Chapter 4: Discovering a Lookup Service

This chapter looks at what is involved in discovering a lookup service/service locator. This is common to both services and clients.

4.1. Lookup Service

A client locates a service by querying a lookup service (service locator). In order to do this, it must first locate such a service. On the other hand, a service must register itself with the lookup service, and in order to do so it must also first locate a service.

The initial phase of both a client and a service is thus discovering a lookup service. Such a service (or set of services) will usually have been started by some independent mechanism. The search for a lookup service can be done either by unicast or by multicast. In fact, the lookup service is just another Jini service, but it is one that is specialised to store services and pass them on to clients looking for them.

4.1.1 Reggie

Sun supplies a lookup service called reggie as part of the standard Jini distribution. The specification of a lookup service is public, and in future we may expect to see other implementations of lookup services. There may be any number of these lookup services running in a network. A LAN may run many lookup services to provide redundancy in case one of them crashes. Across the internet, people may run lookup services for a variety of reasons: sometimes a public lookup service is running on http://www.jini.monash.edu.au to aid people trying Jini clients and services without needing to also set up a lookup service. Other lookup services may act as co-ordination centres, for example by acting as a repository of locations for all of the atomic clock servers in the world.

Anybody can start a lookup service (depending on access permissions), but it will usually be started by an administrator, or started at boot time.

There are several different version of reggie now available from Sun, with different degrees of reliability. (This doesn't mean some versions are buggy, but that if a crash does occur for any reason - such as general system failure - then some versions can recover an earlier state). Each version of reggie requires some support services to work: each one requires an HTTP server. If there is already an HTTP server running, this can be used, or a new one can be started. If you don't have access to an HTTP server (such as Apache), then there is a simple one supplied by Jini. This server is incomplete, and is only good for downloading Java class files - it cannot be used as a general-purpose Web server.

The Jini HTTP server is in the jar file tools.jar. This can be started by

 
java -jar tools.jar 
	
This runs on a default port (8080), which means that any user can start it as long as local network policies do not forbid it. It uses the current directory as "document root" for locating class files. These can be controlled by parameters:
 
java -jar tools-jarfile [-port port-number] [-dir document-root-dir] [-trees] [-verbose]
	
The HTTP server is needed to deliver the stub class files (of the registrar) to clients. These class files are stored in reggie-dl.jar which are in the subdirectory lib of the Jini home directory. For example, on my Linux machine I run
 
java  -jar $JINI_HOME/lib/tools.jar -port 8080 -dir $JINI_HOME/lib 
	

The hardest part of getting Jini to work is getting reggie up and running. There are issues of security and reliability, and simplicity tends to get lost along the way. The following instructions ignore security and reliability, and just show you how to get reggie running as simply as possible. Once you have done this, at some later time you should move to a more robust version.

The security model introduced in Java 1.2 allows fine-grained control of what code can do. While prorammers of standalone applications may not have used this security model, for distributed applications it is important - you are potentially running someone else's code on your machine. But to get going, it is simplest to turn security off. This can be done by having this totally permissive security policy:

 
grant { permission
    java.security.AllPermission; 
}; 
	
Do not run production code with this security policy

There is a new mechanism in Jini 2.0 for starting Sun-supplied services such as reggie. Both reggie and this starter mechanism require a security policy. These could be called reggie.policy and start.policy. Both of these files should contain a security policy as above.

The simplest version of reggie is the so-called transient version. This keeps information about registered services only while it is running. If it is stopped and restarted, the information from the previous session is lost. However, using this one is simplest because you don't have to worry about log files or additional services such as rmid. The start service needs to be told that it has to run this transient version and this is done by a configuration file such as start-transient-reggie.config:


	  import com.sun.jini.start.ServiceDescriptor;
import com.sun.jini.start.NonActivatableServiceDescriptor;

com.sun.jini.start {
    private static codebase = "http://jan.newmarch.name:8080/reggie-dl.jar";
    private static policy = "/usr/local/reggie/reggie.policy";
    private static classpath = "/usr/local/jini2_0/lib/reggie.jar";
    private static config = "/usr/local/reggie/transient-reggie.config";

    static serviceDescriptors = new ServiceDescriptor[] {
                new NonActivatableServiceDescriptor(
                        codebase, policy, classpath,
                        "com.sun.jini.reggie.TransientRegistrarImpl",
                         new String[] { config })
    };
}


	
Here the parameters are
  1. The location of the reggie-dl.jar file relative to the HTTP server started earlier. This file contains code which will represent the lookup service on remote machines

