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997 lines
36 KiB
Plaintext
997 lines
36 KiB
Plaintext
<!DOCTYPE article PUBLIC "-//Davenport//DTD DocBook V3.0//EN">
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<article>
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<artheader>
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<title>The Cygnus Native Interface for C++/Java Integration</title>
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<subtitle>Writing native Java methods in natural C++</subtitle>
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<authorgroup>
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<corpauthor>Cygnus Solutions</corpauthor>
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</authorgroup>
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<date>March, 2000</date>
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</artheader>
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<abstract><para>
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This documents CNI, the Cygnus Native Interface,
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which is is a convenient way to write Java native methods using C++.
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This is a more efficient, more convenient, but less portable
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alternative to the standard JNI (Java Native Interface).</para>
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</abstract>
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<sect1><title>Basic Concepts</title>
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<para>
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In terms of languages features, Java is mostly a subset
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of C++. Java has a few important extensions, plus a powerful standard
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class library, but on the whole that does not change the basic similarity.
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Java is a hybrid object-oriented language, with a few native types,
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in addition to class types. It is class-based, where a class may have
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static as well as per-object fields, and static as well as instance methods.
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Non-static methods may be virtual, and may be overloaded. Overloading is
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resolved at compile time by matching the actual argument types against
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the parameter types. Virtual methods are implemented using indirect calls
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through a dispatch table (virtual function table). Objects are
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allocated on the heap, and initialized using a constructor method.
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Classes are organized in a package hierarchy.
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</para>
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<para>
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All of the listed attributes are also true of C++, though C++ has
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extra features (for example in C++ objects may be allocated not just
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on the heap, but also statically or in a local stack frame). Because
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<acronym>gcj</acronym> uses the same compiler technology as
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<acronym>g++</acronym> (the GNU C++ compiler), it is possible
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to make the intersection of the two languages use the same
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<acronym>ABI</acronym> (object representation and calling conventions).
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The key idea in <acronym>CNI</acronym> is that Java objects are C++ objects,
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and all Java classes are C++ classes (but not the other way around).
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So the most important task in integrating Java and C++ is to
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remove gratuitous incompatibilities.
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</para>
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<para>
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You write CNI code as a regular C++ source file. (You do have to use
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a Java/CNI-aware C++ compiler, specifically a recent version of G++.)</para>
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<para>
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You start with:
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<programlisting>
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#include <gcj/cni.h>
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</programlisting></para>
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<para>
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You then include header files for the various Java classes you need
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to use:
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<programlisting>
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#include <java/lang/Character.h>
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#include <java/util/Date.h>
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#include <java/lang/IndexOutOfBoundsException.h>
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</programlisting></para>
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<para>
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In general, <acronym>CNI</acronym> functions and macros start with the
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`<literal>Jv</literal>' prefix, for example the function
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`<literal>JvNewObjectArray</literal>'. This convention is used to
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avoid conflicts with other libraries.
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Internal functions in <acronym>CNI</acronym> start with the prefix
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`<literal>_Jv_</literal>'. You should not call these;
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if you find a need to, let us know and we will try to come up with an
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alternate solution. (This manual lists <literal>_Jv_AllocBytes</literal>
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as an example; <acronym>CNI</acronym> should instead provide
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a <literal>JvAllocBytes</literal> function.)</para>
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<para>
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These header files are automatically generated by <command>gcjh</command>.
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</para>
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</sect1>
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<sect1><title>Packages</title>
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<para>
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The only global names in Java are class names, and packages.
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A <firstterm>package</firstterm> can contain zero or more classes, and
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also zero or more sub-packages.
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Every class belongs to either an unnamed package or a package that
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has a hierarchical and globally unique name.
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</para>
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<para>
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A Java package is mapped to a C++ <firstterm>namespace</firstterm>.
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The Java class <literal>java.lang.String</literal>
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is in the package <literal>java.lang</literal>, which is a sub-package
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of <literal>java</literal>. The C++ equivalent is the
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class <literal>java::lang::String</literal>,
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which is in the namespace <literal>java::lang</literal>,
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which is in the namespace <literal>java</literal>.
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</para>
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<para>
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Here is how you could express this:
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<programlisting>
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// Declare the class(es), possibly in a header file:
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namespace java {
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namespace lang {
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class Object;
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class String;
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...
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}
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}
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class java::lang::String : public java::lang::Object
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{
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...
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};
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</programlisting>
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</para>
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<para>
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The <literal>gcjh</literal> tool automatically generates the
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nessary namespace declarations.</para>
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<sect2><title>Nested classes as a substitute for namespaces</title>
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<para>
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<!-- FIXME the next line reads poorly jsm -->
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It is not that long since g++ got complete namespace support,
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and it was very recent (end of February 1999) that <literal>libgcj</literal>
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was changed to uses namespaces. Releases before then used
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nested classes, which are the C++ equivalent of Java inner classes.
