Using Enterprise JavaBeans Technology

Previous Next Contents

8 Using Enterprise JavaBeans Technology

This chapter describes how Enterprise JavaBeans ( EJB) technology is supported in the Oracle GlassFish Server.

The following topics are addressed here:

For general information about enterprise beans, see "https://javaee.github.io/tutorial/partentbeans.html[Enterprise Beans]" in The Java EE 8 Tutorial.

Note

The Web Profile of the GlassFish Server supports the EJB 3.1 Lite specification, which allows enterprise beans within web applications, among other features. The full GlassFish Server supports the entire EJB 3.1 specification. For details, see JSR 318 (http://jcp.org/en/jsr/detail?id=318).

The GlassFish Server is backward compatible with 1.1, 2.0, 2.1, and 3.0 enterprise beans. However, to take advantage of version 3.1 features, you should develop new beans as 3.1 enterprise beans.

Value Added Features

The GlassFish Server provides a number of value additions that relate to EJB development. References to more in-depth material are included.

The following topics are addressed here:

Read-Only Beans

Another feature that the GlassFish Server provides is the read-only bean, an EJB 2.1 entity bean that is never modified by an EJB client. Read-only beans avoid database updates completely.

Note

Read-only beans are specific to the GlassFish Server and are not part of the Enterprise JavaBeans Specification, v2.1. Use of this feature for an EJB 2.1 bean results in a non-portable application.

To make an EJB 3.0 entity read-only, use @Column annotations to mark its columns insertable=false and updatable=false.

A read-only bean can be used to cache a database entry that is frequently accessed but rarely updated (externally by other beans). When the data that is cached by a read-only bean is updated by another bean, the read-only bean can be notified to refresh its cached data.

The GlassFish Server provides a number of ways by which a read-only bean’s state can be refreshed. By setting the refresh-period-in-seconds element in the glassfish-ejb-jar.xml file and the trans-attribute element (or @TransactionAttribute annotation) in the ejb-jar.xml file, it is easy to configure a read-only bean that is one of the following:

  • Always refreshed

  • Periodically refreshed

  • Never refreshed

  • Programmatically refreshed

Read-only beans are best suited for situations where the underlying data never changes, or changes infrequently. For further information and usage guidelines, see Using Read-Only Beans.

The pass-by-reference Element

The pass-by-reference element in the glassfish-ejb-jar.xml file allows you to specify the parameter passing semantics for colocated remote EJB invocations. This is an opportunity to improve performance. However, use of this feature results in non-portable applications. See "pass-by-reference" in GlassFish Server Open Source Edition Application Deployment Guide.

Pooling and Caching

The EJB container of the GlassFish Server pools anonymous instances (message-driven beans, stateless session beans, and entity beans) to reduce the overhead of creating and destroying objects. The EJB container maintains the free pool for each bean that is deployed. Bean instances in the free pool have no identity (that is, no primary key associated) and are used to serve method calls. The free beans are also used to serve all methods for stateless session beans.

Bean instances in the free pool transition from a Pooled state to a Cached state after ejbCreate and the business methods run. The size and behavior of each pool is controlled using pool-related properties in the EJB container or the glassfish-ejb-jar.xml file.

In addition, the GlassFish Server supports a number of tunable parameters that can control the number of "stateful" instances (stateful session beans and entity beans) cached as well as the duration they are cached. Multiple bean instances that refer to the same database row in a table can be cached. The EJB container maintains a cache for each bean that is deployed.

To achieve scalability, the container selectively evicts some bean instances from the cache, usually when cache overflows. These evicted bean instances return to the free bean pool. The size and behavior of each cache can be controlled using the cache-related properties in the EJB container or the glassfish-ejb-jar.xml file.

Pooling and caching parameters for the glassfish-ejb-jar.xml file are described in "bean-cache" in GlassFish Server Open Source Edition Application Deployment Guide.

Pooling Parameters

One of the most important parameters for GlassFish Server pooling is steady-pool-size. When steady-pool-size is set to a value greater than 0, the container not only pre-populates the bean pool with the specified number of beans, but also attempts to ensure that this number of beans is always available in the free pool. This ensures that there are enough beans in the ready-to-serve state to process user requests.

Note that the steady-pool-size and max-pool-size parameters only govern the number of instances that are pooled over a long period of time. They do not necessarily guarantee that the number of instances that may exist in the JVM at a given time will not exceed the value specified by max-pool-size. For example, suppose an idle stateless session container has a fully-populated pool with a steady-pool-size of 10. If 20 concurrent requests arrive for the EJB component, the container creates 10 additional instances to satisfy the burst of requests. The advantage of this is that it prevents the container from blocking any of the incoming requests. However, if the activity dies down to 10 or fewer concurrent requests, the additional 10 instances are discarded.

