Generates Java bindings for a specified Interface Definition Language (IDL) file.
idlj [ options ] idlfile
The command-line options. See Options. Options can appear in any order, but must precede the idlfile
.
The name of a file that contains Interface Definition Language (IDL) definitions.
The IDL-to-Java Compiler generates the Java bindings for a specified IDL file. For binding details, see Java IDL: IDL to Java Language Mapping at
http://docs.oracle.com/javase/8/docs/technotes/guides/idl/mapping/jidlMapping.html
Some earlier releases of the IDL-to-Java compiler were named idltojava
.
The following idlj
command generates an IDL file named My.idl
with client-side bindings.
idlj My.idl
The previous syntax is equivalent to the following:
idlj -fclient My.idl
The next example generates the server-side bindings, and includes the client-side bindings plus the skeleton, all of which are POA (Inheritance Model).
idlg -fserver My.idl
If you want to generate both client and server-side bindings, then use one of the following (equivalent) commands:
idlj -fclient -fserver My.idl idlj -fall My.idl
There are two possible server-side models: the Portal Servant Inheritance Model and the Tie Model. See Tie Delegation Model.
Portable Servant Inheritance Model
The default server-side model is the Portable Servant Inheritance Model. Given an interface My
defined in My.idl
, the file MyPOA.java
is generated. You must provide the implementation for the My
interface, and the My
interface must inherit from the MyPOA
class. MyPOA.java
is a stream-based skeleton that extends the org.omg.PortableServer.Servant
class at
http://docs.oracle.com/javase/8/docs/api/org/omg/PortableServer/Servant.html
The My
interface implements the callHandler
interface and the operations interface associated with the IDL interface the skeleton implements.
The PortableServer
module for the Portable Object Adapter (POA) defines the native Servant
type. See Portable Object Adapter (POA) at
http://docs.oracle.com/javase/8/docs/technotes/guides/idl/POA.html
In the Java programming language, the Servant
type is mapped to the Java org.omg.PortableServer.Servant
class. It serves as the base class for all POA servant implementations and provides a number of methods that can be called by the application programmer, and methods that are called by the POA and that can be overridden by the user to control aspects of servant behavior.
Another option for the Inheritance Model is to use the -oldImplBase
flag to generate server-side bindings that are compatible with releases of the Java programming language before Java SE 1.4. The -oldImplBase
flag is nonstandard, and these APIs are deprecated. You would use this flag only for compatibility with existing servers written in Java SE 1.3. In that case, you would need to modify an existing make file to add the -oldImplBase
flag to the idlj
compiler. Otherwise POA-based server-side mappings are generated. To generate server-side bindings that are backward compatible, do the following:
idlj -fclient -fserver -oldImplBase My.idl idlj -fall -oldImplBase My.idl
Given an interface My
defined in My.idl
, the file _MyImplBase.java
is generated. You must provide the implementation for the My
interface, and the My
interface must inherit from the _MyImplBase
class.
Tie Delegation Model
The other server-side model is called the Tie Model. This is a delegation model. Because it is not possible to generate ties and skeletons at the same time, they must be generated separately. The following commands generate the bindings for the Tie Model:
idlj -fall My.idl idlj -fallTIE My.idl
For the My
interface, the second command generates MyPOATie.java
. The constructor to the MyPOATie
class takes a delegate. In this example, using the default POA model, the constructor also needs a POA. You must provide the implementation for the delegate, but it does not have to inherit from any other class, only the interface MyOperations
. To use it with the ORB, you must wrap your implementation within the MyPOATie
class, for example:
ORB orb = ORB.init(args, System.getProperties()); // Get reference to rootpoa & activate the POAManager POA rootpoa = (POA)orb.resolve_initial_references("RootPOA"); rootpoa.the_POAManager().activate(); // create servant and register it with the ORB MyServant myDelegate = new MyServant(); myDelegate.setORB(orb); // create a tie, with servant being the delegate. MyPOATie tie = new MyPOATie(myDelegate, rootpoa); // obtain the objectRef for the tie My ref = tie._this(orb);
You might want to use the Tie model instead of the typical Inheritance model when your implementation must inherit from some other implementation. Java allows any number of interface inheritance, but there is only one slot for class inheritance. If you use the inheritance model, then that slot is used up. With the Tie Model, that slot is freed up for your own use. The drawback is that it introduces a level of indirection: one extra method call occurs when a method is called.
