Spec-Zone .ru
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The example server consists of two classes, the servant and the server. The servant, HelloImpl, is the implementation of the Hello IDL interface; each Hello instance is implemented by a HelloImpl instance. The servant is a subclass of HelloPOA, which is generated by the idlj compiler from the example IDL.
The servant contains one method for each IDL operation, in this example, the sayHello() and shutdown() methods. Servant methods are just like ordinary Java methods; the extra code to deal with the ORB, with marshaling arguments and results, and so on, is provided by the skeleton.
The server class has the server's main() method, which:
This lesson introduces the basics of writing a CORBA server. For an example of the "Hello World" program with a persistent object server, see Example 2: Hello World with Persistent State. For more discussion of CORBA servers, see Developing Servers.
The steps in this lesson cover:
To create HelloServer.java,
// HelloServer.java // Copyright and License import HelloApp.*; import org.omg.CosNaming.*; import org.omg.CosNaming.NamingContextPackage.*; import org.omg.CORBA.*; import org.omg.PortableServer.*; import org.omg.PortableServer.POA; import java.util.Properties; class HelloImpl extends HelloPOA { private ORB orb; public void setORB(ORB orb_val) { orb = orb_val; } // implement sayHello() method public String sayHello() { return "\nHello world !!\n"; } // implement shutdown() method public void shutdown() { orb.shutdown(false); } } public class HelloServer { public static void main(String args[]) { try{ // create and initialize the ORB ORB orb = ORB.init(args, null); // get reference to rootpoa & activate the POAManager POA rootpoa = POAHelper.narrow(orb.resolve_initial_references("RootPOA")); rootpoa.the_POAManager().activate(); // create servant and register it with the ORB HelloImpl helloImpl = new HelloImpl(); helloImpl.setORB(orb); // get object reference from the servant org.omg.CORBA.Object ref = rootpoa.servant_to_reference(helloImpl); Hello href = HelloHelper.narrow(ref); // get the root naming context org.omg.CORBA.Object objRef = orb.resolve_initial_references("NameService"); // Use NamingContextExt which is part of the Interoperable // Naming Service (INS) specification. NamingContextExt ncRef = NamingContextExtHelper.narrow(objRef); // bind the Object Reference in Naming String name = "Hello"; NameComponent path[] = ncRef.to_name( name ); ncRef.rebind(path, href); System.out.println("HelloServer ready and waiting ..."); // wait for invocations from clients orb.run(); } catch (Exception e) { System.err.println("ERROR: " + e); e.printStackTrace(System.out); } System.out.println("HelloServer Exiting ..."); } }
This section explains each line of HelloServer.java, describing what
the code does, as well as why it is needed for this application.
Performing Basic Setup
The structure of a CORBA server program is the same as most Java
applications: You import required library packages, declare the server
class, define a main() method, and handle exceptions.
Importing Required Packages
First, we import the packages required for the server class:
// The package containing our stubs import HelloApp.*; // HelloServer will use the naming service import org.omg.CosNaming.*; // The package containing special exceptions thrown by the name service import org.omg.CosNaming.NamingContextPackage.*; // All CORBA applications need these classes import org.omg.CORBA.*; // Classes needed for the Portable Server Inheritance Model import org.omg.PortableServer.*; import org.omg.PortableServer.POA; // Properties to initiate the ORB import java.util.Properties;
In this example, we are defining the class for the servant object within HelloServer.java, but outside the HelloServer class.
class HelloImpl extends HelloPOA { // The sayHello() and shutdown() methods go here. }
The servant is a subclass of HelloPOA so that it inherits the general CORBA functionality generated for it by the compiler.