Another parameter, pool-idle-timeout-in-seconds, allows the administrator to specify the amount of time a bean instance can be idle in the pool. When pool-idle-timeout-in-seconds is set to greater than 0, the container removes or destroys any bean instance that is idle for this specified duration.

Caching Parameters

GlassFish Server provides a way that completely avoids caching of entity beans, using commit option C. Commit option C is particularly useful if beans are accessed in large number but very rarely reused. For additional information, refer to Commit Options.

The GlassFish Server caches can be either bounded or unbounded. Bounded caches have limits on the number of beans that they can hold beyond which beans are passivated. For stateful session beans, there are three ways (LRU, NRU and FIFO) of picking victim beans when cache overflow occurs. Caches can also passivate beans that are idle (not accessed for a specified duration).

Priority Based Scheduling of Remote Bean Invocations

You can create multiple thread pools, each having its own work queues. An optional element in the glassfish-ejb-jar.xml file, use-thread-pool-id, specifies the thread pool that processes the requests for the bean. The bean must have a remote interface, or use-thread-pool-id is ignored. You can create different thread pools and specify the appropriate thread pool ID for a bean that requires a quick response time. If there is no such thread pool configured or if the element is absent, the default thread pool is used.

Immediate Flushing

Normally, all entity bean updates within a transaction are batched and executed at the end of the transaction. The only exception is the database flush that precedes execution of a finder or select query.

Since a transaction often spans many method calls, you might want to find out if the updates made by a method succeeded or failed immediately after method execution. To force a flush at the end of a method’s execution, use the flush-at-end-of-method element in the glassfish-ejb-jar.xml file. Only non-finder methods in an entity bean can be flush-enabled. (For an EJB 2.1 bean, these methods must be in the Local, Local Home, Remote, or Remote Home interface.) See "flush-at-end-of-method" in GlassFish Server Open Source Edition Application Deployment Guide.

Upon completion of the method, the EJB container updates the database. Any exception thrown by the underlying data store is wrapped as follows:

  • If the method that triggered the flush is a create method, the exception is wrapped with CreateException.

  • If the method that triggered the flush is a remove method, the exception is wrapped with RemoveException.

  • For all other methods, the exception is wrapped with EJBException.

All normal end-of-transaction database synchronization steps occur regardless of whether the database has been flushed during the transaction.

EJB Timer Service

The EJB Timer Service uses a database to store persistent information about EJB timers. The EJB Timer Service in GlassFish Server is preconfigured to use an embedded version of the Apache Derby database.

The EJB Timer Service configuration can store persistent timer information in any database supported by the GlassFish Server for persistence. For a list of the JDBC drivers currently supported by the GlassFish Server, see the GlassFish Server Open Source Edition Release Notes. For configurations of supported and other drivers, see "Configuration Specifics for JDBC Drivers" in GlassFish Server Open Source Edition Administration Guide.

The timer service is automatically enabled when you deploy an application or module that uses it. You can verify that the timer service is running by accessing the following URL:

http://localhost:8080/ejb-timer-service-app/timer

To change the database used by the EJB Timer Service, set the EJB Timer Service’s Timer DataSource setting to a valid JDBC resource. If the EJB Timer Service has already been started in a server instance, you must also create the timer database table. DDL files are located in as-install`/lib/install/databases`.

Using the EJB Timer Service is equivalent to interacting with a single JDBC resource manager. If an EJB component or application accesses a database either directly through JDBC or indirectly (for example, through an entity bean’s persistence mechanism), and also interacts with the EJB Timer Service, its data source must be configured with an XA JDBC driver.

You can change the following EJB Timer Service settings. You must restart the server for the changes to take effect.

Minimum Delivery Interval

Specifies the minimum time in milliseconds before an expiration for a particular timer can occur. This guards against extremely small timer increments that can overload the server. The default is 1000.

Maximum Redeliveries

Specifies the maximum number of times the EJB timer service attempts to redeliver a timer expiration after an exception or rollback of a container-managed transaction. The default is 1.

Redelivery Interval

Specifies how long in milliseconds the EJB timer service waits after a failed ejbTimeout delivery before attempting a redelivery. The default is 5000.

Timer DataSource

Specifies the database used by the EJB Timer Service. The default is jdbc/__TimerPool.

