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Programming WebLogic jCOM

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Understanding WebLogic jCOM

The following sections provide an overview of WebLogic jCOM:


What Is WebLogic jCOM?

WebLogic jCOM is a software bridge that allows bidirectional access between Java/J2EE objects deployed in WebLogic Server®, and Microsoft ActiveX components available within Microsoft Office family of products, Visual Basic and C++ objects, and other Component Object Model/Distributed Component Object Model (COM/DCOM) environments.

In general, BEA Systems believes that Web services are the preferred way to communicate with Microsoft applications. We suggest that customers plan to migrate legacy COM applications to .NET in order to leverage this type of communication. jCOM is provided as a migration path for interim solutions that require Java-to-COM integration. It is suitable for small projects or bridge solutions.

Unlike other Java-to-COM bridges available on the market, jCOM is specifically designed to work with WebLogic Server on the Java side. You cannot use jCOM to make COM objects communicate with any arbitrary Java Virtual Machine (JVM). In addition, jCOM makes direct use of WebLogic Server threads, providing a very robust way to expose services to COM objects.

WebLogic jCOM makes the differences between the object types transparent: to a COM client, WebLogic Server objects appear to be COM objects and to a WebLogic Server application, COM components appear to be Java objects.

WebLogic jCOM is bidirectional because it allows:


An Important Note on Terminology

Throughout the remainder of this programming guide, we refer to the two types of applications by their directions of access. Thus:

jCOM Architecture

WebLogic jCOM provides a runtime component that implements both COM/DCOM over Distributed Computing Environment Remote Procedure Call, and Remote Method Invocation (RMI) over Java Remote Method protocol/Internet Inter-ORB Protocol distributed components infrastructures. This makes the objects on the other side look like native objects for each environment.

WebLogic jCOM also provides automated tools to convert between both types of interfaces: it automatically builds COM/DCOM proxies and RMI stubs necessary for each side to be able to communicate via the above mentioned protocols.

WebLogic jCOM does all the necessary translation between DCOM and RMI technologies, and connects to WebLogic Server as an RMI client. It then communicates requests to Enterprise Java Beans (EJBs) deployed in the WebLogic Server as if the request comes from a regular EJB client.

In a similar manner, when a component deployed in WebLogic Server requests services provided by a DCOM object, the request is translated by the jCOM component from a regular RMI client request issued by the WebLogic Server into DCOM compliant request, and communicated to the DCOM environment to the appropriate object.

In addition to the runtime file, WebLogic jCOM also provides a number of tools and components which are used for configuring the client and server environments.


Why Use WebLogic jCOM?

The major reasons for using WebLogic jCOM are:

WebLogic jCOM follows a software industry trend of making heterogeneous environments and applications interoperate transparently.


WebLogic jCOM Features

The key features of the WebLogic jCOM subsystem are:


Planning Your WebLogic jCOM Application

Before designing and building your jCOM application, you must make a few key decisions. Specifically, you must decide:

This section provides information to help you make these decisions.

Zero-Client Deployment

A jCOM zero client deployment is easy to implement. No WebLogic-jCOM-specific software is required on the client machine.

The WebLogic Server location is coded into the COM client using an object reference moniker (objref) moniker string. The objref moniker is generated by the user and it encodes the IP address and port of the WebLogic Server. You can obtain the moniker string for the COM client code programmatically—or by copying and pasting—from a WebLogic Server servlet. Once the server connection is established, the COM client can link a COM object to an interface in the Java component.

Advantages and Disadvantages of Zero-Client Deployment

The following table summarizes the advantages and disadvantages of a zero-client implementation.



No WebLogic-specific software need be loaded into the client machine registry.

A few jCOM-specific tools must be copied from the WL_HOME\bin directory on the WebLogic Server machine

Offers the benefits of the late binding model (see Early Versus Late Binding) and therefore provides the same flexibility in terms of changes made to the Java component.

Requires that the WebLogic Server location and port number be coded into the COM client, which means that if the server location is changed, this reference has to be regenerated and changed in the source code.