For server-side generation, Tie model bindings that are compatible with versions of the IDL to Java language mapping in versions earlier than Java SE 1.4.
idlj -oldImplBase -fall My.idl idlj -oldImplBase -fallTIE My.idl
For the My
interface, the this generates My_Tie.java
. The constructor to the My_Tie
class takes an impl
object. You must provide the implementation for impl
, but it does not have to inherit from any other class, only the interface HelloOperations
. But to use it with the ORB, you must wrap your implementation within My_Tie
, for example:
ORB orb = ORB.init(args, System.getProperties()); // create servant and register it with the ORB MyServant myDelegate = new MyServant(); myDelegate.setORB(orb); // create a tie, with servant being the delegate. MyPOATie tie = new MyPOATie(myDelegate); // obtain the objectRef for the tie My ref = tie._this(orb);
If you want to direct the emitted files to a directory other than the current directory, then call the compiler this way: i
dlj -td /altdir My.idl
.
For the My
interface, the bindings are emitted to /altdir/My.java
, etc., instead of ./My.java
.
If the My.idl
file includes another idl
file, MyOther.idl
, then the compiler assumes that the MyOther.idl
file resides in the local directory. If it resides in /includes
, for example, then you call the compiler with the following command:
idlj -i /includes My.idl
If My.idl
also included Another.idl
that resided in /moreIncludes
, for example, then you call the compiler with the following command:
idlj -i /includes -i /moreIncludes My.idl
Because this form of include
can become long, another way to indicate to the compiler where to search for included files is provided. This technique is similar to the idea of an environment variable. Create a file named idl.config in a directory that is listed in your CLASSPATH
variable. Inside of idl.config
, provide a line with the following form:
includes=/includes;/moreIncludes
The compiler will find this file and read in the includes list. Note that in this example the separator character between the two directories is a semicolon (;). This separator character is platform dependent. On the Windows platform, use a semicolon; on the Solaris, Linux, and OS X platforms, use a colon.
By default, only those interfaces, structures, and so on, that are defined in the idl
file on the command line have Java bindings generated for them. The types defined in included files are not generated. For example, assume the following two idl
files:
My.idl file: #include <MyOther.idl> interface My { }; MyOther.idl file: interface MyOther { };
There is a caveat to the default rule. Any #include
statements that appear at the global scope are treated as described. These #include
statements can be thought of as import statements. The #include
statements that appear within an enclosed scope are treated as true #include
statements, which means that the code within the included file is treated as though it appeared in the original file and, therefore, Java bindings are emitted for it. Here is an example:
My.idl file: #include <MyOther.idl> interface My { #include <Embedded.idl> }; MyOther.idl file: interface MyOther { }; Embedded.idl enum E {one, two, three};
Run idlj My.idl
to generate the following list of Java files. Notice that MyOther.java
is not generated because it is defined in an import-like #include
. But E.java
was generated because it was defined in a true #include
. Notice that because the Embedded.idl
file is included within the scope of the interface My
, it appears within the scope of My
(in MyPackage
). If the -emitAll
flag had been used, then all types in all included files would have been emitted.
./MyHolder.java ./MyHelper.java ./_MyStub.java ./MyPackage ./MyPackage/EHolder.java ./MyPackage/EHelper.java ./MyPackage/E.java ./My.java
Suppose that you work for a company named ABC that has constructed the following IDL file:
Widgets.idl file: module Widgets { interface W1 {...}; interface W2 {...}; };
If you run this file through the IDL-to-Java compiler, then the Java bindings for W1 and W2 are placed within the Widgets
package. There is an industry convention that states that a company's packages should reside within a package named com.<company name>
. To follow this convention, the package name should be com.abc.Widgets
. To place this package prefix onto the Widgets module, execute the following:
idlj -pkgPrefix Widgets com.abc Widgets.idl
If you have an IDL file that includes Widgets.idl, then the -pkgPrefix
flag must appear in that command also. If it does not, then your IDL file will be looking for a Widgets
package rather than a com.abc.Widgets
package.