Caution:

Do not use the jdbc/TimerPool resource for timers in clustered GlassFish Server environments. You must instead use a custom JDBC resource or the jdbc/default resource. See the instructions below, in To Deploy an EJB Timer to a Cluster. Also refer to "Enabling the jdbc/__default Resource in a Clustered Environment" in GlassFish Server Open Source Edition Administration Guide.

For information about the asadmin list-timers and asadmin migrate-timers subcommands, see the GlassFish Server Open Source Edition Reference Manual. For information about migrating EJB timers, see "Migrating EJB Timers" in GlassFish Server Open Source Edition High Availability Administration Guide.

You can use the --keepstate option of the asadmin redeploy command to retain EJB timers between redeployments.

The default for --keepstate is false. This option is supported only on the default server instance, named server. It is not supported and ignored for any other target.

When the --keepstate is set to true, each application that uses an EJB timer is assigned an ID in the timer database. The EJB object that is associated with a given application is assigned an ID that is constructed from the application ID and a numerical suffix. To preserve active timer data, GlassFish Server stores the application ID and the EJB ID in the timer database. To restore the data, the class loader of the newly redeployed application retrieves the EJB timers that correspond to these IDs from the timer database.

For more information about the asadmin redeploy command, see the GlassFish Server Open Source Edition Reference Manual.

To Deploy an EJB Timer to a Cluster

This procedure explains how to deploy an EJB timer to a cluster.

By default, the GlassFish Server 5.0 timer service points to the preconfigured jdbc/__TimerPool resource, which uses an embedded Apache Derby database configuration that will not work in clustered environments.

The problem is that embedded Apache Derby database runs in the GlassFish Server Java VM, so when you use the jdbc/__TimerPool resource, each DAS and each clustered server instance will have its own database table. Because of this, clustered server instances will not be able to find the database table on the DAS, and the DAS will not be able to find the tables on the clustered server instances.

The solution is to use either a custom JDBC resource or the jdbc/__default resource that is preconfigured but not enabled by default in GlassFish Server. The jdbc/__default resource does not use the embedded Apache Derby database by default.

Before You Begin

If creating a new timer resource, the resource should be created before deploying applications that will use the timer.

Caution

Do not use the jdbc/__TimerPool resource for timers in clustered GlassFish Server environments. You must instead use a custom JDBC resource or the jdbc/__default resource. See "oEnabling the jdbc/__default Resource in a Clustered Environment" in GlassFish Server Open Source Edition Administration Guide.

  1. Execute the following command:

asadmin set configs.config.cluster_name-config.ejb-container.ejb-timer-service.timer-
datasource=jdbc/my-timer-resource
  1. Restart the DAS and the target cluster(s).

asadmin stop-cluster cluster-name
asadmin stop-domain domain-name
asadmin start-domain domain-name
asadmin start-cluster cluster-name

Troubleshooting

If you inadvertently used the jdbc/__TimerPool resource for your EJB timer in a clustered GlassFish Server environment, the DAS and the clustered server instances will be using separate Apache Derby database tables that are running in individual Java VMs. For timers to work in a clustered environment, the DAS and the clustered server instances must share a common database table.

If you attempt to deploy an application with EJB timers without setting the timer resource correctly, the startup will fail, and you will be left with a marker file, named ejb-timer-service-app, on the DAS that will prevent the Timer Service from correctly creating the database table.

The solution is to remove the marker file on the DAS, restart the DAS and the clusters, and then redploy any applications that rely on the offending EJB timer. The marker file is located on the DAS in domain-dir`/generated/ejb/``ejb-timer-service-app`.

Using Session Beans

This section provides guidelines for creating session beans in the GlassFish Server environment.

The following topics are addressed here:

Information on session beans is contained in the Enterprise JavaBeans Specification, v3.1.

About the Session Bean Containers

Like an entity bean, a session bean can access a database through Java Database Connectivity (JDBC) calls. A session bean can also provide transaction settings. These transaction settings and JDBC calls are referenced by the session bean’s container, allowing it to participate in transactions managed by the container.

A container managing stateless session beans has a different charter from a container managing stateful session beans.

The following topics are addressed here:

Stateless Container

The stateless container manages stateless session beans, which, by definition, do not carry client-specific states. All session beans (of a particular type) are considered equal.

A stateless session bean container uses a bean pool to service requests. The GlassFish Server specific deployment descriptor file, glassfish-ejb-jar.xml, contains the properties that define the pool:

  • steady-pool-size

  • resize-quantity

  • max-pool-size

  • pool-idle-timeout-in-seconds

For more information about glassfish-ejb-jar.xml, see "The glassfish-ejb-jar.xml File" in GlassFish Server Open Source Edition Application Deployment Guide.