  2. The security policy for the lookup service

  3. The jar file for the reggie service

  4. The location of the configuration file to run the transient reggie

The configuration file transient-reggie.config should contain

 
	  import net.jini.jrmp.*;

com.sun.jini.reggie {
    serverExporter = new JrmpExporter();
    initialMemberGroups = new String[] {};
}

 
	

Finally, with all these in place, the reggie service can be started:

 
java -Djava.security.policy=/usr/local/reggie/start.policy \ -jar
    $JINI_HOME/lib/start.jar \
    /usr/local/reggie/start-transient-reggie.config
	

4.2. Unicast discovery

Unicast discovery can be used when you already know the machine on which the lookup service resides, so you can ask for it directly. This is expected to be used for a lookup service that is outside of your local network, which you know the address of anyway (your home network while you are at work, given in some newsgroup or email message, or maybe even advertised on TV!).

4.2.1 LookupLocator

The class LookupLocator in package net.jini.core.discovery is used for this. There are two constructors,

 
package net.jini.core.discovery; 

public class  LookupLocator { 
    LookupLocator(java.lang.String url) throws
	  java.net.MalformedURLException;
    LookupLocator(java.lang.String host,int port); 
}
	
For the first constructor, the URL must be of the form jini://host/ or jini://host:port/. If no port is given, it defaults to 4160. The host should be a valid DNS name (such as www.jini.monash.edu.au or an IP address (such as 137.92.11.13). No unicast discovery is performed at this stage, though, so any rubbish could be entered. Only a check for syntactic validity of the URL is performed. This syntantic check is not even done for the second constructor.

The following program creates some objects with valid and invalid host/URLs. They are only checked for syntactic validity rather than existence as URLs:


	  
package basic;

import net.jini.core.discovery.LookupLocator;

/**
 * InvalidLookupLocator.java
 */

public class InvalidLookupLocator  {

    static public void main(String argv[]) {
	new InvalidLookupLocator();
    }
   
    public InvalidLookupLocator() {
	LookupLocator lookup;

	// this is valid
	try {
	    lookup = new LookupLocator("jini://localhost");
	    System.out.println("First lookup creation succeeded");
	} catch(java.net.MalformedURLException e) {
	    System.err.println("First lookup failed: " + e.toString());
	}

	// this is probably an invalid URL, 
	// but the URL is syntactically okay
	try {
	    lookup = new LookupLocator("jini://ABCDEFG.org");
	    System.out.println("Second lookup creation succeeded");
	} catch(java.net.MalformedURLException e) {
	    System.err.println("Second lookup failed: " + e.toString());
	}

	// this IS a malformed URL, and should throw an exception
	try {
	    lookup = new LookupLocator("A:B:C://ABCDEFG.org");
	    System.out.println("Third lookup creation succeeded");
	} catch(java.net.MalformedURLException e) {
	    System.err.println("Third lookup failed: " + e.toString());
	}

	// this is valid, but no check is made anyway
	lookup = new LookupLocator("localhost", 80);
	System.out.println("Fourth lookup creation succeeded");
    }
    
} // InvalidLookupLocator

	

4.2.2 Running the InvalidLookupLocator

All programs will need to be compiled using the JDK 1.2 compiler. Jini programs will not compile or run under JDK 1.1 (any versions). This program defines the class InvalidLookupLocator in package basic. The source code will in the file InvalidLookupLocator.java in the basic subdirectory. From the parent directory, this can be compiled by a command such as


javac basic/InvalidLookupLocator.java 
	
to leave the class file also in the basic subdirectory.

The CLASSPATH will need to include the Jini file jini-core.jar for compilation of the source code. When a service is run, this Jini file will need to be in its CLASSPATH. Similarly, when a client runs, it will also need this file in its CLASSPATH. The reason for this repetition is that the service and the client are two separate applications, running in two separate Java Virtual Machines, and quite likely will be on two separate computers.

The InvalidLookupLocator has no additional requirements. It does not perform any network calls, and does not require any additional service to be running. So it can be run simply by

 
java -Djava.security.policy=policy.all -classpath ...  basic.InvalidLookupLocator 
	
where the policy file could be the permisssive security policy file
 
grant { permission
    java.security.AllPermission; 
}; 
	

An Ant file to build, deploy and run this class is basic.InvalidLookupLocator.xml:


	  
	

4.2.3 Information from the LookupLocator

A LookupLocator has methods


String getHost();
int getPort(); 
	
which will return information about the hostname that the locator will use, and the port it will connect on or is already connect on. This is just the information fed into the constructor or left to default values, though. It doesn't give anything new for unicasting. This information will be useful in the multicast situation, though, if you need to find out where the lookup service is.

