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This tutorial shows you the steps to follow to create a distributed version of the classic "Hello World" program using JavaTM Remote Method Invocation (RMI) over Internet Inter-ORB Protocol (IIOP). RMI-IIOP adds CORBA (Common Object Request Broker Architecture) capability to Java connectivity to many other programming languages and platforms. RMI-IIOP enables distributed Web-enabled Java remote Management Group. Runtime components include a Java ORB for distributed computing using IIOP communication.
RMI-IIOP is for Java programmers who want to program to the RMI interfaces, but use IIOP as the underlying transport. RMI-IIOP provides interoperability with other CORBA objects implemented in various languages - but only if all the remote interfaces are originally defined as Java RMI interfaces. It is of particular interest to programmers using Enterprise JavaBeans (EJB), since the remote object model for EJBs is RMI-based.
Another option for creating distributed applications is JavaTM IDL. Java IDL is for CORBA programmers who want to program in the Java programming language based on interfaces defined in CORBA Interface Definition Language (IDL). This is "business as usual" CORBA programming, supporting Java in exactly the same way as other languages like C++ or COBOL.
The distributed Hello World example uses a client application to make a remote method call via IIOP to a server, running on the host from which the client was downloaded. When the client runs, "Hello World!" is displayed.
This tutorial is organized as follows:
There are three tasks to complete in this section:
HelloInterface.java
- a remote
interface
HelloImpl.java
- a
remote object implementation that implements
HelloInterface
HelloServer.java
- an RMI server
that creates an instance of the remote object implementation and binds that
instance to a name in the Naming Service
HelloClient.java
- a
client application that invokes the remote method, sayHello()
Remote
interface. Your remote
interface will declare each of the methods that you would like to call
from other machines. Remote interfaces have the following characteristics:
public
.
Otherwise, a client will get an error when attempting to load a
remote object that implements the remote interface, unless that
client is in the same package as the remote interface.
java.rmi.Remote
interface.
java.rmi.RemoteException
(or a superclass of RemoteException
) in its
throws
clause, in addition to any
application-specific exceptions.
HelloInterface
) not the
implementation class (HelloImpl
).
For this example, create all of the source files in the same directory, for example,
$HOME/mysrc/RMIHelloPOA
. Here is the interface definition for the remote
interface,
HelloInterface
. The interface contains just one
method, sayHello
:
//HelloInterface.java import java.rmi.Remote; public interface HelloInterface extends java.rmi.Remote { public void sayHello() throws java.rmi.RemoteException; }Because remote method invocations can fail in very different ways from local method invocations (due to network-related communication problems and server problems), remote methods will report communication failures by throwing a
java.rmi.RemoteException
.
If you want
more information on failure and recovery in distributed systems, you
may wish to read A Note on
Distributed Computing.
At a minimum, a remote object implementation class, HelloImpl.java
must:
HelloImpl.java:
//HelloImpl.java import javax.rmi.PortableRemoteObject; public class HelloImpl extends PortableRemoteObject implements HelloInterface { public HelloImpl() throws java.rmi.RemoteException { super(); // invoke rmi linking and remote object initialization } public void sayHello() throws java.rmi.RemoteException { System.out.println( "It works! Hello World!!" ); } }
In the Java programming language, when a class declares that it
implements an interface, a contract is formed between the class and the
compiler. By entering into this contract, the class is promising that
it will provide method bodies, or definitions, for each of the method
signatures declared in that interface. Interface methods are implicitly
public
and abstract
, so if the implementation
class doesn't fulfill its contract, it becomes by definition an
abstract
class, and the compiler will point out this fact
if the class was not declared abstract
.
The implementation class in this example is
HelloImpl
. The implementation class
declares which remote interface(s) it is implementing. Here is the
HelloImpl
class declaration:
public class HelloImpl extends PortableRemoteObject implements HelloInterface{As a convenience, the implementation class can extend a remote class, which in this example is
javax.rmi.PortableRemoteObject
. By extending
PortableRemoteObject
, the HelloImpl
class can
be used to create a remote object that uses IIOP-based transport for communication.