Deprives your application of the advantages of early binding. (See Early Versus Late Binding)

The zero-client model programming model is probably a good choice if your WebLogic jCOM deployment requires a large number of COM client machines.

Early Versus Late Binding

Binding substitutes the symbolic addresses of routines or modules with physical addresses. Early binding and late binding both provide access to another application's objects.

Early bound access gives you information about the object you are accessing while you are compiling your program; all objects accessed are evaluated at compile time. This requires that the server application provide a type library and that the client application identify the library for loading onto the client system.

In late bound access, no information about the object being accessed is available at compile time; the objects being accessed are dynamically evaluated at runtime. This means that it is not until you run the program that you find out if the methods and properties you are accessing actually exist.

Advantages and Disadvantages of Each Binding Model

The following tables summarize the pros and cons of the early binding model:

Early Binding Pros

Early Binding Cons

  • More reliable than late bound implementation.

  • Compile-time type checking makes debugging easy

  • The application's end user can browse the type library.

  • Improved runtime transaction performance relative to a late bound implementation.

  • Complex to implement, as it requires the generation of a type library and wrappers.

The type library is required on the client side; the wrappers are required on the server side. If the client and server are running on separate machines the type library and wrappers have to be generated on the same machine and then copied to the systems where they are required.

  • Lacks the flexibility of late bound access, in that any changes made to the Java component require regeneration of the wrappers and the library.

  • Slower initialization at runtime than a late bound implementation.

The following tables summarize the pros and cons of the late binding model:

Late Binding Advantages

Late Binding Disadvantages

  • Easy to implement

  • Flexible implementation, since objects referenced are only evaluated at runtime

  • Faster runtime initialization than for an early bound implementation

  • Error prone, as no type checking can be done at compile time

It is not until you run the program that you find out if the methods and properties you are accessing actually exist.

  • Runtime transaction performance inferior to early bound implementation

DCOM Versus Native Mode

The DCOM (Distributed Component Object Model) mode uses the Component Object Model (COM) to support communication among objects on different computers. In a WebLogic jCOM application running in DCOM mode, the COM client communicates with WebLogic Server in DCOM protocol.

In native mode, COM clients make native calls to WebLogic Servers (COM-to-WLS) and WebLogic Servers make native calls to COM applications.

For both COM-to-WLS and WLS-to-COM applications, because native mode uses native code dynamically loaded libraries (DLLs)—which are compiled and optimized specifically for the local operating system and CPU—using native mode results in better performance.

Moreover, COM-to-WLS applications operating in native mode use WebLogic's T3/Internet InterORB (IIOP) protocols for communication between the COM client and WebLogic Server. This brings the advantages of:

However, for both types of applications, because native libraries have only been created for Windows, implementing native late bound access requires that the WebLogic Server be installed all COM client machines. However, this does not mean you need a distinct WebLogic Server license for each machine running a COM application.

Moreover, for WLS-to-COM applications, WebLogic Server must be running on a Windows machine to run in native mode.

Advantages and Disadvantages of Native Mode

The following table summarizes the pros and cons of a native mode implementation.



For COM-to-WLS applications, superior performance to that of DCOM mode, because calls aren't made over the network.

For both COM-to-WLS and WLS-to-COM applications, since native libraries have only been created for Windows, implementing native mode requires that the WebLogic Server be installed on all COM machines.

For COM-to-WLS applications, access to WebLogic Server's load balancing and failover features.

In the case of WLS-to-COM applications, WebLogic Server must be running on a Windows machine to run in native mode.

For WLS-to-COM applications, performance benefits because, if the COM object is installed on the same machine as WebLogic Server, WebLogic Server will not make network calls to it.


jCOM Features and Changes in this Release

WebLogic jCOM now supports passing—from COM to Java—two dimensional arrays of the following COM types:

Table 2-1 Two Dimensional Array Support in jCOM

COM Type

Visual Basic Type

Java Type

I1, UI1






I2, UI2



CY, I8, UI8














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