The GlassFish Server provides the wscompile and wsdeploy tools to help you implement a web service endpoint as a stateless session bean. For more information about these tools, see the GlassFish Server Open Source Edition Reference Manual.

Stateful Container

The stateful container manages the stateful session beans, which, by definition, carry the client-specific state. There is a one-to-one relationship between the client and the stateful session beans. At creation, each stateful session bean (SFSB) is given a unique session ID that is used to access the session bean so that an instance of a stateful session bean is accessed by a single client only.

Stateful session beans are managed using cache. The size and behavior of stateful session beans cache are controlled by specifying the following glassfish-ejb-jar.xml parameters:

  • max-cache-size

  • resize-quantity

  • cache-idle-timeout-in-seconds

  • removal-timeout-in-seconds

  • victim-selection-policy

The max-cache-size element specifies the maximum number of session beans that are held in cache. If the cache overflows (when the number of beans exceeds max-cache-size), the container then passivates some beans or writes out the serialized state of the bean into a file. The directory in which the file is created is obtained from the EJB container using the configuration APIs.

For more information about glassfish-ejb-jar.xml, see "The glassfish-ejb-jar.xml File" in GlassFish Server Open Source Edition Application Deployment Guide.

The passivated beans are stored on the file system. The Session Store Location setting in the EJB container allows the administrator to specify the directory where passivated beans are stored. By default, passivated stateful session beans are stored in application-specific subdirectories created under domain-dir`/session-store`.

Note

Make sure the delete option is set in the server.policy file, or expired file-based sessions might not be deleted properly. For more information about server.policy, see The server.policy File.

The Session Store Location setting also determines where the session state is persisted if it is not highly available; see Choosing a Persistence Store.

Stateful Session Bean Failover

An SFSB’s state can be saved in a persistent store in case a server instance fails. The state of an SFSB is saved to the persistent store at predefined points in its life cycle. This is called checkpointing. If SFSB checkpointing is enabled, checkpointing generally occurs after any transaction involving the SFSB is completed, even if the transaction rolls back.

However, if an SFSB participates in a bean-managed transaction, the transaction might be committed in the middle of the execution of a bean method. Since the bean’s state might be undergoing transition as a result of the method invocation, this is not an appropriate instant to checkpoint the bean’s state. In this case, the EJB container checkpoints the bean’s state at the end of the corresponding method, provided the bean is not in the scope of another transaction when that method ends. If a bean-managed transaction spans across multiple methods, checkpointing is delayed until there is no active transaction at the end of a subsequent method.

The state of an SFSB is not necessarily transactional and might be significantly modified as a result of non-transactional business methods. If this is the case for an SFSB, you can specify a list of checkpointed methods. If SFSB checkpointing is enabled, checkpointing occurs after any checkpointed methods are completed.

The following table lists the types of references that SFSB failover supports. All objects bound into an SFSB must be one of the supported types. In the table, No indicates that failover for the object type might not work in all cases and that no failover support is provided. However, failover might work in some cases for that object type. For example, failover might work because the class implementing that type is serializable.

Table 8-1 Object Types Supported for Java EE Stateful Session Bean State Failover

Java Object Type Failover Support

Colocated or distributed stateless session, stateful session, or entity bean reference

Yes

JNDI context

Yes, InitialContext and java:comp/env

UserTransaction

Yes, but if the instance that fails is never restarted, any prepared global transactions are lost and might not be correctly rolled back or committed.

JDBC DataSource

No

Java Message Service (JMS) ConnectionFactory, Destination

No

JavaMail Session

No

Connection Factory

No

Administered Object

No

Web service reference

No

Serializable Java types

Yes

Extended persistence context

No

For more information about the InitialContext, see Accessing the Naming Context. For more information about transaction recovery, see Using the Transaction Service. For more information about Administered Objects, see "Administering JMS Physical Destinations" in GlassFish Server Open Source Edition Administration Guide.

Note

Idempotent URLs are supported along the HTTP path, but not the RMI-IIOP path. For more information, see Configuring Idempotent URL Requests.

If a server instance to which an RMI-IIOP client request is sent crashes during the request processing (before the response is prepared and sent back to the client), an error is sent to the client. The client must retry the request explicitly. When the client retries the request, the request is sent to another server instance in the cluster, which retrieves session state information for this client.

HTTP sessions can also be saved in a persistent store in case a server instance fails. In addition, if a distributable web application references an SFSB, and the web application’s session fails over, the EJB reference is also failed over. For more information, see Distributed Sessions and Persistence.