In addition, the remote object instance will need to be "exported".
Exporting a remote object makes it available to accept incoming remote
method requests, by listening for incoming calls to the remote object
on an anonymous port. When you extend
javax.rmi.PortableRemoteObject
, your class will be
exported automatically upon creation.
Because the object export could potentially throw a
java.rmi.RemoteException
, you must define a
constructor that throws a RemoteException
, even if the
constructor does nothing else. If you forget the constructor,
javac
will produce the following error message:
HelloImpl.java:3: unreported exception java.rmi.RemoteException; must be caught or declared to be thrown. public class HelloImpl extends PortableRemoteObject implements HelloInterface{ ^ 1 errorTo review: The implementation class for a remote object needs to:
java.rmi.RemoteException
HelloImpl
class:
public HelloImpl() throws java.rmi.RemoteException { super(); }Note the following:
super
method call invokes the no-argument
constructor of
javax.rmi.PortableRemoteObject
, which exports
the remote object.
java.rmi.RemoteException
, because RMI's attempt to
export a remote object during construction might fail if
communication resources are not available.
java.rmi.RemoteException
is a checked exception, not a runtime exception.
Although the call to the superclass's no-argument constructor,
super()
, occurs by default (even if omitted), it is
included in this example to make clear the fact that the superclass
will be constructed before the class.
sayHello()
method, which returns the string "It works! Hello World!!"
to the caller:
public void sayHello() throws java.rmi.RemoteException { System.out.println( "It works! Hello World!!" ); }Arguments to, or return values from, remote methods can be any data type for the Java platform, including objects, as long as those objects implement the interface
java.io.Serializable
. Most of the
core classes in java.lang
and java.util
implement the Serializable
interface. In RMI:
static
or transient
.
rmic
to generate stubs and skeletons.
A server class is the class which has a
main
method that creates an instance of the remote object
implementation, and binds that instance to a name in the
Naming Service. The class that contains this
main
method could be the implementation class itself, or
another class entirely.
In this example, the main
method is part of
HelloServer.java
, which does the following:
HelloServer.java:
//HelloServer.java
import javax.naming.InitialContext;
import javax.naming.Context;
import javax.rmi.PortableRemoteObject ;
//Please note that internal Sun APIs
//may change in future releases.
import com.sun.corba.se.internal.POA.POAORB;
import org.omg.PortableServer.*;
import java.util.*;
import org.omg.CORBA.*;
import javax.rmi.CORBA.Stub;
import javax.rmi.CORBA.Util;
public class HelloServer {
public HelloServer(String[] args) {
try {
Properties p = System.getProperties();
// add runtime properties here
//Please note that the name of the servertool
//class may change in future releases.
p.put("org.omg.CORBA.ORBClass",
"com.sun.corba.se.internal.POA.POAORB");
p.put("org.omg.CORBA.ORBSingletonClass",
"com.sun.corba.se.internal.corba.ORBSingleton");
ORB orb = ORB.init( args, p );
POA rootPOA = (POA)orb.resolve_initial_references("RootPOA");
// STEP 1: Create a POA with the appropriate policies
Policy[] tpolicy = new Policy[3];
tpolicy[0] = rootPOA.create_lifespan_policy(
LifespanPolicyValue.TRANSIENT );
tpolicy[1] = rootPOA.create_request_processing_policy(
RequestProcessingPolicyValue.USE_ACTIVE_OBJECT_MAP_ONLY );
tpolicy[2] = rootPOA.create_servant_retention_policy(
ServantRetentionPolicyValue.RETAIN);
POA tPOA = rootPOA.create_POA("MyTransientPOA", null, tpolicy);
// STEP 2: Activate the POA Manager, otherwise all calls to the
// servant hang because, by default, POAManager will be in the
// HOLD state.
tPOA.the_POAManager().activate();
// STEP 3: Instantiate the Servant and activate the Tie, If the
// POA policy is USE_ACTIVE_OBJECT_MAP_ONLY
HelloImpl helloImpl = new HelloImpl();
_HelloImpl_Tie tie = (_HelloImpl_Tie)Util.getTie( helloImpl );
String helloId = "hello";
byte[] id = helloId.getBytes();
tPOA.activate_object_with_id( id, tie );
// STEP 4: Publish the object reference using the same object id
// used to activate the Tie object.
