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). While you work through this example, you will probably come up with a number of related questions. You may find the answers in the RMI FAQ, or you may wish to look in the email archives of the rmi-users alias. If you'd like to subscribe to the rmi-users email alias, click here.
The distributed Hello World example uses an applet to make a remote method call to an RMI server, running on the host from which the applet was downloaded. When the applet runs, "Hello World!" is displayed on the client browser.
This tutorial is organized as follows:
Hello.java
- a remote
interface
HelloImpl.java
- a
remote object implementation that implements
examples.hello.Hello
HelloApplet.java
- an
applet that invokes the remote method, sayHello
hello.html
- the HTML
page that references the applet
examples.hello.HelloImpl
, which implements a remote
interface.
For all of the source code used in this tutorial, you may choose from the following formats:
examples.hello
and the source directory is
$HOME/mysrc/examples/hello
.
To create the directory for your source files on the SolarisTM operating system, execute the command:
mkdir -p $HOME/mysrc/examples/helloOn Microsoft Windows platforms, you would go to the directory of your choice, and type:
mkdir mysrc mkdir mysrc\examples mkdir mysrc\examples\hello
There are three tasks to complete in this section:
Remote
interface. Your remote
interface will declare each of the methods that you would like to call
from other JavaTM virtual machines
(JVMs). 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.
Hello
) not the
implementation class (HelloImpl
).
Here is the interface definition for the remote interface,
examples.hello.Hello
. The interface contains just one
method, sayHello
, which returns a string to the caller:
package examples.hello; import java.rmi.Remote; import java.rmi.RemoteException; public interface Hello extends Remote { String sayHello() throws 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 must:
main
method that creates an instance of the remote object
implementation, and binds that instance to a name in the
rmiregistry
. 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
examples.hello.HelloImpl
. The server program needs to:
HelloImpl.java:
package examples.hello; import java.rmi.Naming; import java.rmi.RemoteException; import java.rmi.RMISecurityManager; import java.rmi.server.UnicastRemoteObject; public class HelloImpl extends UnicastRemoteObject implements Hello { public HelloImpl() throws RemoteException { super(); } public String sayHello() { return "Hello World!"; } public static void main(String args[]) { // Create and install a security manager if (System.getSecurityManager() == null) { System.setSecurityManager(new RMISecurityManager()); } try { HelloImpl obj = new HelloImpl(); // Bind this object instance to the name "HelloServer" Naming.rebind("//myhost/HelloServer", obj); System.out.println("HelloServer bound in registry"); } catch (Exception e) { System.out.println("HelloImpl err: " + e.getMessage()); e.printStackTrace(); } } }
Implement a remote interface
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
andabstract
, so if the implementation class doesn't fulfill its contract, it becomes by definition anabstract
class, and the compiler will point out this fact if the class was not declaredabstract
.The implementation class in this example is
examples.hello.HelloImpl
. The implementation class declares which remote interface(s) it is implementing. Here is theHelloImpl
class declaration:public class HelloImpl extends UnicastRemoteObject implements Hello {As a convenience, the implementation class can extend a remote class, which in this example isjava.rmi.server.UnicastRemoteObject
. By extendingUnicastRemoteObject
, theHelloImpl
class can be used to create a remote object that:If you want a remote object that can be activated (created) when a client requests it, rather than running all the time, after you finish this tutorial, you can take a look at the Remote Object Activation tutorial. Also, you can learn about how to use your own communication protocol, rather than the TCP sockets that RMI uses by default, in the tutorial on Creating a Custom RMI socket factory.