If an SFSB that uses session persistence is undeployed while the GlassFish Server instance is stopped, the session data in the persistence store might not be cleared. To prevent this, undeploy the SFSB while the GlassFish Server instance is running.

Configure SFSB failover by:

Choosing a Persistence Store

The following types of persistent storage are supported for passivation and checkpointing of the SFSB state:

  • The local file system - Allows a single server instance to recover the SFSB state after a failure and restart. This store also provides passivation and activation of the state to help control the amount of memory used. This option is not supported in a production environment that requires SFSB state persistence. This is the default storage mechanism if availability is not enabled.

  • Other servers - Uses other server instances in the cluster for session persistence. Clustered server instances replicate session state. Each backup instance stores the replicated data in memory. This is the default storage mechanism if availability is enabled.

Choose the persistence store in one of the following ways:

  • To use the local file system, first disable availability. Select the Availability Service component under the relevant configuration in the Administration Console. Uncheck the Availability Service box. Then select the EJB Container component and edit the Session Store Location value. The default is domain-dir`/session-store`.

  • To use other servers, select the Availability Service component under the relevant configuration in the Administration Console. Check the Availability Service box. To enable availability for the EJB container, select the EJB Container Availability tab, then check the Availability Service box. All instances in an GlassFish Server cluster should have the same availability settings to ensure consistent behavior.

For more information about SFSB state persistence, see the GlassFish Server Open Source Edition High Availability Administration Guide.

Using the --keepstate Option

If you are using the file system for persistence, you can use the --keepstate option of the asadmin redeploy command to retain the SFSB state between redeployments.

The default for --keepstate is false. This option is supported only on the default server instance, named server. It is not supported and ignored for any other target.

Some changes to an application between redeployments prevent this feature from working properly. For example, do not change the set of instance variables in the SFSB bean class.

If any active SFSB instance fails to be preserved or restored, none of the SFSB instances will be available when the redeployment is complete. However, the redeployment continues and a warning is logged.

To preserve active state data, GlassFish Server serializes the data and saves it in memory. To restore the data, the class loader of the newly redeployed application deserializes the data that was previously saved.

For more information about the asadmin redeploy command, see the GlassFish Server Open Source Edition Reference Manual.

Using the --asyncreplication Option

If you are using replication on other servers for persistence, you can use the --asyncreplication option of the asadmin deploy command to specify that SFSB states are first buffered and then replicated using a separate asynchronous thread. If --asyncreplication is set to true (default), performance is improved but availability is reduced. If the instance where states are buffered but not yet replicated fails, the states are lost. If set to false, performance is reduced but availability is guaranteed. States are not buffered but immediately transmitted to other instances in the cluster.

For more information about the asadmin deploy command, see the GlassFish Server Open Source Edition Reference Manual.

Enabling Checkpointing

The following sections describe how to enable SFSB checkpointing:

Server Instance and EJB Container Levels

To enable SFSB checkpointing at the server instance or EJB container level, see Choosing a Persistence Store.

Application and EJB Module Levels

To enable SFSB checkpointing at the application or EJB module level during deployment, use the asadmin deploy or asadmin deploydir command with the --availabilityenabled option set to true. For details, see the GlassFish Server Open Source Edition Reference Manual.

SFSB Level

To enable SFSB checkpointing at the SFSB level, set availability-enabled="true" in the ejb element of the SFSB’s glassfish-ejb-jar.xml file as follows:

<glassfish-ejb-jar>
   ...
   <enterprise-beans>
      ...
      <ejb availability-enabled="true">
         <ejb-name>MySFSB</ejb-name>
      </ejb>
   ...
   </enterprise-beans>
</glassfish-ejb-jar>

Specifying Methods to Be Checkpointed

If SFSB checkpointing is enabled, checkpointing generally occurs after any transaction involving the SFSB is completed, even if the transaction rolls back.

To specify additional optional checkpointing of SFSBs at the end of non-transactional business methods that cause important modifications to the bean’s state, use the checkpoint-at-end-of-method element within the ejb element in glassfish-ejb-jar.xml.

For example:

<glassfish-ejb-jar>
   ...
   <enterprise-beans>
      ...
      <ejb availability-enabled="true">
         <ejb-name>ShoppingCartEJB</ejb-name>
         <checkpoint-at-end-of-method>
            <method>
               <method-name>addToCart</method-name>
            </method>
         </checkpoint-at-end-of-method>
      </ejb>
      ...
   </enterprise-beans>
</glassfish-ejb-jar>

For details, see "checkpoint-at-end-of-method" in GlassFish Server Open Source Edition Application Deployment Guide.