If you have a number of these packages that require prefixes, then it might be easier to place them into the idl.config file described previously. Each package prefix line should be of the form: PkgPrefix.<type>=<prefix>
. The line for the previous example would be PkgPrefix.Widgets=com.abc
. This option does not affect the Repository ID.
You might need to define a symbol for compilation that is not defined within the IDL file, perhaps to include debugging code in the bindings. The command idlj -d MYDEF My.idl
is equivalent to putting the line #define MYDEF
inside My.idl.
If the Java binding files already exist, then the -keep
flag keeps the compiler from overwriting them. The default is to generate all files without considering that they already exist. If you have customized those files (which you should not do unless you are very comfortable with their contents), then the -keep
option is very useful. The command idlj -keep My.idl
emits all client-side bindings that do not already exist.
The IDL-to-Java compiler generates status messages as it progresses through its phases of execution. Use the -v
option to activate the verbose mode: idlj -v My.idl
.
By default the compiler does not operate in verbose mode
To display the build version of the IDL-to-Java compiler, specify the -version
option on the command-line: idlj -version
.
Version information also appears within the bindings generated by the compiler. Any additional options appearing on the command-line are ignored.
This is equivalent to the following line in an IDL file:
#define symbol
Emit all types, including those found in #include
files.
Defines what bindings to emit. The side
parameter can be client
, server
, serverTIE
, all
, or allTIE
. The -fserverTIE
and -fallTIE
options cause delegate model skeletons to be emitted. Defaults to -fclient
when the flag is not specified.
By default, the current directory is scanned for included files. This option adds another directory.
If a file to be generated already exists, then do not overwrite it. By default it is overwritten.
Suppress warning messages.
Generates skeletons compatible with pre-1.4 JDK ORBs. By default, the POA Inheritance Model server-side bindings are generated. This option provides backward-compatibility with earlier releases of the Java programming language by generating server-side bindings that are ImplBase
Inheritance Model classes.
Wherever type
is encountered at file scope, prefix the generated Java package name with prefix
for all files generated for that type. The type is the simple name of either a top-level module, or an IDL type defined outside of any module.
Whenever the module name type is encountered in an identifier, replace it in the identifier with package for all files in the generated Java package. Note that pkgPrefix
changes are made first. The type value is the simple name of either a top-level module, or an IDL type defined outside of any module and must match the full package name exactly.
If more than one translation matches an identifier, then the longest match is chosen as shown in the following example:
Command:
pkgTranslate type pkg -pkgTranslate type2.baz pkg2.fizz
Resulting Translation:
type => pkg type.ext => pkg.ext type.baz => pkg2.fizz type2.baz.pkg => pkg2.fizz.pkg
The following package names org
, org
.omg
, or any subpackages of org.omg
cannot be translated. Any attempt to translate these packages results in uncompilable code, and the use of these packages as the first argument after -pkgTranslate
is treated as an error.
Use xxx%yyy
as the pattern for naming the skeleton. The defaults are: %POA
for the POA
base class (-fserver
or -fall
), and _%ImplBase
for the oldImplBase
class (-oldImplBase
) and (-fserver
or -fall
)).
Use dir for the output directory instead of the current directory.
Use xxx%yyy
according to the pattern. The defaults are: %POA
for the POA
base class (-fserverTie or -fallTie
), and _%Tie
for the oldImplBase
tie class (-oldImplBase
) and (-fserverTie
or -fallTie
))
Displays release information and terminates.
Displays release information and terminates.
Escaped identifiers in the global scope cannot have the same spelling as IDL primitive types, Object
, or ValueBase
. This is because the symbol table is preloaded with these identifiers. Allowing them to be redefined would overwrite their original definitions. Possible permanent restriction.
The fixed
IDL type is not supported.
No import is generated for global identifiers. If you call an unexported local impl
object, then you do get an exception, but it seems to be due to a NullPointerException
in the ServerDelegate
DSI code.