Context initialNamingContext = new InitialContext();
initialNamingContext.rebind("HelloService",
tPOA.create_reference_with_id(id,
tie._all_interfaces(tPOA,id)[0]) );
System.out.println("Hello Server: Ready...");
// STEP 5: Get ready to accept requests from the client
orb.run();
}
catch (Exception e) {
System.out.println("Problem running HelloServer: " + e);
e.printStackTrace();
}
}
public static void main(String args[]) {
new HelloServer( args );
}
}
main
method of the server first needs to create a Portable
Object Adapter (POA) with the appropriate policies. For example:
Policy[] tpolicy = new Policy[3]; tpolicy[0] = rootPOA.create_lifespan_policy( LifespanPolicyValue.TRANSIENT ); tpolicy[1] = rootPOA.create_request_processing_policy( RequestProcessingPolicyValue.USE_ACTIVE_OBJECT_MAP_ONLY ); tpolicy[2] = rootPOA.create_servant_retention_policy( ServantRetentionPolicyValue.RETAIN); POA tPOA = rootPOA.create_POA("MyTransientPOA", null, tpolicy);
The Portable Object Adaptor (POA) is designed to provide an object adapter that can be used with multiple ORB implementations with a minimum of rewriting needed to deal with different vendors' implementations. POA support was introduced in J2SE version 1.4.
The POA is also intended to allow persistent objects -- at least, from the client's perspective. That is, as far as the client is concerned, these objects are always alive, and maintain data values stored in them, even though physically, the server may have been restarted many times, or the implementation may be provided by many different object implementations.
The POA allows the object implementor a lot more control. Previously, the implementation of the object was responsible only for the code that is executed in response to method requests. Now, additionally, the implementor has more control over the object's identity, state, storage, and lifecycle.
In this example, the policy values include:
LifespanPolicyValue
can have the following values:
TRANSIENT
- The objects implemented in the POA
cannot outlive the POA instance in which they are
first created.
PERSISTENT
- The objects implemented in the POA can
outlive the process in which they are first created.
RequestProcessingPolicyValue
can have the following
values:
USE_ACTIVE_OBJECT_MAP_ONLY
- If the object ID
is not found in the Active Object Map,
an OBJECT_NOT_EXIST
exception is returned to the
client. The RETAIN
policy is also required.
USE_DEFAULT_SERVANT
- If the object ID is not found in
the Active Object Map or the NON_RETAIN
policy is
present, and a default servant has been registered
with the POA using the set_servant
operation,
the request is dispatched to the default servant.
USE_SERVANT_MANAGER
- If the object ID is not found
in the Active Object Map or the NON_RETAIN
policy
is present, and a servant manager has been registered
with the POA using the set_servant_manager
operation,
the servant manager is given the opportunity to
locate a servant or raise an exception.
ServantRetentionPolicyValue
can have the following
values.
RETAIN
- to indicate that the POA will retain
active servants in its Active Object Map. If no
ServantRetentionPolicy
is specified at
POA creation, the default is RETAIN
.
NON_RETAIN
- to indicate Servants are not retained by
the POA.
For more information on POA policies, refer to Chapter 11, Portable Object Adapter of the CORBA/IIOP 2.3.1 Specification at http://www.omg.org/cgi-bin/doc?formal/99-10-07
Each POA object has an associated POAManager
object.
A POA Manager may be associated with one or more
POA objects. A POA Manager encapsulates the processing
state of the POAs it is associated with. In this step, the POA Manager
is activated. If this step is missing, all calls to the Servant
would
hang because, by default, the POA Manager will be in the HOLD
state.
tPOA.the_POAManager().activate();
main
method of the server needs to create an
instance of the remote object implementation, or Servant. For example:
HelloImpl helloImpl = new HelloImpl();The constructor exports the remote object, which means that once created, the remote object is ready to accept incoming calls.