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They provide similar (though less convenient) functionality.
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The old syntax is:
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<programlisting>
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class java {
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class lang {
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class Object;
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class String;
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};
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};
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</programlisting>
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The obvious difference is the use of <literal>class</literal> instead
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of <literal>namespace</literal>. The more important difference is
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that all the members of a nested class have to be declared inside
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the parent class definition, while namespaces can be defined in
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multiple places in the source. This is more convenient, since it
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corresponds more closely to how Java packages are defined.
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The main difference is in the declarations; the syntax for
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using a nested class is the same as with namespaces:
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<programlisting>
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class java::lang::String : public java::lang::Object
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{ ... }
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</programlisting>
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Note that the generated code (including name mangling)
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using nested classes is the same as that using namespaces.</para>
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</sect2>
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<sect2><title>Leaving out package names</title>
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<para>
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<!-- FIXME next line reads poorly jsm -->
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Having to always type the fully-qualified class name is verbose.
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It also makes it more difficult to change the package containing a class.
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The Java <literal>package</literal> declaration specifies that the
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following class declarations are in the named package, without having
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to explicitly name the full package qualifiers.
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The <literal>package</literal> declaration can be followed by zero or
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more <literal>import</literal> declarations, which allows either
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a single class or all the classes in a package to be named by a simple
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identifier. C++ provides something similar
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with the <literal>using</literal> declaration and directive.
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</para>
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<para>
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A Java simple-type-import declaration:
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<programlisting>
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import <replaceable>PackageName</replaceable>.<replaceable>TypeName</replaceable>;
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</programlisting>
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allows using <replaceable>TypeName</replaceable> as a shorthand for
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<literal><replaceable>PackageName</replaceable>.<replaceable>TypeName</replaceable></literal>.
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The C++ (more-or-less) equivalent is a <literal>using</literal>-declaration:
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<programlisting>
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using <replaceable>PackageName</replaceable>::<replaceable>TypeName</replaceable>;
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</programlisting>
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</para>
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<para>
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A Java import-on-demand declaration:
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<programlisting>
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import <replaceable>PackageName</replaceable>.*;
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</programlisting>
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allows using <replaceable>TypeName</replaceable> as a shorthand for
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<literal><replaceable>PackageName</replaceable>.<replaceable>TypeName</replaceable></literal>
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The C++ (more-or-less) equivalent is a <literal>using</literal>-directive:
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<programlisting>
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using namespace <replaceable>PackageName</replaceable>;
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</programlisting>
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</para>
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</sect2>
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</sect1>
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<sect1><title>Primitive types</title>
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<para>
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Java provides 8 <quote>primitives</quote> types:
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<literal>byte</literal>, <literal>short</literal>, <literal>int</literal>,
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<literal>long</literal>, <literal>float</literal>, <literal>double</literal>,
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<literal>char</literal>, and <literal>boolean</literal>.
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These are the same as the following C++ <literal>typedef</literal>s
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(which are defined by <literal>gcj/cni.h</literal>):
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<literal>jbyte</literal>, <literal>jshort</literal>, <literal>jint</literal>,
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<literal>jlong</literal>, <literal>jfloat</literal>,
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<literal>jdouble</literal>,
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<literal>jchar</literal>, and <literal>jboolean</literal>.
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You should use the C++ typenames
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(<ForeignPhrase><Abbrev>e.g.</Abbrev></ForeignPhrase> <literal>jint</literal>),
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and not the Java types names
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(<ForeignPhrase><Abbrev>e.g.</Abbrev></ForeignPhrase> <literal>int</literal>),
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even if they are <quote>the same</quote>.
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This is because there is no guarantee that the C++ type
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<literal>int</literal> is a 32-bit type, but <literal>jint</literal>
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<emphasis>is</emphasis> guaranteed to be a 32-bit type.
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<informaltable frame="all" colsep="1" rowsep="0">
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<tgroup cols="3">
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<thead>
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<row>
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<entry>Java type</entry>
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<entry>C/C++ typename</entry>
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<entry>Description</entry>
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</thead>
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<tbody>
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<row>
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<entry>byte</entry>
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<entry>jbyte</entry>
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<entry>8-bit signed integer</entry>
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</row>
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<row>
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<entry>short</entry>
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<entry>jshort</entry>
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<entry>16-bit signed integer</entry>
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</row>
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<row>
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<entry>int</entry>
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<entry>jint</entry>
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<entry>32-bit signed integer</entry>
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</row>
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<row>
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<entry>long</entry>
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<entry>jlong</entry>
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<entry>64-bit signed integer</entry>
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</row>
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<row>
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<entry>float</entry>
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<entry>jfloat</entry>
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<entry>32-bit IEEE floating-point number</entry>
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</row>
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<row>
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<entry>double</entry>
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<entry>jdouble</entry>
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<entry>64-bit IEEE floating-point number</entry>
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</row>
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<row>
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<entry>char</entry>
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<entry>jchar</entry>
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<entry>16-bit Unicode character</entry>
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</row>
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<row>
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<entry>boolean</entry>
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<entry>jboolean</entry>
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<entry>logical (Boolean) values</entry>
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</row>
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<row>
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<entry>void</entry>
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<entry>void</entry>
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<entry>no value</entry>
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</row>
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</tbody></tgroup>
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</informaltable>
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</para>
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<para>
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<funcsynopsis>
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<funcdef><function>JvPrimClass</function></funcdef>
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<paramdef><parameter>primtype</parameter></paramdef>
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</funcsynopsis>
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This is a macro whose argument should be the name of a primitive
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type, <ForeignPhrase><Abbrev>e.g.</Abbrev></ForeignPhrase>
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<literal>byte</literal>.