4.2.4 Get Registrar

Search and lookup is performed by the method getRegistrar() of the LookupLocator which returns an object of class ServiceRegistrar.

 
public ServiceRegistrar getRegistrar() throws 
                   java.io.IOException,
	           java.lang.ClassNotFoundException 
	
The ServiceRegistrar is discussed in detail later. This performs network lookup on the URL given in the LookupLocator constructor.

UML sequence diagrams are useful for showing the timelines of object existence and the method calls that are made from one object to another. The timeline reads down, and method calls and their returns read across. A UML sequence diagram augmented with a jagged arrow showing the network connection is shown in figure 4.1. The UnicastRegister object makes a new() call to create a LookupLocator and this call returns a lookup object. The method call getRegistrar() is then made on the lookup object, and this causes network activity. As a result of this, a ServiceRegistrar object is created in some manner by the lookup object, and this is returned from the method as the registrar.

Figure 4.1: UML sequence diagram for lookup
By this stage, the program looks like

	  
package basic;

import net.jini.core.discovery.LookupLocator;
import net.jini.core.lookup.ServiceRegistrar;
import java.rmi.RMISecurityManager;

/**
 * UnicastRegistrar.java
 */

public class UnicastRegister  {
    
    static public void main(String argv[]) {
        new UnicastRegister();
    }
   
    public UnicastRegister() {
	LookupLocator lookup = null;
	ServiceRegistrar registrar = null;

	System.setSecurityManager(new RMISecurityManager());

        try {
            lookup = new LookupLocator("jini://localhost");
        } catch(java.net.MalformedURLException e) {
            System.err.println("Lookup failed: " + e.toString());
	    System.exit(1);
        }

	try {
	    registrar = lookup.getRegistrar();
	} catch (java.io.IOException e) {
            System.err.println("Registrar search failed: " + e.toString());
	    System.exit(1);
	} catch (java.lang.ClassNotFoundException e) {
            System.err.println("Registrar search failed: " + e.toString());
	    System.exit(1);
	}
	System.out.println("Registrar found");

	// the code takes separate routes from here for client or service
    }
   
} // UnicastRegister
 
	
The registrar object will be used in different ways for clients and services: the services will use it to register themselves, and the clients will use it to locate services.

4.2.5 Running the UnicastRegister

The program needs to be compiled and run with jini-code.jar in its CLASSPATH. When run, it will attempt to connect to the service locator, so obviously one needs to be running on the machine specified in order for this to happen. Otherwise, the program will throw an exception and terminate. Here the host specified is localhost. It could, however, be any machine accessible on the local or remote network (as long as it is running a service locator). For example, to connect to the service locator running on my current workstation, the parameter to LookupLocator would be jini://www.jini.monash.edu.au.

This program will receive a ServiceRegistrar from the service locator. However, it does so by a simple readObject() on a socket connected to the service locator, and so does not need any additional support services such as rmiregistry or rmid. It can be run by

 
java -classpath ... basic.UnicastRegister 
	

An Ant file to build, deploy and run this class is basic.UnicastRegister.xml:


	  
	

4.3. Broadcast discovery

If the location of a lookup service is unknown, it is necessary to make a broadcast search for one. UDP supports a multicast mechanism which the current implementations of Jini use. Because multicast is expensive in terms of network requirements, most routers block multicast packets. This usually restricts broadcast to a local area network, although this depends on the network configuration and the time-to-live (TTL) of the multicast packets.

There may be any number of lookup services running on the network accessible to broadcast search. On a small network, such as a home network, there may be just a single lookup service, but in a large network there may be many - perhaps one or two per department. Each one of these may choose to reply to a broadcast request.

4.3.1 Groups

Some services may be meant for anyone to use, but some may be more restricted in applicability. For example, the Engineering Dept may wish to keep lists of services specific to that department. This may include a departmental diary service, a deparmental inventory, etc. The services themselves may be running anywhere in the organisation, but the department would like to be able to store information about them and to locate them from their own lookup service. Of course, this lookup service may be running anywhere too!

So there could be lookup services specifically for a particular group of services such as the Engineering Dept services, and others for the Publicity Dept services. Some lookup services may cater for more than one group - for example a company lookup service may want to hold information about all services running for all groups.