The non-transactional methods in the checkpoint-at-end-of-method element can be the following:

  • create methods defined in the home or business interface of the SFSB, if you want to checkpoint the initial state of the SFSB immediately after creation

  • For SFSBs using container managed transactions only, methods in the remote interface of the bean marked with the transaction attribute TX_NOT_SUPPORTED or TX_NEVER

  • For SFSBs using bean managed transactions only, methods in which a bean managed transaction is neither started nor committed

Any other methods mentioned in this list are ignored. At the end of invocation of each of these methods, the EJB container saves the state of the SFSB to persistent store.

Note

If an SFSB does not participate in any transaction, and if none of its methods are explicitly specified in the checkpoint-at-end-of-method element, the bean’s state is not checkpointed at all even if availability-enabled="true" for this bean.

For better performance, specify a small subset of methods. The methods chosen should accomplish a significant amount of work in the context of the Java EE application or should result in some important modification to the bean’s state.

Session Bean Restrictions and Optimizations

This section discusses restrictions on developing session beans and provides some optimization guidelines.

Optimizing Session Bean Performance

For stateful session beans, colocating the stateful beans with their clients so that the client and bean are executing in the same process address space improves performance.

Restricting Transactions

The following restrictions on transactions are enforced by the container and must be observed as session beans are developed:

  • A session bean can participate in, at most, a single transaction at a time.

  • If a session bean is participating in a transaction, a client cannot invoke a method on the bean such that the trans-attribute element (or @TransactionAttribute annotation) in the ejb-jar.xml file would cause the container to execute the method in a different or unspecified transaction context or an exception is thrown.

  • If a session bean instance is participating in a transaction, a client cannot invoke the remove method on the session object’s home or business interface object, or an exception is thrown.

EJB Singletons

EJB Singletons are created for each server instance in a cluster, and not once per cluster.

Using Read-Only Beans

A read-only bean is an EJB 2.1 entity bean that is never modified by an EJB client. The data that a read-only bean represents can be updated externally by other enterprise beans, or by other means, such as direct database updates.

Note

Read-only beans are specific to the GlassFish Server and are not part of the Enterprise JavaBeans Specification, v2.1. Use of this feature for an EJB 2.1 bean results in a non-portable application.

To make an EJB 3.0 entity bean read-only, use @Column annotations to mark its columns insertable=false and updatable=false.

Read-only beans are best suited for situations where the underlying data never changes, or changes infrequently.

The following topics are addressed here:

Read-Only Bean Characteristics and Life Cycle

Read-only beans are best suited for situations where the underlying data never changes, or changes infrequently. For example, a read-only bean can be used to represent a stock quote for a particular company, which is updated externally. In such a case, using a regular entity bean might incur the burden of calling ejbStore, which can be avoided by using a read-only bean.

Read-only beans have the following characteristics:

  • Only entity beans can be read-only beans.

  • Either bean-managed persistence (BMP) or container-managed persistence (CMP) is allowed. If CMP is used, do not create the database schema during deployment. Instead, work with your database administrator to populate the data into the tables. See Using Container-Managed Persistence.

  • Only container-managed transactions are allowed; read-only beans cannot start their own transactions.

  • Read-only beans don’t update any bean state.

  • ejbStore is never called by the container.

  • ejbLoad is called only when a transactional method is called or when the bean is initially created (in the cache), or at regular intervals controlled by the bean’s refresh-period-in-seconds element in the glassfish-ejb-jar.xml file.

  • The home interface can have any number of find methods. The return type of the find methods must be the primary key for the same bean type (or a collection of primary keys).

  • If the data that the bean represents can change, then refresh-period-in-seconds must be set to refresh the beans at regular intervals. ejbLoad is called at this regular interval.

A read-only bean comes into existence using the appropriate find methods.

Read-only beans are cached and have the same cache properties as entity beans. When a read-only bean is selected as a victim to make room in the cache, ejbPassivate is called and the bean is returned to the free pool. When in the free pool, the bean has no identity and is used only to serve any finder requests.

Read-only beans are bound to the naming service like regular read-write entity beans, and clients can look up read-only beans the same way read-write entity beans are looked up.

Read-Only Bean Good Practices

For best results, follow these guidelines when developing read-only beans:

  • Avoid having any create or remove methods in the home interface.

  • Use any of the valid EJB 2.1 transaction attributes for the trans-attribute element.
    The reason for having TX_SUPPORTED is to allow reading uncommitted data in the same transaction. Also, the transaction attributes can be used to force ejbLoad.

