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ab9b52e69c
• Remove copies of function declarations from the explanation — if people want those, they can follow links to the reference manual. • Add markup to make C code more defined. • Remove use of first person and irrelevant name dropping. https://bugzilla.gnome.org/show_bug.cgi?id=744060
186 lines
9.1 KiB
XML
186 lines
9.1 KiB
XML
<?xml version='1.0' encoding="UTF-8"?>
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<!DOCTYPE chapter PUBLIC "-//OASIS//DTD DocBook XML V4.5//EN"
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"http://www.oasis-open.org/docbook/xml/4.5/docbookx.dtd" [
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]>
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<chapter id="chapter-intro">
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<title>Background</title>
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<para>
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GObject, and its lower-level type system, GType, are used by GTK+ and most GNOME libraries to
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provide:
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<itemizedlist>
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<listitem><para>object-oriented C-based APIs and</para></listitem>
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<listitem><para>automatic transparent API bindings to other compiled
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or interpreted languages.</para></listitem>
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</itemizedlist>
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</para>
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<para>
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A lot of programmers are used to working with compiled-only or dynamically interpreted-only
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languages and do not understand the challenges associated with cross-language interoperability.
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This introduction tries to provide an insight into these challenges and briefly describes
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the solution chosen by GLib.
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</para>
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<para>
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The following chapters go into greater detail into how GType and GObject work and
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how you can use them as a C programmer. It is useful to keep in mind that
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allowing access to C objects from other interpreted languages was one of the major design
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goals: this can often explain the sometimes rather convoluted APIs and features present
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in this library.
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</para>
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<sect1>
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<title>Data types and programming</title>
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<para>
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One could say
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that a programming language is merely a way to create data types and manipulate them. Most languages
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provide a number of language-native types and a few primitives to create more complex types based
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on these primitive types.
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</para>
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<para>
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In C, the language provides types such as <emphasis>char</emphasis>, <emphasis>long</emphasis>,
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<emphasis>pointer</emphasis>. During compilation of C code, the compiler maps these
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language types to the compiler's target architecture machine types. If you are using a C interpreter
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(assuming one exists), the interpreter (the program which interprets
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the source code and executes it) maps the language types to the machine types of the target machine at
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runtime, during the program execution (or just before execution if it uses a Just In Time compiler engine).
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</para>
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<para>
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Perl and Python are interpreted languages which do not really provide type definitions similar
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to those used by C. Perl and Python programmers manipulate variables and the type of the variables
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is decided only upon the first assignment or upon the first use which forces a type on the variable.
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The interpreter also often provides a lot of automatic conversions from one type to the other. For example,
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in Perl, a variable which holds an integer can be automatically converted to a string given the
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required context:
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<informalexample><programlisting>
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my $tmp = 10;
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print "this is an integer converted to a string:" . $tmp . "\n";
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</programlisting></informalexample>
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Of course, it is also often possible to explicitly specify conversions when the default conversions provided
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by the language are not intuitive.
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</para>
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</sect1>
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<sect1>
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<title>Exporting a C API</title>
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<para>
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C APIs are defined by a set of functions and global variables which are usually exported from a
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binary. C functions have an arbitrary number of arguments and one return value. Each function is thus
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uniquely identified by the function name and the set of C types which describe the function arguments
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and return value. The global variables exported by the API are similarly identified by their name and
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their type.
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</para>
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<para>
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A C API is thus merely defined by a set of names to which a set of types are associated. If you know the
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function calling convention and the mapping of the C types to the machine types used by the platform you
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are on, you can resolve the name of each function to find where the code associated to this function
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is located in memory, and then construct a valid argument list for the function. Finally, all you have to
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do is trigger a call to the target C function with the argument list.
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</para>
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<para>
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For the sake of discussion, here is a sample C function and the associated 32 bit x86
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assembly code generated by GCC on a Linux computer:
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<informalexample><programlisting>
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static void
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function_foo (int foo)
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{
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}
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int
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main (int argc,
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char *argv[])
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{
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function_foo (10);
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return 0;
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}
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push $0xa
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call 0x80482f4 <function_foo>
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</programlisting></informalexample>
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The assembly code shown above is pretty straightforward: the first instruction pushes
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the hexadecimal value 0xa (decimal value 10) as a 32-bit integer on the stack and calls
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<function>function_foo</function>. As you can see, C function calls are implemented by
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GCC as native function calls (this is probably the fastest implementation possible).
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</para>
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<para>
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Now, let's say we want to call the C function <function>function_foo</function> from
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a Python program. To do this, the Python interpreter needs to:
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<itemizedlist>
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<listitem><para>Find where the function is located. This probably means finding the binary generated by the C compiler
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which exports this function.</para></listitem>
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<listitem><para>Load the code of the function in executable memory.</para></listitem>
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<listitem><para>Convert the Python parameters to C-compatible parameters before calling
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the function.</para></listitem>
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<listitem><para>Call the function with the right calling convention.</para></listitem>
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<listitem><para>Convert the return values of the C function to Python-compatible
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variables to return them to the Python code.</para></listitem>
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</itemizedlist>
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</para>
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<para>
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The process described above is pretty complex and there are a lot of ways to make it entirely automatic
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and transparent to C and Python programmers:
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<itemizedlist>
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<listitem><para>The first solution is to write by hand a lot of glue code, once for each function exported or imported,
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which does the Python-to-C parameter conversion and the C-to-Python return value conversion. This glue code is then
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linked with the interpreter which allows Python programs to call Python functions which delegate work to
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C functions.</para></listitem>
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<listitem><para>Another, nicer solution is to automatically generate the glue code, once for each function exported or
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imported, with a special compiler which
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reads the original function signature.</para></listitem>
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<listitem><para>The solution used by GLib is to use the GType library which holds at runtime a description of
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all the objects manipulated by the programmer. This so-called <emphasis>dynamic type</emphasis>
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<footnote>
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<para>
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There are numerous different implementations of dynamic type systems: all C++
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compilers have one, Java and .NET have one too. A dynamic type system allows you
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to get information about every instantiated object at runtime. It can be implemented
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by a process-specific database: every new object created registers the characteristics
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of its associated type in the type system. It can also be implemented by introspection
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interfaces. The common point between all these different type systems and implementations
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is that they all allow you to query for object metadata at runtime.
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</para>
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</footnote>
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library is then used by special generic glue code to automatically convert function parameters and
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function calling conventions between different runtime domains.</para></listitem>
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</itemizedlist>
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The greatest advantage of the solution implemented by GType is that the glue code sitting at the runtime domain
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boundaries is written once: the figure below states this more clearly.
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<figure>
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<mediaobject>
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<imageobject> <!-- this is for HTML output -->
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<imagedata fileref="glue.png" format="PNG" align="center"/>
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</imageobject>
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<imageobject> <!-- this is for PDF output -->
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<imagedata fileref="glue.jpg" format="JPG" align="center"/>
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</imageobject>
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</mediaobject>
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</figure>
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Currently, there exist at least Python and Perl generic glue code which makes it possible to use
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C objects written with GType directly in Python or Perl, with a minimum amount of work: there
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is no need to generate huge amounts of glue code either automatically or by hand.
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</para>
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<para>
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Although that goal was arguably laudable, its pursuit has had a major influence on
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the whole GType/GObject library. C programmers are likely to be puzzled at the complexity
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of the features exposed in the following chapters if they forget that the GType/GObject library
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was not only designed to offer OO-like features to C programmers but also transparent
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cross-language interoperability.
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</para>
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</sect1>
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</chapter>
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