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The macro expands to a pointer to the <literal>Class</literal> object
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corresponding to the primitive type.
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<ForeignPhrase><Abbrev>E.g.</Abbrev></ForeignPhrase>,
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<literal>JvPrimClass(void)</literal>
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has the same value as the Java expression
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<literal>Void.TYPE</literal> (or <literal>void.class</literal>).
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</para>
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</sect1>
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<sect1><title>Objects and Classes</title>
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<sect2><title>Classes</title>
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<para>
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All Java classes are derived from <literal>java.lang.Object</literal>.
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C++ does not have a unique <quote>root</quote>class, but we use
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a C++ <literal>java::lang::Object</literal> as the C++ version
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of the <literal>java.lang.Object</literal> Java class. All
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other Java classes are mapped into corresponding C++ classes
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derived from <literal>java::lang::Object</literal>.</para>
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<para>
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Interface inheritance (the <quote><literal>implements</literal></quote>
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keyword) is currently not reflected in the C++ mapping.</para>
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</sect2>
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<sect2><title>Object references</title>
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<para>
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We implement a Java object reference as a pointer to the start
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of the referenced object. It maps to a C++ pointer.
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(We cannot use C++ references for Java references, since
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once a C++ reference has been initialized, you cannot change it to
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point to another object.)
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The <literal>null</literal> Java reference maps to the <literal>NULL</literal>
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C++ pointer.
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</para>
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<para>
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Note that in some Java implementations an object reference is implemented as
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a pointer to a two-word <quote>handle</quote>. One word of the handle
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points to the fields of the object, while the other points
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to a method table. Gcj does not use this extra indirection.
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</para>
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</sect2>
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<sect2><title>Object fields</title>
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<para>
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Each object contains an object header, followed by the instance
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fields of the class, in order. The object header consists of
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a single pointer to a dispatch or virtual function table.
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(There may be extra fields <quote>in front of</quote> the object,
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for example for
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memory management, but this is invisible to the application, and
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the reference to the object points to the dispatch table pointer.)
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</para>
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<para>
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The fields are laid out in the same order, alignment, and size
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as in C++. Specifically, 8-bite and 16-bit native types
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(<literal>byte</literal>, <literal>short</literal>, <literal>char</literal>,
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and <literal>boolean</literal>) are <emphasis>not</emphasis>
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widened to 32 bits.
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Note that the Java VM does extend 8-bit and 16-bit types to 32 bits
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when on the VM stack or temporary registers.</para>
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<para>
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If you include the <literal>gcjh</literal>-generated header for a
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class, you can access fields of Java classes in the <quote>natural</quote>
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way. Given the following Java class:
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<programlisting>
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public class Int
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{
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public int i;
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public Integer (int i) { this.i = i; }
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public static zero = new Integer(0);
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}
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</programlisting>
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you can write:
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<programlisting>
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#include <gcj/cni.h>
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#include <Int.h>
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Int*
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mult (Int *p, jint k)
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{
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if (k == 0)
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return Int::zero; // static member access.
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return new Int(p->i * k);
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}
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</programlisting>
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</para>
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<para>
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<acronym>CNI</acronym> does not strictly enforce the Java access
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specifiers, because Java permissions cannot be directly mapped
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into C++ permission. Private Java fields and methods are mapped
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to private C++ fields and methods, but other fields and methods
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are mapped to public fields and methods.
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</para>
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</sect2>
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</sect1>
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<sect1><title>Arrays</title>
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<para>
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While in many ways Java is similar to C and C++,
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it is quite different in its treatment of arrays.
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C arrays are based on the idea of pointer arithmetic,
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which would be incompatible with Java's security requirements.
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Java arrays are true objects (array types inherit from
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<literal>java.lang.Object</literal>). An array-valued variable
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is one that contains a reference (pointer) to an array object.