Refreshing Read-Only Beans

There are several ways of refreshing read-only beans, as addressed in the following sections:

Invoking a Transactional Method

Invoking any transactional method invokes ejbLoad.

Refreshing Periodically

Use the refresh-period-in-seconds element in the glassfish-ejb-jar.xml file to refresh a read-only bean periodically.

  • If the value specified in refresh-period-in-seconds is zero or not specified, which is the default, the bean is never refreshed (unless a transactional method is accessed).

  • If the value is greater than zero, the bean is refreshed at the rate specified.

Note

This is the only way to refresh the bean state if the data can be modified external to the GlassFish Server.

By default, a single timer is used for all instances of a read-only bean. When that timer fires, all bean instances are marked as expired and are refreshed from the database the next time they are used.

Use the -Dcom.sun.ejb.containers.readonly.relative.refresh.mode=true flag to refresh each bean instance independently upon access if its refresh period has expired. The default is false. Note that each instance still has the same refresh period. This additional level of granularity can improve the performance of read-only beans that do not need to be refreshed at the same time.

To set this flag, use the asadmin create-jvm-options command. For example:

asadmin create-jvm-options -Dcom.sun.ejb.containers.readonly.relative.refresh.mode=true

Refreshing Programmatically

Typically, beans that update any data that is cached by read-only beans need to notify the read-only beans to refresh their state. Use ReadOnlyBeanNotifier to force the refresh of read-only beans.

To do this, invoke the following methods on the ReadOnlyBeanNotifier bean:

public interface ReadOnlyBeanNotifier extends java.rmi.Remote {
   refresh(Object PrimaryKey) throws RemoteException;
 }

The implementation of the ReadOnlyBeanNotifier interface is provided by the container. The bean looks up ReadOnlyBeanNotifier using a fragment of code such as the following example:

com.sun.appserv.ejb.ReadOnlyBeanHelper helper =
  new com.sun.appserv.ejb.ReadOnlyBeanHelper();
com.sun.appserv.ejb.ReadOnlyBeanNotifier notifier =
  helper.getReadOnlyBeanNotifier("java:comp/env/ejb/ReadOnlyCustomer");
notifier.refresh(PrimaryKey);

For a local read-only bean notifier, the lookup has this modification:

helper.getReadOnlyBeanLocalNotifier("java:comp/env/ejb/LocalReadOnlyCustomer");

Beans that update any data that is cached by read-only beans need to call the refresh methods. The next (non-transactional) call to the read-only bean invokes ejbLoad.

For Javadoc tool pages relevant to read-only beans, go to http://glassfish.java.net/nonav/docs/v3/api/ and click on the com.sun.appserv.ejb package.

Deploying Read-Only Beans

Read-only beans are deployed in the same manner as other entity beans. However, in the entry for the bean in the glassfish-ejb-jar.xml file, the is-read-only-bean element must be set to true. That is:

<is-read-only-bean>true</is-read-only-bean>

Also, the refresh-period-in-seconds element in the glassfish-ejb-jar.xml file can be set to some value that specifies the rate at which the bean is refreshed. If this element is missing, no refresh occurs.

All requests in the same transaction context are routed to the same read-only bean instance. Set the allow-concurrent-access element to either true (to allow concurrent accesses) or false (to serialize concurrent access to the same read-only bean). The default is false.

For further information on these elements, refer to "The glassfish-ejb-jar.xml File" in GlassFish Server Open Source Edition Application Deployment Guide.

Using Message-Driven Beans

This section describes message-driven beans and explains the requirements for creating them in the GlassFish Server environment.

The following topics are addressed here:

Message-Driven Bean Configuration

The following topics are addressed here:

For information about setting up load balancing for message-driven beans, see Load-Balanced Message Inflow.

Connection Factory and Destination

A message-driven bean is a client to a Connector inbound resource adapter. The message-driven bean container uses the JMS service integrated into the GlassFish Server for message-driven beans that are JMS clients. JMS clients use JMS Connection Factory- and Destination-administered objects. A JMS Connection Factory administered object is a resource manager Connection Factory object that is used to create connections to the JMS provider.

The mdb-connection-factory element in the glassfish-ejb-jar.xml file for a message-driven bean specifies the connection factory that creates the container connection to the JMS provider.

The jndi-name element of the ejb element in the glassfish-ejb-jar.xml file specifies the JNDI name of the administered object for the JMS Queue or Topic destination that is associated with the message-driven bean.

