Enterprise JavaBeans Components and CORBA Clients: A Developer Guide

This paper discusses how to enable a client written in any language supported by CORBA to access Enterprise JavaBeans components (EJB components). This paper is directed at programmers with advanced knowledge of both the Java Platform, Enterprise Edition (Java EE) and CORBA (Common Object Request Broker Architecture).

Java EE technology simplifies enterprise applications by basing them on standardized, modular and re-usable components based on the Enterprise JavaBeans (EJB) architecture, providing a complete set of services to those components, and handling many details of application behavior automatically. By automating many of the time-consuming and difficult tasks of application development, Java EE technology allows enterprise developers to focus on adding value, that is, enhancing business logic, rather than building infrastructure.

The EJB server-side component model simplifies development of middleware components that are transactional, scalable, and portable. Enterprise JavaBeans servers reduce the complexity of developing middleware by providing automatic support for middleware services such as transactions, security, database connectivity, and more.

CORBA is an Object Management Group (OMG) standard that is an open, vendor-independent architecture and infrastructure that computer applications use to work together over networks. Using the standard Internet Inter-ORB Protocol (IIOP), a CORBA-based program from any vendor, on almost any computer, operating system, programming language, and network, can interoperate with a CORBA-based program from the same or another vendor, on almost any other computer, operating system, programming language, and network. To learn more about CORBA, see the Object Management Group website.

CORBA technology complements the Java platform by providing a distributed objects framework, services to support that framework, and interoperability with other languages. CORBA technology is an integral part of the Java SE platform, being used in Enterprise JavaBeans components, Java Remote Method Invocation APIs running over Internet Inter-ORB Protocol ("Java RMI-IIOP"), and Java IDL APIs ("Java IDL").

OMG Interface Definition Language (IDL) is used to describe the interfaces being implemented by the remote objects. IDL is used to define the name of the interface and the names of each of the attributes and methods. Once you create the IDL file, you can use an IDL compiler to generate the client stub and the server skeleton in any language for which the OMG has defined a specification for such language mapping. To learn more about OMG IDL, see the OMG IDL web page.

Java IDL makes it possible for distributed Java applications to transparently invoke operations on remote network services using the industry standard OMG IDL and IIOP defined by the Object Management Group (http://www.omg.org). Java RMI over IIOP APIs enable the programming of CORBA servers and applications via the javax.rmi API.

Developers who program EJB components follow the Java RMI programming model for their distributed object model, where the required transport common across all application servers is Java RMI-IIOP. In heterogeneous server environments, the standard mapping of the EJB architecture to CORBA enables the following interoperability:

The rest of this document provides an example of a CORBA client application accessing an enterprise bean object. In this document, a CORBA client means a client application written in any language supported by CORBA, including the Java programming language, C++, C, Smalltalk, COBOL, Ada, Lisp, or Python. While the Java code in this example is specific to enterprise beans, the process for developing a CORBA client that accesses a server created using the Java RMI-IIOP APIs is the same.

Links to similar example applications from other vendors who implement Java EE can be found in Links to similar examples.

Developing a CORBA Client that Accesses an Enterprise JavaBean Component

This is an example of how to develop a CORBA client application that accesses an EJB component. In this example, the client is written in the C++ programming language, but the client could be written in any language supported by CORBA.

The general process for developing a CORBA client so that it can access an enterprise bean is demonstrated in the following sections:

  1. Write the Enterprise JavaBean component
  2. Generate the CORBA IDL
  3. Create a CORBA client
  4. Deploy the Enterprise JavaBean component
  5. Run the client executable

This document also includes:

In order to make the example simple, we have taken a few shortcuts. For information on building more advanced solutions, see Tips for complex interfaces.

  1. Part I: Write the Enterprise JavaBean component

    The following examples show the code for an enterprise bean that will accept simple String log messages sent to the application server from Java RMI-IIOP and CORBA clients. The enterprise bean prints them on the server along with the current server time.

  2. Create the files Logger.java , LoggerHome.java , LoggerEJB.java , and LogMessage.java in the /Java/src/ejbinterop directory.


    The file Logger.java is the enterprise bean's remote interface, and as such, it extends EJBObject . A remote interface provides the remote client view of an EJB object and defines the business methods callable by a remote client.