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</para>
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<para>
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Referencing a Java array in C++ code is done using the
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<literal>JArray</literal> template, which as defined as follows:
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<programlisting>
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class __JArray : public java::lang::Object
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{
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public:
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int length;
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};
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template<class T>
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class JArray : public __JArray
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{
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T data[0];
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public:
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T& operator[](jint i) { return data[i]; }
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};
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</programlisting></para>
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<para>
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<funcsynopsis>
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<funcdef>template<class T> T *<function>elements</function></funcdef>
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<paramdef>JArray<T> &<parameter>array</parameter></paramdef>
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</funcsynopsis>
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This template function can be used to get a pointer to the
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elements of the <parameter>array</parameter>.
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For instance, you can fetch a pointer
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to the integers that make up an <literal>int[]</literal> like so:
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<programlisting>
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extern jintArray foo;
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jint *intp = elements (foo);
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</programlisting>
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The name of this function may change in the future.</para>
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<para>
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There are a number of typedefs which correspond to typedefs from JNI.
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Each is the type of an array holding objects of the appropriate type:
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<programlisting>
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typedef __JArray *jarray;
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typedef JArray<jobject> *jobjectArray;
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typedef JArray<jboolean> *jbooleanArray;
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typedef JArray<jbyte> *jbyteArray;
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typedef JArray<jchar> *jcharArray;
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typedef JArray<jshort> *jshortArray;
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typedef JArray<jint> *jintArray;
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typedef JArray<jlong> *jlongArray;
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typedef JArray<jfloat> *jfloatArray;
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typedef JArray<jdouble> *jdoubleArray;
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</programlisting>
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</para>
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<para>
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You can create an array of objects using this function:
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<funcsynopsis>
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<funcdef>jobjectArray <function>JvNewObjectArray</function></funcdef>
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<paramdef>jint <parameter>length</parameter></paramdef>
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<paramdef>jclass <parameter>klass</parameter></paramdef>
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<paramdef>jobject <parameter>init</parameter></paramdef>
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</funcsynopsis>
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Here <parameter>klass</parameter> is the type of elements of the array;
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<parameter>init</parameter> is the initial
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value to be put into every slot in the array.
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</para>
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<para>
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For each primitive type there is a function which can be used
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to create a new array holding that type. The name of the function
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is of the form
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`<literal>JvNew<<replaceable>Type</replaceable>>Array</literal>',
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where `<<replaceable>Type</replaceable>>' is the name of
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the primitive type, with its initial letter in upper-case. For
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instance, `<literal>JvNewBooleanArray</literal>' can be used to create
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a new array of booleans.
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Each such function follows this example:
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<funcsynopsis>
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<funcdef>jbooleanArray <function>JvNewBooleanArray</function></funcdef>
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<paramdef>jint <parameter>length</parameter></paramdef>
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</funcsynopsis>
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</para>
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<para>
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<funcsynopsis>
|
|
<funcdef>jsize <function>JvGetArrayLength</function></funcdef>
|
|
<paramdef>jarray <parameter>array</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Returns the length of <parameter>array</parameter>.</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Methods</title>
|
|
|
|
<para>
|
|
Java methods are mapped directly into C++ methods.
|
|
The header files generated by <literal>gcjh</literal>
|
|
include the appropriate method definitions.
|
|
Basically, the generated methods have the same names and
|
|
<quote>corresponding</quote> types as the Java methods,
|
|
and are called in the natural manner.</para>
|
|
|
|
<sect2><title>Overloading</title>
|
|
<para>
|
|
Both Java and C++ provide method overloading, where multiple
|
|
methods in a class have the same name, and the correct one is chosen
|
|
(at compile time) depending on the argument types.
|
|
The rules for choosing the correct method are (as expected) more complicated
|
|
in C++ than in Java, but given a set of overloaded methods
|
|
generated by <literal>gcjh</literal> the C++ compiler will choose
|
|
the expected one.</para>
|
|
<para>
|
|
Common assemblers and linkers are not aware of C++ overloading,
|
|
so the standard implementation strategy is to encode the
|
|
parameter types of a method into its assembly-level name.
|
|
This encoding is called <firstterm>mangling</firstterm>,
|
|
and the encoded name is the <firstterm>mangled name</firstterm>.
|
|
The same mechanism is used to implement Java overloading.
|
|
For C++/Java interoperability, it is important that both the Java
|
|
and C++ compilers use the <emphasis>same</emphasis> encoding scheme.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2><title>Static methods</title>
|
|
<para>
|
|
Static Java methods are invoked in <acronym>CNI</acronym> using the standard
|
|
C++ syntax, using the `<literal>::</literal>' operator rather
|
|
than the `<literal>.</literal>' operator. For example:
|
|
</para>
|
|
<programlisting>
|
|
jint i = java::lang::Math::round((jfloat) 2.3);
|
|
</programlisting>
|
|
<para>
|
|
<!-- FIXME this next sentence seems ungammatical jsm -->
|
|
Defining a static native method uses standard C++ method
|
|
definition syntax. For example:
|
|
<programlisting>
|
|
#include <java/lang/Integer.h>
|
|
java::lang::Integer*
|
|
java::lang::Integer::getInteger(jstring str)
|
|
{
|
|
...