Message-Driven Bean Pool

The container manages a pool of message-driven beans for the concurrent processing of a stream of messages. The glassfish-ejb-jar.xml file contains the elements that define the pool (that is, the bean-pool element):

  • steady-pool-size

  • resize-quantity

  • max-pool-size

  • pool-idle-timeout-in-seconds

For more information about glassfish-ejb-jar.xml, see "The glassfish-ejb-jar.xml File" in GlassFish Server Open Source Edition Application Deployment Guide.

Domain-Level Settings

You can control the following domain-level message-driven bean settings in the EJB container:

Initial and Minimum Pool Size

Specifies the initial and minimum number of beans maintained in the pool. The default is 0.

Maximum Pool Size

Specifies the maximum number of beans that can be created to satisfy client requests. The default is 3`2`.

Pool Resize Quantity

Specifies the number of beans to be created if a request arrives when the pool is empty (subject to the Initial and Minimum Pool Size), or the number of beans to remove if idle for more than the Idle Timeout. The default is 8.

Idle Timeout

Specifies the maximum time in seconds that a bean can remain idle in the pool. After this amount of time, the bean is destroyed. The default is 600 (10 minutes). A value of 0 means a bean can remain idle indefinitely.

For information on monitoring message-driven beans, click the Help button in the Administration Console. Select the Stand-Alone Instances component, select the instance from the table, and select the Monitor tab. Or select the Clusters component, select the cluster from the table, select the Instances tab, select the instance from the table, and select the Monitor tab.

Note

Running monitoring when it is not needed might impact performance, so you might choose to turn monitoring off when it is not in use. For details, see "oAdministering the Monitoring Service" in GlassFish Server Open Source Edition Administration Guide.

Message-Driven Bean Restrictions and Optimizations

This section discusses the following restrictions and performance optimizations that pertain to developing message-driven beans:

Pool Tuning and Monitoring

The message-driven bean pool is also a pool of threads, with each message-driven bean instance in the pool associating with a server session, and each server session associating with a thread. Therefore, a large pool size also means a high number of threads, which impacts performance and server resources.

When configuring message-driven bean pool properties, make sure to consider factors such as message arrival rate and pattern, onMessage method processing time, overall server resources (threads, memory, and so on), and any concurrency requirements and limitations from other resources that the message-driven bean accesses.

When tuning performance and resource usage, make sure to consider potential JMS provider properties for the connection factory used by the container (the mdb-connection-factory element in the glassfish-ejb-jar.xml file). For example, you can tune the Open Message Queue flow control related properties for connection factory in situations where the message incoming rate is much higher than max-pool-size can handle.

Refer to "Administering the Monitoring Service" in GlassFish Server Open Source Edition Administration Guide for information on how to get message-driven bean pool statistics.

The onMessage Runtime Exception

Message-driven beans, like other well-behaved MessageListeners, should not, in general, throw runtime exceptions. If a message-driven bean’s onMessage method encounters a system-level exception or error that does not allow the method to successfully complete, the Enterprise JavaBeans Specification, v3.0 provides the following guidelines:

  • If the bean method encounters a runtime exception or error, it should simply propagate the error from the bean method to the container.

  • If the bean method performs an operation that results in a checked exception that the bean method cannot recover, the bean method should throw the javax.ejb.EJBException that wraps the original exception.

  • Any other unexpected error conditions should be reported using javax.ejb.EJBException (javax.ejb.EJBException is a subclass of java.lang.RuntimeException).

Under container-managed transaction demarcation, upon receiving a runtime exception from a message-driven bean’s onMessage method, the container rolls back the container-started transaction and the message is redelivered. This is because the message delivery itself is part of the container-started transaction. By default, the GlassFish Server container closes the container’s connection to the JMS provider when the first runtime exception is received from a message-driven bean instance’s onMessage method. This avoids potential message redelivery looping and protects server resources if the message-driven bean’s onMessage method continues misbehaving. To change this default container behavior, use the cmt-max-runtime-exceptions property of the MDB container. Here is an example asadmin set command that sets this property:

asadmin set server-config.mdb-container.property.cmt-max-runtime-exceptions="5"

For more information about the asadmin set command, see the GlassFish Server Open Source Edition Reference Manual.

The cmt-max-runtime-exceptions property specifies the maximum number of runtime exceptions allowed from a message-driven bean’s onMessage method before the container starts to close the container’s connection to the message source. By default this value is 1; -1 disables this container protection.

A message-driven bean’s onMessage method can use the javax.jms.Message.getJMSRedelivered method to check whether a received message is a redelivered message.

Note

The cmt-max-runtime-exceptions property is deprecated.


Previous Next Contents
Eclipse Foundation Logo  Copyright © 2019, Oracle and/or its affiliates. All rights reserved.