- Uses RMI's default sockets-based transport for communication
- Runs all the time
Define the constructor for the remote object
The constructor for a remote class provides the same functionality as the constructor for a non-remote class: it initializes the variables of each newly-created instance of the class, and returns an instance of the class to the program which called the constructor.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
java.rmi.server.UnicastRemoteObject
orjava.rmi.activation.Activatable
, your class will be exported automatically upon creation.If you choose to extend a remote object from any class other than
UnicastRemoteObject
orActivatable
, you will need to explicitly export the remote object by calling either theUnicastRemoteObject.exportObject
method or theActivatable.exportObject
method from your class's constructor (or another initialization method, as appropriate).Because the object export could potentially throw a
java.rmi.RemoteException
, you must define a constructor that throws aRemoteException
, even if the constructor does nothing else. If you forget the constructor,javac
will produce the following error message:HelloImpl.java:13: Exception java.rmi.RemoteException must be caught, or it must be declared in the throws clause of this method. super(); ^ 1 errorTo review: The implementation class for a remote object needs to:Here is the constructor for the
- Implement a remote interface
- Export the object so that it can accept incoming remote method calls
- Declare its constructor(s) to throw at least a
java.rmi.RemoteException
examples.hello.HelloImpl
class:public HelloImpl() throws RemoteException { super(); }Note the following:Although the call to the superclass's no-argument constructor,
- The
super
method call invokes the no-argument constructor ofjava.rmi.server.UnicastRemoteObject
, which exports the remote object.- The constructor must throw
java.rmi.RemoteException
, because RMI's attempt to export a remote object during construction might fail if communication resources are not available.super()
, occurs by default (even if omitted), it is included in this example to make clear the fact that the Java virtual machine (JVM) constructs the superclass before the class.Provide an implementation for each remote method
The implementation class for a remote object contains the code that implements each of the remote methods specified in the remote interface. For example, here is the implementation for thesayHello
method, which returns the string "Hello World!" to the caller:public String sayHello() throws RemoteException { return "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 interfacejava.io.Serializable
. Most of the core classes injava.lang
andjava.util
implement theSerializable
interface. In RMI:A class can define methods not specified in the remote interface, but those methods can only be invoked within the virtual machine running the service and cannot be invoked remotely.
- By default, local objects are passed by copy, which means that all data members (or fields) of an object are copied, except those marked as
static
ortransient
. Please refer to the Java Object Serialization Specification for information on how to alter the default serialization behavior.- Remote objects are passed by reference. A reference to a remote object is actually a reference to a stub, which is a client-side proxy for the remote object. Stubs are described fully in the Java Remote Method Invocation Specification. We'll create them later in this tutorial in the section: Use
rmic
to generate stubs and skeletons.Create and install a security manager
Themain
method of the server first needs to create and install a security manager: either theRMISecurityManager
or one that you have defined yourself. For example:if (System.getSecurityManager() == null) { System.setSecurityManager(new RMISecurityManager()); }A security manager needs to be running so that it can guarantee that the classes that get loaded do not perform operations that they are not allowed to perform. If no security manager is specified no class loading, by RMI clients or servers, is allowed, aside from what can be found in the local CLASSPATH.Create one or more instances of a remote object
Themain
method of the server needs to create one or more instances of the remote object implementation which provides the service. For example:HelloImpl obj = new HelloImpl();The constructor exports the remote object, which means that once created, the remote object is ready to accept incoming calls.Register the remote object
For a caller (client, peer, or applet) to be able to invoke a method on a remote object, that caller must first obtain a reference to the remote object.For bootstrapping, the RMI system provides a remote object registry that allows you to bind a URL-formatted name of the form "
//host/objectname
" to the remote object, whereobjectname
is a simple string name.The RMI registry is a simple server-side name service that allows remote clients to get a reference to a remote object. It is typically used only to locate the first remote object an RMI client needs to talk to. Then that first object in turn, would provide application-specific support for finding other objects.
For example, the reference can be obtained as a parameter to, or a return value from, another remote method call. For a discussion on how this works, please take a look at Applying the Factory Pattern to RMI.
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.
For example, the following code binds the name "HelloServer" to a reference for the remote object:
Note the following about the arguments to the
Naming.rebind("//myhost/HelloServer", obj);
rebind
method call:For security reasons, an application can bind or unbind only to a registry running on the same host. This prevents a client from removing or overwriting any of the entries in a server's remote registry. A lookup, however, can be done from any host.