When using RMI-IIOP technology, your implementations use delegation (known as the Tie
model) to associate your implementation with the interface. When you create an instance
of your implementation, as above, you also need to create a Tie object to associate it
with a CORBA interface. The next few lines of code activate the Tie, but only if the POA
policy is USE_ACTIVE_OBJECT_MAP_ONLY
.
_HelloImpl_Tie tie = (_HelloImpl_Tie)Util.getTie( helloImpl ); String helloId = "hello"; byte[] id = helloId.getBytes(); tPOA.activate_object_with_id( id, tie );
Once a remote object is registered on the server, callers can look up
the object by name (using a naming service), obtain a remote object reference, and then remotely invoke methods on the object. In this example, we use the Object Request Broker Daemon (orbd
), which is a daemon process containing a Bootstrap Service, a Transient Naming Service, a Persistent Naming Service, and a Server Manager.
For example, the following code binds the name "HelloService" to a reference for the remote object:
Context initialNamingContext = new InitialContext(); initialNamingContext.rebind("HelloService", tPOA.create_reference_with_id(id, tie._all_interfaces(tPOA,id)[0]) ); System.out.println("Hello Server: Ready...");
Note the following about the arguments to the rebind
method call:
"HelloService"
, is a
java.lang.String
, representing the name of the remote object to bind
tPOA.create_reference_with_id(id,
tie._all_interfaces(tPOA,id)[0]
is the object id of the remote object
to bind
orb.run();
The client application in this example remotely invokes the
sayHello
method in order to get the string "Hello World!"
to display when the client application runs. Here is the code for the client application:
//HelloClient.java import java.rmi.RemoteException; import java.net.MalformedURLException; import java.rmi.NotBoundException; import javax.rmi.*; import java.util.Vector; import javax.naming.NamingException; import javax.naming.InitialContext; import javax.naming.Context; public class HelloClient { public static void main( String args[] ) { Context ic; Object objref; HelloInterface hi; try { ic = new InitialContext(); } catch (NamingException e) { System.out.println("failed to obtain context" + e); e.printStackTrace(); return; } // STEP 1: Get the Object reference from the Name Service // using JNDI call. try { objref = ic.lookup("HelloService"); System.out.println("Client: Obtained a ref. to Hello server."); } catch (NamingException e) { System.out.println("failed to lookup object reference"); e.printStackTrace(); return; } // STEP 2: Narrow the object reference to the concrete type and // invoke the method. try { hi = (HelloInterface) PortableRemoteObject.narrow( objref, HelloInterface.class); hi.sayHello(); } catch (ClassCastException e) { System.out.println("narrow failed"); e.printStackTrace(); return; } catch( Exception e ) { System.err.println( "Exception " + e + "Caught" ); e.printStackTrace( ); return; } } }
First, the client application gets a reference to the remote object
implementation (advertised as "HelloService") from the Name Service using Java
Naming and Directory Interface [TM] (JNDI)
calls. Like the Naming.rebind
method,
the Naming.lookup
method takes java.lang.String
value representing the name of the object to look up.
You supply Naming.lookup() the name of the object you want
to look up, and it returns the object bound to that name.
_HelloImpl_Stub
instance bound to
that name
lookup
method receives the
remote object's
(HelloImpl
) stub instance and
loads the stub class
(_HelloImpl_Stub
)
Naming.lookup
returns the stub
to its caller (HelloClient
)
sayHello()
method on
the server's remote object, causing the
string "It works! Hello World!!" to be displayed on the command line.
HelloInterface.java
contains the source code for the
remote interface
HelloImpl.java
contains the source code for the
remote object implementation
HelloServer.java
contains the source code for the
server
HelloClient.java
contains the source code for the client
application
HelloImpl.java
, in order to
create the .class
files needed to run rmic
.
You then run the rmic
compiler to create stubs and skeletons. A stub is a client-side proxy
for a remote object which forwards RMI-IIOP calls to the server-side
dispatcher, which in turn forwards the call to the actual remote object
implementation. The last task is to compile the remaining .java
source files to create .class
files.