When a lookup service is started, it can be given a list of groups to act for as a command line parameter. A service may include such group information by giving a list of groups that it belongs too. This is an array of strings, such as

 
String [] groups = {"Engineering dept"};
	

4.3.2 LookupDiscovery

The class LookupDiscovery in package net.jini.discovery is used for broadcast discovery. There are two constructors


LookupDiscovery(java.lang.String[] groups)
LookupDiscovery(java.lang.String[] groups, Configuration config) 
	
We shall only look at the first one for now. The second one is new to Jini 2.0

The parameter to the first LookupDiscovery constructor can take three cases

4.3.3 DiscoveryListener

A broadcast is a multicast call across the network, expecting lookup services to reply as they receive it. Doing so may take time, and there will generally be an unknown number of lookup services that can reply. To be notified of lookup services as they are discovered, the application must register a listener with the LookupDiscovery object.


public void addDiscoveryListener(DiscoveryListener l)
	
The listener must implement the DiscoveryListener interface:

package net.jini.discovery; 

public abstract interface DiscoveryListener { 
    public void discovered(DiscoveryEvent e); 
    public void discarded(DiscoveryEvent e); 
}
	

The discovered() method is invoked whenever a lookup service has been discovered. The API recommends that this method should return quickly, and not make any remote calls. However, for a service it is the natural place to register the service, and for a client it is the natural place to ask if there is a service available and to invoke this service. It may be better to perform these lengthy operations in a separate thread.

There are other timing issues involved: when the DiscoveryListener is created, the broadcast is made. After this, a listener is added to this discovery object. What happens if replies come in very quickly, before the listener is added? The ``Jini Discovery Utilities Specification'' guarantees that these replies will be buffered and delivered when a listener is added. Conversely, no replies may come in for a long time - what is the application supposed to do in the meantime? It cannot simply exit, because then there would be no object to reply to! it has to be made persistent enough to last till replies come in. One way of handling this is if the application has a GUI interface - then it will stay till the user dismisses it. Another possibility is that the application may be prepared to wait for a while before giving up. In that case the main could sleep for, say, ten seconds and then exit. This will depend on what the application should do if no lookup service is discovered.

The discarded() method is invoked whenever the application discards a lookup service by calling discard() on the registrar object.

4.3.4 DiscoveryEvent

The parameter to the discovered()method of the DiscoveryListener interface is a DiscoveryEvent object.

 
package net.jini.discovery; 

public Class DiscoveryEvent { 
    public net.jini.core.lookup.ServiceRegistrar[] getRegistrars(); 
}
	
This has one public method, getRegistrars() which returns an array of ServiceRegistrar objects. Each one of these implements the ServiceRegistrar interface, just like the object returned from a unicast search for a lookup service. More than one can be returned if a set of replies have come in before the listener was registered - they are collected in an array and returned in a single call to the listener. A UML sequence diagram augmented with jagged arrows showing the network broadcast and replies is shown in figure 4.2.

In this figure, creation of a LookupDiscovery object starts the broadcast search, and it returns the discover object. The MulticastRegister adds itself as listener to the discover object. The search continues in a separate thread, and when a new lookup service replies, the discover object invokes the discovered() method in the MulticastRegister, passing it a newly created DiscoveryEvent. The MulticastRegister object can then make calls on the DiscoveryEvent such as getRegistrars(), which will return suitable ServiceRegistrar objects.

Figure 4.2: UML sequence diagram for discovery

By this stage the program looks like


	  package basic;

import net.jini.discovery.LookupDiscovery;
import net.jini.discovery.DiscoveryListener;
import net.jini.discovery.DiscoveryEvent;
import net.jini.core.lookup.ServiceRegistrar;

/**
 * MulticastRegister.java
 */

public class MulticastRegister implements DiscoveryListener {
 
    static public void main(String argv[]) {
        new MulticastRegister();

	// stay around long enough to receive replies
	try {
	    Thread.currentThread().sleep(10000L);
	} catch(java.lang.InterruptedException e) {
	    // do nothing
	}
    }
      
    public MulticastRegister() {
	System.setSecurityManager(new java.rmi.RMISecurityManager());
        LookupDiscovery discover = null;
        try {
            discover = new LookupDiscovery(LookupDiscovery.ALL_GROUPS);
        } catch(Exception e) {
            System.err.println(e.toString());
	    e.printStackTrace();
	    System.exit(1);
        }
        discover.addDiscoveryListener(this);
    }
    
    public void discovered(DiscoveryEvent evt) {

        ServiceRegistrar[] registrars = evt.getRegistrars();

        for (int n = 0; n < registrars.length; n++) {
	    ServiceRegistrar registrar = registrars[n];