- The first parameter is a URL-formatted
java.lang.String
, representing the location and name of the remote object.
- No protocol needs to be specified in the URL-formatted string.
- You will need to change the value of
myhost
to be the name or IP address of your server machine; otherwise, the remote object host defaults to the current host. For example, "HelloServer
" is a valid name string that refers to a remote object bound to the nameHelloServer
, running on the local host.- Optionally, a port number can be supplied in the URL-formatted string. Specifying the port number is necessary when the registry that needs to be contacted is running on a port other than the default port, 1099. For example, "
//myhost:1234/HelloServer
" is a valid name string for theHelloServer
remote object, reachable through an RMI registry that is running on the hostmyhost
and is listening for incoming calls on port 1234.
- The second parameter is a reference to the object implementation, on which remote methods will be invoked.
- The RMI runtime substitutes a reference to the remote object's stub for the actual remote object reference specified by the
obj
argument. Remote implementation objects, like instances ofHelloImpl
, never leave the virtual machine where they are created, so when a client performs a lookup in a server's remote object registry, a serialized instance of the stub for the implementation is returned.
The applet in this example remotely invokes the
sayHello
method in order to get the string "Hello World!",
to display when the applet runs. Here is the code for the applet:
package examples.hello; import java.applet.Applet; import java.awt.Graphics; import java.rmi.Naming; import java.rmi.RemoteException; public class HelloApplet extends Applet { String message = "blank"; // "obj" is the identifier that we'll use to refer // to the remote object that implements the "Hello" // interface Hello obj = null; public void init() { try { obj = (Hello)Naming.lookup("//" + getCodeBase().getHost() + "/HelloServer"); message = obj.sayHello(); } catch (Exception e) { System.out.println("HelloApplet exception: " + e.getMessage()); e.printStackTrace(); } } public void paint(Graphics g) { g.drawString(message, 25, 50); } }
rmiregistry
. Like the Naming.rebind
method,
the Naming.lookup
method takes a URL-formatted
java.lang.String
. In this example, the applet
constructs the URL string by using the getCodeBase
method
in conjunction with the getHost
method.
Naming.lookup
takes care of the following tasks:
Naming.lookup
lookup
method on the registry, using the
URL's name component ("HelloServer
")
HelloImpl_Stub
instance bound to
that name
lookup
method receives the
remote object's
(HelloImpl
) stub instance and
loads the stub class
(examples.hello.HelloImpl_Stub
)
from the CLASSPATH or the applet's codebase
Naming.lookup
returns the stub to its
caller (HelloApplet
)
sayHello
method on
the server's remote object
message
.
paint
method, causing the
string "Hello World!" to be displayed in the drawing area of
the applet.
Naming.lookup
method must include the server's
hostname. Otherwise, the applet's lookup attempt will default to the
client, and the AppletSecurityManager
will throw an
exception because the applet cannot access the local system, but is
instead limited to only communicating with the applet's host.
Here is the HTML code for the web page that references the Hello World applet:
<HTML> <title>Hello World</title> <center> <h1>Hello World</h1> </center> <applet codebase="myclasses/" code="examples.hello.HelloApplet" width=500 height=120> </applet> </HTML>Note the following:
codebase
in the HTML file specifies a
directory below the directory from which the web page was
itself loaded. Using this kind of relative path is usually a
good idea. For example, if the codebase
directory
(where the applet's class files live), referenced by the
applet's HTML, was in the directory above the the HTML
directory, you would use the relative path, "../".
code
attribute specifies the
fully-qualified package name of the applet, in this example
examples.hello.HelloApplet
:
code="examples.hello.HelloApplet"
$HOME/mysrc/examples/hello
directory has four files:
Hello.java
contains the source code for the
Hello
remote interface
HelloImpl.java
contains the source code for the
HelloImpl
remote object implementation and the RMI
server for the applet
HelloApplet.java
contains the source code for the applet
hello.html
is the web page that references
the Hello World applet.