First, we create a private variable, orb
that is used in the
setORB(ORB)
method. The setORB method is a private method
defined by the application developer so that they can set the ORB value with the
servant. This ORB value is used to invoke shutdown() on that specific ORB
in
response to the shutdown() method invocation from the client.
private ORB orb; public void setORB(ORB orb_val) { orb = orb_val; }
Next, we declare and implement the required sayHello() method:
public String sayHello() { return "\nHello world!!\n"; }
And last of all, we implement the shutdown()
method in a similar
way. The shutdown()
method calls the
org.omg.CORBA.ORB.shutdown(boolean)
method for the ORB. The
shutdown(false)
operation indicate that the ORB should shut down
immediately, without waiting for processing to complete.
public void shutdown() { orb.shutdown(false); }
The next step is to declare the server class:
public class HelloServer { // The main() method goes here. }
Every Java application needs a main method. It is declared within the scope of the HelloServer class:
public static void main(String args[]) { // The try-catch block goes here. }
Because all CORBA programs can throw CORBA system exceptions at runtime, all of the main() functionality is placed within a try-catch block. CORBA programs throw runtime exceptions whenever trouble occurs during any of the processes (marshaling, unmarshaling, upcall) involved in invocation. The exception handler simply prints the exception and its stack trace to standard output so you can see what kind of thing has gone wrong.
The try-catch block is set up inside main(), as shown:
try{ // The rest of the HelloServer code goes here. } catch(Exception e) { System.err.println("ERROR: " + e); e.printStackTrace(System.out); }
A CORBA server needs a local ORB object, as does the CORBA client. Every server instantiates an ORB and registers its servant objects so that the ORB can find the server when it receives an invocation for it.
The ORB variable is declared and initialized inside the try-catch block.
ORB orb = ORB.init(args, null);
The call to the ORB's init() method passes in the server's command
line arguments, allowing you to set certain properties at
runtime.
Get a Reference to the Root POA and Activate the POAManager
The ORB obtains the initial object references to services such as
the Name Service using the method resolve_initial_references
.
The reference to the root POA is retrieved and the POAManager is activated from within the try-catch block.
POA rootpoa = POAHelper.narrow(orb.resolve_initial_references("RootPOA")); rootpoa.the_POAManager().activate();
The activate()
operation changes the state of the POA manager
to active, causing associated POAs to start processing requests. The POA manager
encapsulates the processing state of the POAs with which it is associated. Each
POA
object has an associated POAManager
object. A POA
manager may be associated with one or more POA objects.
Managing the Servant Object
A server is a process that instantiates
one or more servant objects. The servant inherits from the interface generated by idlj and
actually performs the work of the operations on that interface. Our
HelloServer needs a HelloImpl.
Instantiating the Servant Object
We instantiate the servant object inside the try-catch block, just after activating the POA manager, as shown:
HelloImpl helloImpl = new HelloImpl();
The section of code describing the servant class was explained previously.
In the next line of code, setORB(orb) is defined on the servant so that ORB.shutdown() can be called as part of the shutdown operation. This step is required because of the shutdown() method defined in Hello.idl.
helloImpl.setORB(orb);
There are other options for implementing the shutdown operation. In this example, the shutdown() method called on the Object takes care of shutting down an ORB. In another implementation, the shutdown method implementation could have simply set a flag, which the server could have checked and called shutdown().
The next set of code is used to get the object reference associated with the servant. The narrow() method is required to cast CORBA object references to their proper types.
org.omg.CORBA.Object ref = rootpoa.servant_to_reference(helloImpl); Hello href = HelloHelper.narrow(ref);
The HelloServer works with the Common Object Services (COS) Naming Service to make the servant object's operations available to clients. The server needs an object reference to the naming service so that it can publish the references to the objects implementing various interfaces. These object references are used by the clients for invoking methods. Another way a servant can make the objects available to clients for invocations is by stringifying the object references to a file.
The two options for Naming Services shipped with J2SE v.1.4 are:
This example uses orbd.
Obtaining the Initial Naming Context
In the try-catch block, below getting the object reference for the servant, we call orb.resolve_initial_references() to get an object reference to the name server:
org.omg.CORBA.Object objRef = orb.resolve_initial_references("NameService");
The string "NameService" is defined for all CORBA ORBs. When you pass in that string, the ORB returns a naming context object that is an object reference for the name service. The string "NameService" indicates:
The proprietary string "TNameService" indicates that the naming service will be
transient when using ORBD's naming service.
