are only a small number of custom
annotations, it's important to spend time choosing a good descriptive name for
the annotation.
Example: Blue.java
package example;
import static java.lang.annotation.ElementType.*;
import static java.lang.annotation.RetentionPolicy.*;
import java.lang.annotation.*;
import javax.inject.Qualifier;
@Qualifier
@Documented
@Target({TYPE, METHOD, FIELD, PARAMETER})
@Retention(RUNTIME)
public @interface Blue {
}
The resource implementation itself is straightforward. When the
resource is a singleton, it will need a
@Singleton
annotation, just like a service. By default, CanDI will inject a new
instance of the bean at every injection point.
Example: BlueResourceBean.java
package example;
public class BlueResourceBean {
private String _data;
public void setData(String data)
{
_data = data;
}
}
Startup Pattern
The @Startup annotation marks a bean as initializing
on server startup.
Because the startup bean is discovered through classpath
scanning like the other beans, the initialization is controlled by
the startup class itself. In other words, looking at the startup
class is sufficient, because it doesn't rely on XML for startup. The
startup bean uses the @PostConstruct annotation on an
initialization method to start initialization code.
Example: MyStartupBean.java
package example;
import javax.annotation.PostConstruct;
import javax.ejb.Startup;
import javax.inject.Inject;
@Startup
public class MyStartupBean {
private @Inject MyService _service;
@PostConstruct
public void init()
{
_service.setMessage(this + ": initial value");
}
}
Plugin/Extension Pattern
A plugin or extension architecture can make an application more
flexible and configurable. For example, a filtering system, or
blueprints or custom actions can add significant power to an
application. The plugin pattern uses CanDI's discovery system
to find all implementations of the plugin interface. The Instance
iterator together with the special @Any binding
annotation gives all implementations of a resource.
The CanDI Instance interface has two uses: return a
unique instance programmatically with the get() method,
and list all instances for a plugin capability. Since
Instance implements the JDK's Iterable
interface, you can use it in a for loop. Each returned
instance obeys the standard CanDI scoping rules, either returning the
single value for @Singleton singletons, or
creating a new instance for the default.
The @Any annotation works with Instance
to select all values. Because bindings default to the
@Inject binding type, we need to override the default to
get all instances.
Example: GetServlet.java
package example;
import javax.inject.Inject;
import javax.enterprise.inject.Any;
import javax.enterprise.inject.Instance;
...
public class GetServlet extends HttpServlet {
@Inject @Any Instance<MyResource> _resources;
public void service(HttpServletRequest request,
HttpServletResponse response)
throws IOException, ServletException
{
PrintWriter out = response.getWriter();
for (MyResource resource : _resources) {
out.println("resource: " + resource);
}
}
}