.java
source files to
create .class
files. 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 calls to the server-side
dispatcher, which in turn forwards the call to the actual remote object
implementation.
When you use the javac
and rmic
compilers,
you must specify where the resulting class files should reside. For
applets, all files should be in the applet's codebase directory. For
our example, this directory is
$HOME/public_html/myclasses
.
Some web servers allow accessing a user's public_html directory
via an HTTP URL constructed as
"http://host/~username/"
. If your web server does
not support this convention, you may use a file URL of the form
"file:/home/username/public_html".
There are four tasks to complete in this section:
rmic
to generate stubs and
skeletons
Compile the source files
Make sure that the deployment directory$HOME/public_html/myclasses
and the development directory$HOME/mysrc/examples/hello
are each accessible through the localCLASSPATH
on the development machine before attempting to compile.To compile the source files, run the
javac
command as follows:
javac -d $HOME/public_html/myclasses Hello.java HelloImpl.java HelloApplet.java
This command creates the directory
examples/hello
(if it does not already exist) in the directory$HOME/public_html/myclasses
. The command then writes to that directory the filesHello.class
,HelloImpl.class
, andHelloApplet.class
. These are the remote interface, the implementation, and the applet respectively. For an explanation ofjavac
options, you can refer to the Solarisjavac
manual page or the Win32javac
manual page.Use
To create stub and skeleton files, run thermic
to generate skeletons and/or stubsrmic
compiler on the fully-qualified package names of compiled class files that contain remote object implementations, likemy.package.MyImpl
. Thermic
command takes one or more class names as an argument and produces class files of the formMyImpl_Skel.class
andMyImpl_Stub.class
.By default, in JDK 1.2,
rmic
runs with the-vcompat
flag on, which produces stubs and skeletons that support access to:If you will only ever need support for 1.2 clients,
- Unicast (not
Activatable
) remote objects from 1.1 clients and- All types of remote objects from 1.2 clients
rmic
can be run with the-v1.2
option. For an explanation ofrmic
options, you can refer to the Solarisrmic
manual page or the Win32rmic
manual page.For example, to create the stub and skeleton for the
HelloImpl
remote object implementation, runrmic
like this:
rmic -d $HOME/public_html/
myclasses
examples.hello.HelloImplThe "
-d
" option indicates the root directory in which to place the compiled stub and skeleton class files. So the preceding command creates the following files in the directory$HOME/public_html/myclasses/examples/hello
:The generated stub class implements exactly the same set of remote interfaces as the remote object itself. This means that a client can use the Java programming language's built-in operators for casting and type checking. It also means that remote objects written for the Java platform support true object-oriented polymorphism.
HelloImpl_Stub.class
HelloImpl_Skel.class
Move the HTML file to the deployment directory
To make the web page that references the applet visible to clients, thehello.html
file must be moved from the development directory to the applet'scodebase
directory. For example:
mv $HOME/mysrc/examples/hello/hello.html $HOME/public_html/
Set paths for runtime
Make sure that the $HOME/public_html/codebase
directory is available through the server's localCLASSPATH
when you run theHelloImpl
server.