|
|
}
|
|
</programlisting>
|
|
</sect2>
|
|
|
|
<sect2><title>Object Constructors</title>
|
|
<para>
|
|
Constructors are called implicitly as part of object allocation
|
|
using the <literal>new</literal> operator. For example:
|
|
<programlisting>
|
|
java::lang::Int x = new java::lang::Int(234);
|
|
</programlisting>
|
|
</para>
|
|
<para>
|
|
<!-- FIXME rewrite needed here, mine may not be good jsm -->
|
|
Java does not allow a constructor to be a native method.
|
|
Instead, you could define a private method which
|
|
you can have the constructor call.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2><title>Instance methods</title>
|
|
<para>
|
|
<!-- FIXME next para week, I would remove a few words from some sentences jsm -->
|
|
Virtual method dispatch is handled essentially the same way
|
|
in C++ and Java -- <abbrev>i.e.</abbrev> by doing an
|
|
indirect call through a function pointer stored in a per-class virtual
|
|
function table. C++ is more complicated because it has to support
|
|
multiple inheritance, but this does not effect Java classes.
|
|
However, G++ has historically used a different calling convention
|
|
that is not compatible with the one used by <acronym>gcj</acronym>.
|
|
During 1999, G++ will switch to a new ABI that is compatible with
|
|
<acronym>gcj</acronym>. Some platforms (including Linux) have already
|
|
changed. On other platforms, you will have to pass
|
|
the <literal>-fvtable-thunks</literal> flag to g++ when
|
|
compiling <acronym>CNI</acronym> code. Note that you must also compile
|
|
your C++ source code with <literal>-fno-rtti</literal>.
|
|
</para>
|
|
<para>
|
|
Calling a Java instance method in <acronym>CNI</acronym> is done
|
|
using the standard C++ syntax. For example:
|
|
<programlisting>
|
|
java::lang::Number *x;
|
|
if (x->doubleValue() > 0.0) ...
|
|
</programlisting>
|
|
</para>
|
|
<para>
|
|
Defining a Java native instance method is also done the natural way:
|
|
<programlisting>
|
|
#include <java/lang/Integer.h>
|
|
jdouble
|
|
java::lang:Integer::doubleValue()
|
|
{
|
|
return (jdouble) value;
|
|
}
|
|
</programlisting>
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2><title>Interface method calls</title>
|
|
<para>
|
|
In Java you can call a method using an interface reference.
|
|
This is not yet supported in <acronym>CNI</acronym>.</para>
|
|
</sect2>
|
|
</sect1>
|
|
|
|
<sect1><title>Object allocation</title>
|
|
|
|
<para>
|
|
New Java objects are allocated using a
|
|
<firstterm>class-instance-creation-expression</firstterm>:
|
|
<programlisting>
|
|
new <replaceable>Type</replaceable> ( <replaceable>arguments</replaceable> )
|
|
</programlisting>
|
|
The same syntax is used in C++. The main difference is that
|
|
C++ objects have to be explicitly deleted; in Java they are
|
|
automatically deleted by the garbage collector.
|
|
Using <acronym>CNI</acronym>, you can allocate a new object
|
|
using standard C++ syntax. The C++ compiler is smart enough to
|
|
realize the class is a Java class, and hence it needs to allocate
|
|
memory from the garbage collector. If you have overloaded
|
|
constructors, the compiler will choose the correct one
|
|
using standard C++ overload resolution rules. For example:
|
|
<programlisting>
|
|
java::util::Hashtable *ht = new java::util::Hashtable(120);
|
|
</programlisting>
|
|
</para>
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>void *<function>_Jv_AllocBytes</function></funcdef>
|
|
<paramdef>jsize <parameter>size</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Allocate <parameter>size</parameter> bytes. This memory is not
|
|
scanned by the garbage collector. However, it will be freed by
|
|
the GC if no references to it are discovered.
|
|
</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Interfaces</title>
|
|
<para>
|
|
A Java class can <firstterm>implement</firstterm> zero or more
|
|
<firstterm>interfaces</firstterm>, in addition to inheriting from
|
|
a single base class.
|
|
An interface is a collection of constants and method specifications;
|
|
it is similar to the <firstterm>signatures</firstterm> available
|
|
as a G++ extension. An interface provides a subset of the
|
|
functionality of C++ abstract virtual base classes, but they
|
|
are currently implemented differently.
|
|
CNI does not currently provide any support for interfaces,
|
|
or calling methods from an interface pointer.
|
|
This is partly because we are planning to re-do how
|
|
interfaces are implemented in <acronym>gcj</acronym>.
|
|
</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Strings</title>
|
|
<para>
|
|
<acronym>CNI</acronym> provides a number of utility functions for
|
|
working with Java <literal>String</literal> objects.