Narrowing the Object Reference
As with all CORBA object references, objRef is a generic CORBA object. To use it as a NamingContextExt object, you must narrow it to its proper type. The call to narrow() is just below the previous statement:
NamingContextExt ncRef = NamingContextExtHelper.narrow(objRef);
Here you see the use of an idlj-generated helper class, similar in function to HelloHelper. The ncRef object is now an org.omg.CosNaming.NamingContextExt and you can use it to access the naming service and register the server, as shown in the next topic.
The NamingContextExt object is new to J2SE v.1.4, and is part of the Interoperable
Naming Service specification.
Registering the Servant with the Name Server
Just below the call to narrow(), we create a new NameComponent array. Because the path to Hello has a single element, we create the single-element array that NamingContext.resolve requires for its work:
String name = "Hello"; NameComponent path[] = ncRef.to_name( name );
Finally, we pass path and the servant object to the naming service, binding the servant object to the "Hello" id:
ncRef.rebind(path, href);
Now, when the client calls resolve("Hello") on the initial naming context, the naming service returns an object reference to the Hello servant.
The previous sections describe the code that makes the server ready; the next section explains the code that enables it to simply wait around for a client to request its service. The following code, which is at the end of (but within) the try-catch block, shows how to accomplish this.
orb.run();
When called by the main thread, ORB.run() enables the ORB to perform
work using the main thread, waiting until an invocation comes from the ORB.
Because of its placement in main(), after an invocation completes and
sayHello() returns, the server will wait again. This is the reason that
the HelloClient
explicitly shuts down the ORB after completing its
task.
Now we will compile the HelloServer.java so that we can correct any errors before continuing with this tutorial.
Windows users note that you should substitute backslashes (\) for the slashes (/) in all paths in this document.
To compile HelloServer.java,
javac HelloServer.java HelloApp/*.java
The document Running the Hello World Application discusses running HelloServer and the rest of the application.
Understanding The Server-Side Implementation Models
CORBA supports at least two different server-side mappings for implementing an IDL interface:
Using the Inheritance Model, you implement the IDL interface using an implementation class that also extends the compiler-generated skeleton.
Inheritance models include:
New in J2SE v.1.4: The default
server-side
mapping generated when either the -fall or -fserver
arguments are used conform to Chapter 11, Portable Object Adapter (POA) of
the CORBA 2.3.1 Specification (
The advantages of using the Portable Object Adaptor (POA) are:
NOTE: ImplBase is deprecated in favor of the POA model, but is provided to allow compatibility with servers written in J2SE 1.3 and prior. We do not recommend creating new servers using this nonstandard model.
Using the Delegation Model, you implement the IDL interface using two classes:
The Delegation model is also known as the Tie model, or the Tie Delegation model. It inherits from either the POA or ImplBase compiler-generated skeleton, so the models will be described as POA/Tie or ImplBase/Tie models in this document.
This tutorial presents the POA Inheritance model for server-side implementation. For tutorials using the other server-side implementations, see the following documents:
You might want to use the Tie model instead of the typical Inheritance model if your implementation must inherit from some other implementation. Java allows any number of interface inheritance, but there is only one slot for class inheritance. If you use the inheritance model, that slot is used up . By using the Tie Model, that slot is freed up for your own use. The drawback is that it introduces a level of indirection: one extra method call occurs when invoking a method.
The ImplBase server-side model is an Inheritance Model, as is the POA model. Use the idlj compiler with the -oldImplBase flag to generate server-side bindings that are compatible with older version of Java IDL (prior to J2SE 1.4).
Note that using the -oldImplBase flag is non-standard: these APIs are being deprecated. You would use this flag ONLY for compatibility with existing servers written in J2SE 1.3 or earlier. In that case, you would need to modify an existing MAKEFILE to add the -oldImplBase flag to the idlj compiler, otherwise POA-based server-side mappings will be generated.
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