	    // the code takes separate routes from here for client or service
	    System.out.println("found a service locator");
  	}
    }

    public void discarded(DiscoveryEvent evt) {

    }
} // MulticastRegister

 
	

4.3.5 Staying alive

In the constructor we create a LookupDiscovery object, add a DiscoveryListener and then the constructor terminates. The main() method, having called this constructor, promptly goes to sleep. What is going on here? The constructor to LookupDiscovery actually starts up a number of threads, to broadcast the service and to listen for replies. (See the chapter on Architecture). When replies come in, the listener thread will call the discovered() method of the MulticastRegister. However, these threads are daemon threads. Java has two types of threads: daemon and user threads, and at least one user thread must be running or the application will terminate. All these other threads are not enough to keep the application alive, and it keep a user thread running in order to continue to exist.

The sleep() ensures that a user thread continues to run, even though it apparently does nothing! This will keep the application alive so that the daemon threads (running in the ``background'') can discover some lookup locators. Ten seconds (10,000 milliseconds) is long enough for that. To stay alive after this ten seconds expires will depend on either increasing the sleep time or creating another user thread in the discovered() method. Later in this book, use is made in ``leasing'' of a useful constant Lease.FOREVER. While the ``leasing'' system understands a special meaning for this constant, the standard Java sleep() merely uses its value Long.MAX_VALUE and just sleeps for a lengthy period.

I have placed the sleep() in the main() method. It is perfectly reasonable to place it in the application constructor, and some examples do this. However, it looks a bit strange there, so I prefer this placement. Note that although the constructor to MulticastRegister will have terminated without us assigning its object reference, a live reference has been passed into the discover object as a DiscoveryListener and it will keep the reference alive in its own daemon threads. This means that the application object will still exist for its discovered() method to be called.

Any other method that results in a user thread continuing to exist will do just as well. For example, a client that has an AWT or Swing user interface will stay alive because there are many user threads created by any of these GUI objects.

For services, which typically will not have a GUI interface running, another simple way is to create an object and then wait for another thread to notify() it. Since nothing will, the thread (and hence the application) stays alive. Essentially, this is an unsatisfied wait that will never terminate - usually an erroneous thing to do, but here it is deliberate.

 
Object keepAlive = new Object(); 
synchronized(keepAlive) { 
    try { 
        keepAlive.wait();
    } catch(InterruptedException e) { 
        // do nothing 
    } 
}
	
This will keep the service alive indefinitely long, and will not terminate unless interrupted. This is unlike sleep() which will terminate eventually.

4.3.6 Running the MulticastRegister

The program needs to be compiled and run with jini-core.jar and jini-ext.jar in its CLASSPATH. The extra jar file is needed as it contains the class files from the net.jini.discovery package. When run, the program will attempt to find all service locators that it can. If there are none, it will find none - pretty boring. So one or more should be set running in the near network or on the local machine.

This program will receive ServiceRegistrar's from the service locators. However, it does so by a simple readObject() on a socket connected to a service locator, and so does not need any additional support services such as rmiregistry.

An Ant file to build, deploy and run this class is basic.MulticastRegister.xml:


	    
	  

4.3.7 Broadcast range

Services and clients search for lookup locators using the multicast protocol, by sending out packets as UDP datagrams. It makes announcements on UDP 224.0.1.84 on port 4160. How far do these announcements reach? This is controlled by two things:

  1. the ``time to live'' (TTL) field on the packets

  2. network administrator settings on routers and gateways

By default the current implementation of LookupDiscovery sets the TTL to be 15. Common network administrative settings restrict such packets to the local network. However, the TTL may be changed by giving the system property net.jini.discovery.ttl a different value. But be careful about setting this: many people will get irate if you flood the networks with multicast packets.

4.4. ServiceRegistrar

The ServiceRegistrar is an abstract class which is implemented by each lookup service. The actual details of this implementation are not relevant here. The role of a ServiceRegistrar is to act as a proxy for the lookup service. This proxy runs in the application, which may be a service or a client.