|
|
The names and interfaces are analogous to those of <acronym>JNI</acronym>.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>jstring <function>JvNewString</function></funcdef>
|
|
<paramdef>const jchar *<parameter>chars</parameter></paramdef>
|
|
<paramdef>jsize <parameter>len</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Creates a new Java String object, where
|
|
<parameter>chars</parameter> are the contents, and
|
|
<parameter>len</parameter> is the number of characters.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>jstring <function>JvNewStringLatin1</function></funcdef>
|
|
<paramdef>const char *<parameter>bytes</parameter></paramdef>
|
|
<paramdef>jsize <parameter>len</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Creates a new Java String object, where <parameter>bytes</parameter>
|
|
are the Latin-1 encoded
|
|
characters, and <parameter>len</parameter> is the length of
|
|
<parameter>bytes</parameter>, in bytes.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>jstring <function>JvNewStringLatin1</function></funcdef>
|
|
<paramdef>const char *<parameter>bytes</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Like the first JvNewStringLatin1, but computes <parameter>len</parameter>
|
|
using <literal>strlen</literal>.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>jstring <function>JvNewStringUTF</function></funcdef>
|
|
<paramdef>const char *<parameter>bytes</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Creates a new Java String object, where <parameter>bytes</parameter> are
|
|
the UTF-8 encoded characters of the string, terminated by a null byte.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef>jchar *<function>JvGetStringChars</function></funcdef>
|
|
<paramdef>jstring <parameter>str</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Returns a pointer to the array of characters which make up a string.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef> int <function>JvGetStringUTFLength</function></funcdef>
|
|
<paramdef>jstring <parameter>str</parameter></paramdef>
|
|
</funcsynopsis>
|
|
Returns number of bytes required to encode contents
|
|
of <parameter>str</parameter> as UTF-8.
|
|
</para>
|
|
|
|
<para>
|
|
<funcsynopsis>
|
|
<funcdef> jsize <function>JvGetStringUTFRegion</function></funcdef>
|
|
<paramdef>jstring <parameter>str</parameter></paramdef>
|
|
<paramdef>jsize <parameter>start</parameter></paramdef>
|
|
<paramdef>jsize <parameter>len</parameter></paramdef>
|
|
<paramdef>char *<parameter>buf</parameter></paramdef>
|
|
</funcsynopsis>
|
|
This puts the UTF-8 encoding of a region of the
|
|
string <parameter>str</parameter> into
|
|
the buffer <parameter>buf</parameter>.
|
|
The region of the string to fetch is specifued by
|
|
<parameter>start</parameter> and <parameter>len</parameter>.
|
|
It is assumed that <parameter>buf</parameter> is big enough
|
|
to hold the result. Note
|
|
that <parameter>buf</parameter> is <emphasis>not</emphasis> null-terminated.
|
|
</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Class Initialization</title>
|
|
<para>
|
|
Java requires that each class be automatically initialized at the time
|
|
of the first active use. Initializing a class involves
|
|
initializing the static fields, running code in class initializer
|
|
methods, and initializing base classes. There may also be
|
|
some implementation specific actions, such as allocating
|
|
<classname>String</classname> objects corresponding to string literals in
|
|
the code.</para>
|
|
<para>
|
|
The Gcj compiler inserts calls to <literal>JvInitClass</literal> (actually
|
|
<literal>_Jv_InitClass</literal>) at appropriate places to ensure that a
|
|
class is initialized when required. The C++ compiler does not
|
|
insert these calls automatically - it is the programmer's
|
|
responsibility to make sure classes are initialized. However,
|
|
this is fairly painless because of the conventions assumed by the Java
|
|
system.</para>
|
|
<para>
|
|
First, <literal>libgcj</literal> will make sure a class is initialized
|
|
before an instance of that object is created. This is one
|
|
of the responsibilities of the <literal>new</literal> operation. This is
|
|
taken care of both in Java code, and in C++ code. (When the G++
|
|
compiler sees a <literal>new</literal> of a Java class, it will call
|
|
a routine in <literal>libgcj</literal> to allocate the object, and that
|
|
routine will take care of initializing the class.) It follows that you can
|
|
access an instance field, or call an instance (non-static)
|
|
method and be safe in the knowledge that the class and all
|
|
of its base classes have been initialized.</para>
|
|
<para>
|
|
Invoking a static method is also safe. This is because the
|
|
Java compiler adds code to the start of a static method to make sure
|
|
the class is initialized. However, the C++ compiler does not
|
|
add this extra code. Hence, if you write a native static method
|
|
using CNI, you are responsible for calling <literal>JvInitClass</literal>
|
|
before doing anything else in the method (unless you are sure
|
|
it is safe to leave it out).</para>
|
|
<para>
|
|
Accessing a static field also requires the class of the
|
|
field to be initialized. The Java compiler will generate code
|
|
to call <literal>_Jv_InitClass</literal> before getting or setting the field.