Start the RMI registry
The RMI registry is a simple server-side name server that allows remote clients to get a reference to a remote object. Typically, it is used only to locate the first remote object an application needs to talk to. Then that object in turn would provide application-specific support for finding other objects.Note: Before you start the
rmiregistry
, you must make sure that the shell or window in which you will run the registry either has no CLASSPATH set or has a CLASSPATH that does not include the path to any classes that you want downloaded to your client, including the stubs for your remote object implementation classes.If you start the
rmiregistry
, and it can find your stub classes in its CLASSPATH, it will ignore the server'sjava.rmi.server.codebase
property, and as a result, your client(s) will not be able to download the stub code for your remote object.To start the registry on the server, execute the
rmiregistry
command. This command produces no output and is typically run in the background. For more on thermiregistry
, you can refer to the Solarisrmiregistry
manual page or the Win32rmiregistry
manual page.For example, on Solaris:
rmiregistry &For example, on Windows 95 or Windows NT:
start rmiregistry(Use
javaw
if start is not available.)By default, the registry runs on port 1099. To start the registry on a different port, specify the port number from the command line. For example, to start the registry on port 2001 on a Windows NT system:
start rmiregistry 2001If the registry is running on a port other than 1099, you'll need to specify the port number in the name handed to the URL-based methods of the
java.rmi.Naming
class when making calls to the registry. For example, if the registry is running on port 2001 in this example, the call required to bind the name "HelloServer
" to the remote object reference would be:Naming.rebind("//myhost:2001/HelloServer", obj);You must stop and restart the registry 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 registry will not match the modified class.
Start the server
When starting the server, thejava.rmi.server.codebase
property must be specified, so that the stub class can be dynamically downloaded to the registry and then to the client. Run the server, setting the codebase property to be the location of the implementation stubs. Because the codebase property can only reference a single directory, make sure that any other classes that may need to be downloaded have also been installed in the directory referenced byjava.rmi.server.codebase
.For explanations of each of the
java.rmi.server
properties, click here. To see all the availablejava.rmi.activation
properties, click here. For an explanation ofjava
options, you can refer to the Solarisjava
manual page or the Win32java
manual page. If you have problems running the example code, please take a look at the RMI and Serialization FAQ.Note: A stub class is dynamically downloaded to a client's virtual machine only when the class is not already available locally and the
java.rmi.server.codebase
property has been set properly to specify where the class files are located on the server.There are four things that need to go on the same command line: the "
java
" command, followed by two property name=value pairs (for thecodebase
property, note that there are no spaces from the "-D" all the way though the last "/") and then the fully-qualified package name of the server program. There should be a space just after the word "java
", between the two properties, and just before the word "examples
" (which is very hard to see when you view this as text, in a browser, or on paper). The following command shows how to start theHelloImpl
server, specifying thejava.rmi.server.codebase
andjava.security.policy
properties:
java -Djava.rmi.server.codebase=http://myhost/~myusrname/myclasses/ -Djava.security.policy=$HOME/mysrc/policy examples.hello.HelloImpl
In order to run this code on your system, you'll need to change the location of the
policy
file to be the location of the directory on your system, where you've installed the example source code.Note: In this example, for simplicity, we will use a policy file that gives global permission to anyone from anywhere. Do not use this policy file in a production environment. For more information on how to properly open up permissions using a
java.security.policy
file, please refer to to the following documents:
http://java.sun.com/products/jdk/1.2/docs/guide/security/PolicyFiles.html
http://java.sun.com/products/jdk/1.2/docs/guide/security/permissions.html
The codebase property will be resolved to a URL, so it must have the form of "
http://aHost/somesource/
" or "file:/myDirectory/location
/" or, due to the requirements of some operating systems, "file:///myDirectory/location/
" (three slashes after the "file:").Please note that each of the URL strings above has a trailing "/". The trailing slash is a requirement for the URL set by
the java.rmi.server.codebase
property, so the implementation can resolve (find) your class definition(s) properly.If you forget the trailing slash on the
codebase
property, or if the class files can't be located at the source (they aren't really being made available for download) or if you misspell the property name, you'll get thrown a java.lang.ClassNotFoundException. This exception will be thrown when you try to bind your remote object to thermiregistry
, or when the first client attempts to access that object's stub. If the latter case occurs, you have another problem as well because thermiregistry
was finding the stubs in its CLASSPATH.The output should look like this:
Run the applet
Once the registry and server are running, the applet can be run. An applet is run by loading its web page into a browser orappletviewer
, as shown here:appletviewer http://myhost/~myusrname/hello.html &After running the appletviewer, you will see output similar to the following on your display: