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5.8 RMI Socket Factories

When the RMI runtime implementation needs instances of java.net.Socket and java.net.ServerSocket for its connections, instead of instantiating objects of those classes directly, it calls the createSocket and createServerSocket methods on the current RMISocketFactory object, returned by the static method RMISocketFactory.getSocketFactory. This allows the application to have a hook to customize the type of sockets used by the RMI transport, such as alternate subclasses of the java.net.Socket and java.net.ServerSocket classes. The instance of RMISocketFactory to be used can be set once by trusted system code. In JDK1.1, this customization was limited to relatively global decisions about socket type, because the only parameters supplied to the factory's methods were host and port (for createSocket) and just port (for createServerSocket).

In the Java 2 platform, the new interfaces RMIServerSocketFactory and RMIClientSocketFactory have been introduced to provide more flexible customization of what protocols are used to communicate with remote objects.

To allow applications using RMI to take advantage of these new socket factory interfaces, several new constructors and exportObject methods, that take the client and server socket factory as additional parameters, have been added to both UnicastRemoteObject and java.rmi.activation.Activatable.

Remote objects exported with either of the new constructors or exportObject methods (with RMIClientSocketFactory and RMIServerSocketFactory parameters) will be treated differently by the RMI runtime. For the lifetime of such a remote object, the runtime will use the custom RMIServerSocketFactory to create a ServerSocket to accept incoming calls to the remote object and use the custom RMIClientSocketFactory to create a Socket to connect clients to the remote object.

The implementation of RemoteRef and ServerRef used in the stubs and skeletons for remote objects exported with custom socket factories is UnicastRef2 and UnicastServerRef2, respectively. The wire representation of the UnicastRef2 type contains a different representation of the "endpoint" to contact than the UnicastRef type has (which used just a host name string in UTF format, following by an integer port number). For UnicastRef2, the endpoint's wire representation consists of a format byte specifying the contents of the rest of the endpoint's representation (to allow for future expansion of the endpoint representation) followed by data in the indicated format. Currently, the data may consist of a hostname in UTF format, a port number, and optionally (as specified by the endpoint format byte) the serialized representation of an RMIClientSocketFactory object that is used by clients to generate socket connections to remote object at this endpoint. The endpoint representation does not contain the RMIServerSocketFactory object that was specified when the remote object was exported.

When calls are made through references of the UnicastRef2 type, the runtime uses the createSocket method of the RMIClientSocketFactory object in the endpoint when creating sockets for connections to the referent remote object. Also, when the runtime makes DGC "dirty" and "clean" calls for a particular remote object, it must call the DGC on the remote JVM using a connection generated from the same RMIClientSocketFactory object as specified in the remote reference, and the DGC implementation on the server side should verify that this was done correctly.

Remote objects exported with the older constructor or method on UnicastRemoteObject that do not take custom socket factories as arguments will have RemoteRef and ServerRef of type UnicastRef and UnicastServerRef as before and use the old wire representation for their endpoints, i.e. a host string in UTF format followed by an integer specifying the port number. This is so that RMI servers that do not use new 1.2 features will interoperate with older RMI clients.


5.8.1 The RMISocketFactory Class

The java.rmi.server.RMISocketFactory abstract class provides an interface for specifying how the transport should obtain sockets. Note that the class below uses Socket and ServerSocket from the java.net package.

package java.rmi.server;

public abstract class RMISocketFactory 
	implements RMIClientSocketFactory, RMIServerSocketFactory
{

	public abstract Socket createSocket(String host, int port)
		throws IOException;
 	public abstract ServerSocket createServerSocket(int port)
		throws IOException;
	public static void setSocketFactory(RMISocketFactory fac)
		throws IOException {...}
	public static RMISocketFactory getSocketFactory() {...}
	public static void setFailureHandler(RMIFailureHandler fh) {...}
	public static RMIFailureHandler getFailureHandler() {...}
}


The static method setSocketFactory is used to set the socket factory from which RMI obtains sockets. The application may invoke this method with its own RMISocketFactory instance only once. An application-defined implementation of RMISocketFactory could, for example, do preliminary filtering on the requested connection and throw exceptions, or return its own extension of the java.net.Socket or java.net.ServerSocket classes, such as ones that provide a secure communication channel. Note that the RMISocketFactory may only be set if the current security manager allows setting a socket factory; if setting the socket factory is disallowed, a SecurityException will be thrown.

The static method getSocketFactory returns the socket factory used by RMI. The method returns null if the socket factory is not set.

The transport layer invokes the createSocket and createServerSocket methods on the RMISocketFactory returned by the getSocketFactory method when the transport needs to create sockets. For example:

RMISocketFactory.getSocketFactory().createSocket(myhost, myport)


The method createSocket should create a client socket connected to the specified host and port. The method createServerSocket should create a server socket on the specified port.

The default transport's implementation of RMISocketFactory provides for transparent RMI through firewalls using HTTP as follows:

The method setFailureHandler sets the failure handler to be called by the RMI runtime if the creation of a server socket fails. The failure handler returns a boolean to indicate if retry should occur. The default failure handler returns false, meaning that by default recreation of sockets is not attempted by the runtime.

The method getFailureHandler returns the current handler for socket creation failure, or null if the failure handler is not set.


5.8.2 The RMIServerSocketFactory Interface

See the RMIServerSocketFactory API documentation.


5.8.3 The RMIClientSocketFactory Interface

See the RMIClientSocketFactory API documentation.



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