|
|
However, the C++ compiler will not generate this extra code,
|
|
so it is your responsibility to make sure the class is
|
|
initialized before you access a static field.</para>
|
|
</sect1>
|
|
<sect1><title>Exception Handling</title>
|
|
<para>
|
|
While C++ and Java share a common exception handling framework,
|
|
things are not yet perfectly integrated. The main issue is that the
|
|
<quote>run-time type information</quote> facilities of the two
|
|
languages are not integrated.</para>
|
|
<para>
|
|
Still, things work fairly well. You can throw a Java exception from
|
|
C++ using the ordinary <literal>throw</literal> construct, and this
|
|
exception can be caught by Java code. Similarly, you can catch an
|
|
exception thrown from Java using the C++ <literal>catch</literal>
|
|
construct.
|
|
<para>
|
|
Note that currently you cannot mix C++ catches and Java catches in
|
|
a single C++ translation unit. We do intend to fix this eventually.
|
|
</para>
|
|
<para>
|
|
Here is an example:
|
|
<programlisting>
|
|
if (i >= count)
|
|
throw new java::lang::IndexOutOfBoundsException();
|
|
</programlisting>
|
|
</para>
|
|
<para>
|
|
Normally, GNU C++ will automatically detect when you are writing C++
|
|
code that uses Java exceptions, and handle them appropriately.
|
|
However, if C++ code only needs to execute destructors when Java
|
|
exceptions are thrown through it, GCC will guess incorrectly. Sample
|
|
problematic code:
|
|
<programlisting>
|
|
struct S { ~S(); };
|
|
extern void bar(); // is implemented in Java and may throw exceptions
|
|
void foo()
|
|
{
|
|
S s;
|
|
bar();
|
|
}
|
|
</programlisting>
|
|
The usual effect of an incorrect guess is a link failure, complaining of
|
|
a missing routine called <literal>__gxx_personality_v0</literal>.
|
|
</para>
|
|
<para>
|
|
You can inform the compiler that Java exceptions are to be used in a
|
|
translation unit, irrespective of what it might think, by writing
|
|
<literal>#pragma GCC java_exceptions</literal> at the head of the
|
|
file. This <literal>#pragma</literal> must appear before any
|
|
functions that throw or catch exceptions, or run destructors when
|
|
exceptions are thrown through them.</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Synchronization</title>
|
|
<para>
|
|
Each Java object has an implicit monitor.
|
|
The Java VM uses the instruction <literal>monitorenter</literal> to acquire
|
|
and lock a monitor, and <literal>monitorexit</literal> to release it.
|
|
The JNI has corresponding methods <literal>MonitorEnter</literal>
|
|
and <literal>MonitorExit</literal>. The corresponding CNI macros
|
|
are <literal>JvMonitorEnter</literal> and <literal>JvMonitorExit</literal>.
|
|
</para>
|
|
<para>
|
|
The Java source language does not provide direct access to these primitives.
|
|
Instead, there is a <literal>synchronized</literal> statement that does an
|
|
implicit <literal>monitorenter</literal> before entry to the block,
|
|
and does a <literal>monitorexit</literal> on exit from the block.
|
|
Note that the lock has to be released even the block is abnormally
|
|
terminated by an exception, which means there is an implicit
|
|
<literal>try</literal>-<literal>finally</literal>.
|
|
</para>
|
|
<para>
|
|
From C++, it makes sense to use a destructor to release a lock.
|
|
CNI defines the following utility class.
|
|
<programlisting>
|
|
class JvSynchronize() {
|
|
jobject obj;
|
|
JvSynchronize(jobject o) { obj = o; JvMonitorEnter(o); }
|
|
~JvSynchronize() { JvMonitorExit(obj); }
|
|
};
|
|
</programlisting>
|
|
The equivalent of Java's:
|
|
<programlisting>
|
|
synchronized (OBJ) { CODE; }
|
|
</programlisting>
|
|
can be simply expressed:
|
|
<programlisting>
|
|
{ JvSynchronize dummy(OBJ); CODE; }
|
|
</programlisting>
|
|
</para>
|
|
<para>
|
|
Java also has methods with the <literal>synchronized</literal> attribute.
|
|
This is equivalent to wrapping the entire method body in a
|
|
<literal>synchronized</literal> statement.
|
|
(Alternatively, an implementation could require the caller to do
|
|
the synchronization. This is not practical for a compiler, because
|
|
each virtual method call would have to test at run-time if
|
|
synchronization is needed.) Since in <literal>gcj</literal>
|
|
the <literal>synchronized</literal> attribute is handled by the
|
|
method implementation, it is up to the programmer
|
|
of a synchronized native method to handle the synchronization
|
|
(in the C++ implementation of the method).
|
|
In otherwords, you need to manually add <literal>JvSynchronize</literal>
|
|
in a <literal>native synchornized</literal> method.</para>
|
|
</sect1>
|
|
|
|
<sect1><title>Reflection</title>
|
|
<para>The types <literal>jfieldID</literal> and <literal>jmethodID</literal>
|
|
are as in JNI.</para>
|
|
<para>
|
|
The function <literal>JvFromReflectedField</literal>,
|
|
<literal>JvFromReflectedMethod</literal>,
|
|
<literal>JvToReflectedField</literal>, and
|
|
<literal>JvToFromReflectedMethod</literal> (as in Java 2 JNI)
|
|
will be added shortly, as will other functions corresponding to JNI.</para>
|
|
|
|
<sect1><title>Using gcjh</title>
|
|
<para>
|
|
The <command>gcjh</command> is used to generate C++ header files from
|
|
Java class files. By default, <command>gcjh</command> generates
|
|
a relatively straightforward C++ header file. However, there
|
|
are a few caveats to its use, and a few options which can be
|
|
used to change how it operates:
|
|
</para>
|
|
<variablelist>
|
|
<varlistentry>
|
|
<term><literal>--classpath</literal> <replaceable>path</replaceable></term>
|
|
<term><literal>--CLASSPATH</literal> <replaceable>path</replaceable></term>
|
|
<term><literal>-I</literal> <replaceable>dir</replaceable></term>
|
|
<listitem><para>
|
|
These options can be used to set the class path for gcjh.
|
|
Gcjh searches the class path the same way the compiler does;
|
|
these options have their familiar meanings.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-d <replaceable>directory</replaceable></literal></term>
|
|
<listitem><para>
|
|
Puts the generated <literal>.h</literal> files
|
|
beneath <replaceable>directory</replaceable>.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-o <replaceable>file</replaceable></literal></term>
|
|
<listitem><para>
|
|
Sets the name of the <literal>.h</literal> file to be generated.
|
|
By default the <literal>.h</literal> file is named after the class.
|
|
This option only really makes sense if just a single class file
|
|
is specified.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>--verbose</literal></term>
|
|
<listitem><para>
|
|
gcjh will print information to stderr as it works.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-M</literal></term>
|
|
<term><literal>-MM</literal></term>
|
|
<term><literal>-MD</literal></term>
|
|
<term><literal>-MMD</literal></term>
|
|
<listitem><para>
|
|
These options can be used to generate dependency information
|
|
for the generated header file. They work the same way as the
|
|
corresponding compiler options.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-prepend <replaceable>text</replaceable></literal></term>
|
|
<listitem><para>
|
|
This causes the <replaceable>text</replaceable> to be put into the generated
|
|
header just after class declarations (but before declaration
|
|
of the current class). This option should be used with caution.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-friend <replaceable>text</replaceable></literal></term>
|
|
<listitem><para>
|
|
This causes the <replaceable>text</replaceable> to be put into the class
|
|
declaration after a <literal>friend</literal> keyword.
|
|
This can be used to declare some
|
|
other class or function to be a friend of this class.
|
|
This option should be used with caution.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-add <replaceable>text</replaceable></literal></term>
|
|
<listitem><para>
|
|
The <replaceable>text</replaceable> is inserted into the class declaration.
|
|
This option should be used with caution.</para>
|
|
</listitem>
|
|
</varlistentry>
|
|
|
|
<varlistentry>
|
|
<term><literal>-append <replaceable>text</replaceable></literal></term>
|
|
<listitem><para>
|
|
The <replaceable>text</replaceable> is inserted into the header file
|
|
after the class declaration. One use for this is to generate
|
|
inline functions. This option should be used with caution.
|
|
</listitem>
|
|
</varlistentry>
|
|
</variablelist>
|
|
<para>
|
|
All other options not beginning with a <literal>-</literal> are treated
|
|
as the names of classes for which headers should be generated.</para>
|
|
<para>
|
|
gcjh will generate all the required namespace declarations and
|
|
<literal>#include</literal>'s for the header file.
|
|
In some situations, gcjh will generate simple inline member
|
|
functions. Note that, while gcjh puts <literal>#pragma
|
|
interface</literal> in the generated header file, you should
|
|
<emphasis>not</emphasis> put <literal>#pragma implementation</literal>
|
|
into your C++ source file. If you do, duplicate definitions of
|
|
inline functions will sometimes be created, leading to link-time
|
|
errors.
|
|
</para>
|
|
<para>
|
|
There are a few cases where gcjh will fail to work properly:</para>
|
|
<para>
|
|
gcjh assumes that all the methods and fields of a class have ASCII
|
|
names. The C++ compiler cannot correctly handle non-ASCII
|
|
identifiers. gcjh does not currently diagnose this problem.</para>
|
|
<para>
|
|
gcjh also cannot fully handle classes where a field and a method have
|
|
the same name. If the field is static, an error will result.
|
|
Otherwise, the field will be renamed in the generated header; `__'
|
|
will be appended to the field name.</para>
|
|
<para>
|
|
Eventually we hope to change the C++ compiler so that these
|
|
restrictions can be lifted.</para>
|
|
</sect1>
|
|
|
|
</article>
|