The following tasks will be completed in this section:
rmic
to generate stubs and
skeletons
To create stub and skeleton files, the rmic
compiler must be
run on the fully-qualified package names of compiled class files that contain
remote object implementations. In this example, the file that contains the remote
object implementations is HelloImpl.java
. In order to generate the
stubs and skeletons, we must first compile HelloImpl.java
, as follows:
javac -d . -classpath . HelloImpl.java
The "-d .
" option indicates that the generated files should be
placed in the directory from which you are running the compiler. The "-classpath .
" option indicates that files on which HelloImpl.java
is dependent can be found in this directory.
rmic
to generate skeletons and stubsrmic
compiler with the -poa -iiop
option. The rmic -poa -iiop
command takes one
or more class names as an argument and produces class files of the form
_MyImpl_Tie.class
and _MyInterface_Stub.class
. The remote
implementation file, HelloImpl.class
, is the class name to pass in
this example.
For an explanation of
rmic
options, refer to the Solaris Operating Environment
rmic
manual page or the Microsoft Windows rmic
manual
page.
To create the stub and skeleton for the
HelloImpl
remote object implementation, run
rmic
like this:
rmic -poa -iiop HelloImpl
The preceding command creates the following files:
_HelloInterface_Stub.class
- the client stub
_HelloImpl_Tie.class
- the server skeleton
To compile the source files, run the javac
command
as follows:
javac -d . -classpath . HelloInterface.java HelloServer.java HelloClient.java
This command creates the class files HelloInterface.class
,
HelloServer.class
, and HelloClient.class
. These
are the remote interface, the server, and the client application
respectively. For an explanation of javac
options, you
can refer to the Solaris
javac
manual page or the Microsoft Windows javac
manual
page.
orbd
, which includes both a
Transient and a Persistent Naming Service, and is available with every download of J2SE 1.4 and higher.
For a caller (client, peer, or client application) to be able to invoke a method on a remote object, that caller must first obtain a reference to the remote object.
Once a remote object is registered on the server, callers can look up the object by name, obtain a remote object reference, and then remotely invoke methods on the object.
To start the Naming Service, run
orbd
from the command line. This command produces no output and
is typically run in the background. For more on the
orbd
tool, you can refer to the orbd
manual page.
For this example, on the Solaris operating system:
orbd -ORBInitialPort 1060&
or, on the Microsoft Windows operating system:
start orbd -ORBInitialPort 1060
You must specify a port on which to run orbd
.
For this example the port of 1060
is chosen because in the
Solaris operating environment, a user must become root to start a process
on a port under 1024.
You must stop and restart the server any time you modify a remote interface or use modified/additional remote interfaces in a remote object implementation. Otherwise, the type of the object reference bound in the Naming Service will not match the modified class.
Open another terminal window and change to the directory containing the
source files for this example. The command for running
the client has been spread out below to make it easier to read, but should be typed without returns between the lines. The following command shows how to start the HelloServer
server. Of course, if you used a port other than 1060 or
a host other than localhost when starting the orbd
tool, replace those
values in the command below with the actual values used to start orbd
.
java -classpath . -Djava.naming.factory.initial=com.sun.jndi.cosnaming.CNCtxFactory -Djava.naming.provider.url=iiop://localhost:1060 HelloServer
For an explanation of java
options, you can refer to the
Solaris
java
manual page or the Microsoft Windows java
manual page.
The output should look like this:
Hello Server: Ready ...
orbd
tool, replace those
values in the command below with the actual values used to start orbd
.
java -classpath . -Djava.naming.factory.initial=com.sun.jndi.cosnaming.CNCtxFactory -Djava.naming.provider.url=iiop://localhost:1060 HelloClientAfter running the client application, you will see output similar to the following in your terminal window or command prompt window:
Client: Obtained a ref. to Hello server.
The server window will return the following message:
It works! Hello World!!
This completes the tutorial. If you are ready to move on to more complicated applications, here are some sources that may help:
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