This is the first object that is moved from one Java process to another in Jini. It is shipped from the lookup service to the application looking for the lookup service, using a socket connection. From then it runs as an object in the application's address space, and the application makes normal method calls to it. When needed, it communicates back to its lookup service. The implementation used by Sun's reggie uses RMI to communicate, but the application does not need to know this, and anyway, it could be done in different ways. This proxy object should not cache any information on the application side, but get ``live'' information from the lookup service as needed. The implementation of the lookup service supplied by Sun does exactly this.

This object has two major methods, one used by a service attempting to register

 public
ServiceRegistration register(ServiceItem item, long leaseDuration) 
                    throws java.rmi.RemoteException
      
and the other(s) by a client trying to locate a particular service
 
public java.lang.Object lookup(ServiceTemplate tmpl) 
             throws java.rmi.RemoteException;
public ServiceMatches lookup(ServiceTemplate tmpl, int maxMatches) 
             throws java.rmi.RemoteException; 
      
The details of these are given in Service Registration and in Client Search . For now, an overview will suffice.

A service provider will register a service object (that is, an instance of a class), and a set of attributes for that object. For example, a printer may specify that it can handle Postscript documents, or a toaster that it can deal with frozen slices of bread. The service provider may register a singleton object that completely implements the service, but more likely it will register a service proxy that will communicate back to other objects in the service provider. Note carefully: the registered object will be shipped around the network. When it finally gets to run, it may be a long way away from where it was originally created. It will have been created in the service's JVM, transferred to the lookup locator by register() and then to the client's JVM by lookup().

A client is trying to find a service, using some properties of the service that it knows about. Whereas the service can export a live object, the client cannot use a service object as a property - because then it would already have the thing, and wouldn't need to try to find one! What it can do is to use a class object, and try to find if there are any instances of this class lying around in service locators. As discussed later in Client Search, it is best if the client asks for an interface class object. In addition to this class specification, the client may specify a set of attribute values that it requires from the service.

The next step is to look at the possible forms of attribute values, and how matching will be performed. This is done using Jini Entry objects. The simplest services, and the least demanding clients, will not require any attributes: the Entry[] array will be null. You may wish to skip ahead to service registration or to client search and come back to entries later.

4.4.1 Information from the ServiceRegistrar

The ServiceRegistrar is returned after a successful discovery has been made. This object has a number of methods that will return useful information about the lookup service itself. So in addition to using this object to register a service or lookup a service, you can use it to find out about the lookup locator. The major methods are

 
String[] getGroups(); 
LookupLocator getLocator(); 
ServiceID getServiceID(); 
	
The method getGroups() will return a list of the groups that the locator is a member of.

The second method, getLocator() is more interesting. This is exactly the same object as is used in the unicast lookup, but now its fields are filled in by the discovery process. So you can find which host the locator is running on, and its hostname by


registrar.getLocator().getHost(); 
	
This can be used to find a list of which locators are running. From there information such as host can be found - this will be information filled in by the discovery process, rather than being preset as in unicast lookup.
 
public void discovered(DiscoveryEvent evt) { 
    ServiceRegistrar[] registrars = evt.getRegistrars(); 
    for (int n = 0; n <  registrars.length; n++) { 
        ServiceRegistrar registrar = registrars[n]; 
        System.out.println("Service locator at " +
	      registrar.getLocator().getHost()); 
    } 
} 
	
You could use this to find where a service locator is so that the next time this program runs it could connect directly by unicast.

The third method getServiceID() is unlikely to be of much use to you. In general, service ID's are used to give a globally identifier for the service (no different services should have the same ID), and a service should have the same ID with all service locators. However, this is the service ID of the lookup service, not of any services registered with it.

4.5. Summary

Both services and clients need to find lookup services. Discovering a lookup service may be done using unicast or multicast protocols. Unicast discovery is a synchronous mechanism. Multicast discovery is an asynchronous mechanism that requires use of a listener to respond when a new service locator is discovered.

When a service locator is discovered, it sends a ServiceRegistrar object to run in the client or service. This acts as a proxy for the locator. This object may be queried for information, such as the host the service locator is on.

4.6. Copyright

If you found this chapter of value, the full book is available from APress or Amazon . There is a review of the book at Java Zone . The current edition of the book does not yet deal with Jini 2.0, but the next edition will.

This file is Copyright (©) 1999, 2000, 2001, 2003, 2004 by Jan Newmarch (http://jan.netcomp.edu.au) jan@newmarch.name.

Creative Commons License This work is licensed under a Creative Commons License, the replacement for the earlier Open Content License.