    //Code Example 1: Logger.java
    package ejbinterop;
    import javax.ejb.EJBObject;
    import java.rmi.RemoteException;
     * Accepts simple String log messages and prints
     * them on the server.
    public interface Logger extends EJBObject
         * Logs the given message on the server with
         * the current server time.
        void logString(String message) throws RemoteException;


    The file LoggerHome.java extends EJBHome . The EJBHome interface must be extended by all EJB component's remote home interfaces. A home interface defines the methods that allow a remote client to create, find, and remove EJB objects, as well as home business methods that are not specific to an EJB instance.

    //Code Example 2: LoggerHome.java
    package ejbinterop;
    import java.rmi.RemoteException;
    import javax.ejb.EJBHome;
    import javax.ejb.CreateException;
    public interface LoggerHome extends EJBHome
        Logger create() throws RemoteException, CreateException;


    The file LoggerEJB.java contains the code for a session bean. A session bean is an enterprise bean that is created by a client and that usually exists only for the duration of a single client-server session. A session bean performs operations such as calculations or accessing a database for the client. In this example, the enterprise bean accepts simple String log messages from the client and prints them on the server.

    package ejbinterop;
    import javax.ejb.*;
    import java.util.*;
    import java.rmi.*;
    import java.io.*;
     * Accepts simple String log messages and prints
     * them on the server.
    public class LoggerEJB implements SessionBean {
        public LoggerEJB() {}
        public void ejbCreate() {}
        public void ejbRemove() {}
        public void ejbActivate() {}
        public void ejbPassivate() {}
        public void setSessionContext(SessionContext sc) {}
         * Logs the given message on the server with
         * the current server time.
        public void logString(String message) {
            LogMessage msg = new LogMessage(message);


    The file LogMessage.java takes the current date and time, creates a formatted String showing the message, and prints the message to the server.

    package ejbinterop;
    import java.io.Serializable;
    import java.util.Date;
    import java.text.*;
     * Simple message class that handles pretty
     * printing of log messages.
    public class LogMessage implements Serializable
        private String message;
        private long datetime;
         * Constructor taking the message. This will
         * take the current date and time.
        public LogMessage(String msg) {
            message = msg;
            datetime = (new Date()).getTime();
         * Creates a formatted String showing the message.
        public String toString() {
            StringBuffer sbuf = new StringBuffer();
            DateFormat dformat
                = DateFormat.getDateTimeInstance(DateFormat.MEDIUM,
            FieldPosition fpos = new
            dformat.format(new Date(datetime), sbuf, fpos);
            sbuf.append(": ");
            return sbuf.toString();

  3. Compile the files written in this section, for example,
    javac -classpath $JAVA_EE_HOME/lib/java_ee.jar:.. *.java

    These commands create class files for all of the .java files in the current directory. This command and others in this paper assume that the JAVA_EE_HOME environment variable has been set correctly. Using $JAVA_EE_HOME is a convention of the UNIX operating environment. Substitute %JAVA_EE_HOME% when working in the Microsoft Windows operating environment.

    Part II: Generate the CORBA IDL

    This sections discusses generating the Interface Definition Language (IDL) files from the Java class files generated in the previous section. In this example, we will use the rmic compiler to map the Java code to IDL. IDL provides a purely declarative, programming language-independent way of specifying an object's API.

  4. Run the rmic compiler against the Java class files generated in the previous step as follows:
    rmic -idl -noValueMethods -classpath
      -d <path_to_where_idl_files_should_be_generated>
      ejbinterop.Logger ejbinterop.LoggerHome

    In the preceding example, we are including the JAR file containing definitions for the javax.ejb package as well as the directory to our ejbinterop files. If you're using the Java Platform, Enterprise Edition (Java EE), Reference Implementation (RI), the JAR files are located in $JAVA_EE_HOME/lib/java_ee.jar .

    In the command line for rmic above, we recommend a shortcut -- using the noValueMethods option. This option tells rmic to skip any methods with parameter or return types that would be mapped to CORBA value types. The advantage is that it will prevent us from generating a lot of unnecessary IDL that we might have to implement in the C++ client. The disadvantage is that we can only use primitive data types, arrays, and Strings as parameters or return values, and not our own Java class types. Read more about this in Tips for complex interfaces

    Running the rmic compiler on the Java class files generates the following files to the directory indicated with the -d option in the rmic statement above:

    • java/lang/Ex.idl
    • java/lang/Exception.idl
    • java/lang/Object.idl
    • java/lang/Throwable.idl
    • java/lang/ThrowableEx.idl
    • javax/ejb/CreateEx.idl
    • javax/ejb/CreateException.idl
    • javax/ejb/EJBHome.idl
    • javax/ejb/EJBMetaData.idl
    • javax/ejb/EJBObject.idl
    • javax/ejb/Handle.idl
    • javax/ejb/HomeHandle.idl
    • javax/ejb/RemoveEx.idl
    • javax/ejb/RemoveException.idl
    • ejbinterop/Logger.idl
    • ejbinterop/LoggerHome.idl


    NOTE: A number of these generated files contain API that can only be used within a Java programming environment. For example, the EJBMetaData implementation is currently specific to each application server, and thus it will be difficult to develop equivalents that will continue to work over time on platforms other than the Java platform. One option is to remove these from the IDL, but if you do, you'll have to remove them from the IDL every time you change the Java interface and regenerate the IDL files from the rmic compiler.

    NOTE: Since CORBA exceptions don't support inheritance, the Java language to IDL mapping creates an Ex class that contains a CORBA value type representing the actual Java exception. In this basic example, we're not going to worry much about exception support. More information about exceptions can be found at Exceptions.

  5. Compile the IDL files with your C++ vendor's "IDL to C++" compiler to generate the C++ code corresponding to the IDL. The steps for this procedure vary by vendor, so consult your product documentation for the specific steps for your vendor.

    Part III: Create a CORBA client

    The client application can be written in any language supported by CORBA. The following example provides the code for a simple C++ client that, given an Object Request Broker (ORB) and a corbaname URL for a LoggerHome object, logs a simple String message on the server. You'll have to adjust the include statements and modify the code for registering the value factories based on your C++ ORB vendor's libraries. This example was written for ORBacus for C++ 4.0.5 and some of the C++ code in this example is specific to that product.

    A corbaname URL is a human-readable URL format that enables you to access CORBA objects. It is used to resolve a stringified name from a specific naming context. This is part of the CORBA Interoperable Naming Service (INS). INS is an extension to CORBA Object Services (COS) Naming Service, which was delivered in previous releases of the Java EE platform. To read more about INS, see Interoperable Naming Service.

    In this example, the client code does the following:

    • Creates an Object Request Broker (ORB). The ORB connects objects requesting services to the objects providing them.
    • Registers value factories.
    • Looks up the LoggerHome object in the naming context pointed to by the corbaname URL.
    • Performs a safe downcast from the object returned to a LoggerHome object.
    • Creates a LoggerEJB object reference.
    • Logs our message.
    • Tells the application server we won't use this EJB reference again.
  6. Create the client using C++ code similar to the following. The exact code may vary with your C++ implementation. This code was written for ORBacus for C++ 4.0.5 and some of the C++ code in this example may be specific to that product.
    //Code Example: Client.cpp
    #include <fstream.h>
    // C++ ORB Vendor specific include files
    // These are from C++ ORBacus 4.0.5
    #include <OB/CORBA.h>
    #include <OB/OBORB.h>
    // Include files generated from our IDL
    #include <java/lang/Exception.h>
    #include <java/lang/Throwable.h>
    #include <javax/ejb/CreateException.h>
    #include <javax/ejb/RemoveException.h>
    #include <ejbinterop/Logger.h>
    #include <ejbinterop/LoggerHome.h>
     * Given an ORB and a corbaname URL for a LoggerHome
     * object, logs a simple string message on the server.
    run(CORBA::ORB_ptr orb, const char* logger_home_url)
      cout << "Looking for: " << logger_home_url << endl;
      // Look up the LoggerHome object in the naming context
      // pointed to by the corbaname URL
      CORBA::Object_var home_obj
        = orb->string_to_object(logger_home_url);
      // Perform a safe downcast
      ejbinterop::LoggerHome_var home
        = ejbinterop::LoggerHome::_narrow(home_obj.in());
      // Create a Logger EJB reference
      ejbinterop::Logger_var logger = home->create();
      CORBA::WStringValue_var msg =
        new CORBA::WStringValue((const CORBA::WChar*)L"Message
          from a C++ client");
      cout << "Logging..." << endl;
      // Log our message
      // Tell the application server we won't use this
      // EJB reference any more
      cout << "Done" << endl;
     * Simple main method that checks arguments, creates an
     * ORB, and handles exceptions.
    main(int argc, char* argv[])
      int exit_code = 0;
      CORBA::ORB_var orb;
      try {
      // Check the arguments
      if (argc != 2) {
        cerr << "Usage: Client <corbaname URL of LoggerHome>" << endl;
        return 1;
      // Create an ORB
      orb = CORBA::ORB_init(argc, argv);
      // Register value factories
      // NOTE: This is overkill for the example since we'll never
      // get these exceptions.  Also, the _OB_id method is a
      // proprietary feature of ORBacus C++ generated code.
      CORBA::ValueFactory factory = new java::lang::Throwable_init;
      orb -> register_value_factory(java::lang::Throwable::_OB_id(),
      factory -> _remove_ref();
      factory = new java::lang::Exception_init;
      orb -> register_value_factory(java::lang::Exception::_OB_id(),
      factory -> _remove_ref();
      factory = new javax::ejb::CreateException_init;
      orb ->                 register_value_factory(javax::ejb::CreateException::_OB_id(),
      factory -> _remove_ref();
      factory = new javax::ejb::RemoveException_init;
      orb ->
      factory -> _remove_ref();
      // Perform the work
      run(orb, argv[1]);
    } catch(const CORBA::Exception& ex) {
      // Handle any CORBA related exceptions
      cerr << ex._to_string() << endl;
      exit_code = 1;
      // Release any ORB resources
      if (!CORBA::is_nil(orb)) {
        try {
          orb -> destroy();
        } catch(const CORBA::Exception& ex) {
          cerr << ex._to_string() << endl;
          exit_code = 1;
      return exit_code;
  7. Use your C++ compiler to compile all of the C++ files, including the Client.cpp file, to create a Client executable. Such tools vary widely across platforms, so consult your product documentation for instructions.

    Part IV: Deploy the Enterprise JavaBean component

  8. Deploy the enterprise bean using your favorite application server. The following steps describe how to deploy the LoggerEJB component using the Java EE Reference Implementation (RI).
    1. Start the RI application from a terminal window or command prompt by typing:
         $JAVA_EE_HOME/bin/java_ee -verbose
    2. When the Java EE RI indicates "Java EE server startup complete", run the deployment tool from another terminal window or command prompt by typing:
    3. From the deployment tool, select File -> New -> Application.
    4. In the Application File Name field, enter Logger.ear to indicate in which file to create the application.
    5. In the Application Display Name field, enter Logger
    6. Select OK to save the settings and close this dialog window.
    7. From the deployment tool, select File -> New -> Enterprise Bean.
    8. Select Next if you get the Introduction screen. If not, continue.
    9. In the New EnterpriseBean Wizard, select Edit in the Contents box.
    10. Expand the Available Files list, and add the following four .class files from our ejbinterop package: Logger.class , LoggerHome.class , LoggerEJB.class , LogMessage.class . Select OK, then Next.
    11. Select Stateless Session Bean Type.
    12. Select ejbinterop.LoggerEJB for the Enterprise Bean Class .
    13. Select ejbinterop.LoggerHome for the Remote Home Interface .
    14. Select ejbinterop.Logger for the Remote Interface .
    15. Select the Next button until you get to the Security Settings page.
    16. Select the Deployment Settings button.
    17. Select Support Client Choice .
    18. Select OK to save the settings and close this dialog window.
    19. Select Finish.
    20. From the deployment tool, select, Tools -> Deploy.
    21. If running the Java RMI-IIOP client only, select Return Client JAR.
    22. Select Next.
    23. Enter ejbinterop/logger in the JNDI Name for our LoggerEJB field.
    24. Select Finish.
    25. Select File -> Exit to exit the deploytool.

    Now, the Logger application with our LoggerEJB components are deployed and ready to receive messages.

    Part V: Run the client executable

  9. Run the client executable. One way you can run the client executable is to enter the following URL in a terminal window from the directory containing the executable client file:
    Client corbaname:iiop:1.2@localhost:1050#ejbinterop/logger

    In this URL,

    • Client is the name of the application to run.
    • corbaname specifies that we will resolve a stringified name from a specific naming context.
    • iiop:1.2 tells the ORB to use the IIOP protocol and GIOP 1.2.
    • The host machine on which to find the reference is localhost, the local machine. To expand this example to run on two machines, enter the IP address or host name of the machine on which the server is running instead of localhost.
    • 1050 is the port on which the naming service is listening for requests. By default in the Java EE RI, the default port the naming service listens on is port 1050. The portion of the reference up to this point at the hash mark (Client corbaname:iiop:1.2@localhost:1050 ) is the URL that returns the root naming context.
    • ejbinterop/logger is the name to resolve in the naming context.

    If you are using the Java EE Reference Implementation, you should see a message similar to the following printed on the application server:

    Sep 21, 2001 3:33:07 PM PDT: Message from a C++ client ejbinterop/
    logger is the name to be resolved from the Naming Service.

    Part VI: Stop the Java EE Server

  10. Stop the Java EE server. To stop the server, enter this command in a terminal window or command prompt.
    $JAVA_EE_HOME/bin/java_ee -stop

    Procedures for stopping running processes vary among operating systems, so if you are running a different server, consult your system documentation for details.

Creating a Java RMI-IIOP client application

Using the same example, we can easily develop a Java RMI-IIOP client that connects to an enterprise bean. The differences from the example using a C++ client are:

The following code is the Java RMI-IIOP version of a client for our LoggerEJB component. Follow the same steps as those presented for the C++ client example. When running the client, use the same URL as in the C++ example.

//Code Example: LogClient.java
package ejbinterop;

import java.rmi.RemoteException;
import javax.rmi.*;
import java.io.*;
import javax.naming.*;
import javax.ejb.*;

 * Simple Java RMI-IIOP client that uses an EJB component.
public class LogClient
     * Given a corbaname URL for a LoggerHome,
     * log a simple String message on the server.
    public static void run(String loggerHomeURL)
        throws CreateException, RemoveException,
               RemoteException, NamingException
        System.out.println("Looking for: " + loggerHomeURL);

        // Create an InitialContext. This will use the
        // CosNaming provider we will specify at runtime.
        InitialContext ic = new InitialContext();

        // Lookup the LoggerHome in the naming context
        // pointed to by the corbaname URL
        Object homeObj = ic.lookup(loggerHomeURL);

        // Perform a safe downcast
        LoggerHome home
            = (LoggerHome)PortableRemoteObject.narrow(homeObj,

        // Create a Logger EJB reference
        Logger logger = home.create();


        // Log our message
        logger.logString("Message from a Java RMI-IIOP client");

        // Tell the application server we won't use this
        // EJB reference anymore


     * Simple main method to check arguments and handle
     * exceptions.
    public static void main(String args[])
        try {

            if (args.length != 1) {
                System.out.println("Args: corbaname URL of LoggerHome");


        } catch (Throwable t) {

Running the application with the Java RMI-IIOP client

When running the example application with a Java RMI-IIOP client instead of a C++ client, follow these steps:

  1. Compile the .java files in the ejbinterop / directory with the following command:
    javac -classpath $JAVA_EE_HOME/lib/java_ee.jar:<ejbinterop_directory> *.java
  2. Deploy the Enterprise JavaBean component as described in Deploy the Enterprise JavaBean component. Remember to select Return Client JAR on the Tools -> Deploy page when running a Java RMI-IIOP client application. The commands in the Deployment topic instruct you to start the Java EE RI or other application server.
  3. Run the client application using a command similar to the following:
    java -classpath $JAVA_EE_HOME/lib/java_ee.jar:
    <path to LoggerClient.jar>/LoggerClient.jar:

    In the window in which the Java EE RI is running, you will see this:

    Jan 31, 2002 2:27:47 PM PST: Message from a Java RMI-IIOP client

    In the window from where the client is run, you will see this:

    Looking for: corbaname:iiop:1.2@localhost:1050#ejbinterop/logger
  4. Stop the Java EE server.

Beyond the Basic Application

This section contains the following information:

Where to go from here

To enhance the application you could:

Tips for complex interfaces

The interfaces are key to the communication between clients and servers speaking different languages. To increase the probability of success in this area, consider the following suggestions:

Links to similar examples

Several vendors implementing Java EE technology have excellent examples and tips for integrating CORBA and Enterprise JavaBeans technology. For example, see the EJB-to-CORBA/Java Simpapp Sample Application.

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