gstreamer/docs/pwg/building-boiler.xml

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<!-- ############ chapter ############# -->
<chapter id="chapter-building-boiler" xreflabel="Constructing the Boilerplate">
<title>Constructing the Boilerplate</title>
<para>
In this chapter you will learn how to construct the bare minimum code for a
new plugin. Starting from ground zero, you will see how to get the
&GStreamer; template source. Then you will learn how to use a few basic
tools to copy and modify a template plugin to create a new plugin. If you
follow the examples here, then by the end of this chapter you will have a
functional audio filter plugin that you can compile and use in &GStreamer;
applications.
</para>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-source" xreflabel="Getting the GStreamer Plugin Templates">
<title>Getting the GStreamer Plugin Templates</title>
<para>
There are currently two ways to develop a new plugin for &GStreamer;: You
can write the entire plugin by hand, or you can copy an existing plugin
template and write the plugin code you need. The second method is by far
the simpler of the two, so the first method will not even be described
here. (Errm, that is, <quote>it is left as an exercise to the
reader.</quote>)
</para>
<para>
The first step is to check out a copy of the
<filename>gst-template</filename> CVS module to get an important tool and
the source code template for a basic &GStreamer; plugin. To check out the
<filename>gst-template</filename> module, make sure you are connected to
the internet, and type the following commands at a command console:
</para>
<screen>
<prompt>shell $ </prompt><userinput>cvs -d:pserver:anoncvs@cvs.freedesktop.org/cvs/gstreamer co login</userinput>
Logging in to :pserver:anoncvs@cvs.freedesktop.org:/cvs/gstreamer
CVS password: <keycap>[ENTER]</keycap>
<prompt>shell $ </prompt><userinput>cvs -z3 -d:pserver:anoncvs@cvs.freedesktop.org:/cvs/gstreamer co gst-template</userinput>
U gst-template/README
U gst-template/gst-app/AUTHORS
U gst-template/gst-app/ChangeLog
U gst-template/gst-app/Makefile.am
U gst-template/gst-app/NEWS
U gst-template/gst-app/README
U gst-template/gst-app/autogen.sh
U gst-template/gst-app/configure.ac
U gst-template/gst-app/src/Makefile.am
...
</screen>
<para>
After the first command, you will have to press <keycap>ENTER</keycap> to
log in to the CVS server. (You might have to log in twice.) The second
command will check out a series of files and directories into <filename
class="directory">./gst-template</filename>. The template you will be
using is in <filename
class="directory">./gst-template/gst-plugin/</filename> directory. You
should look over the files in that directory to get a general idea of the
structure of a source tree for a plugin.
</para>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-project-stamp" xreflabel="Using the Project Stamp">
<title>Using the Project Stamp</title>
<!-- FIXME
This section needs some fixing from someone that is aware of how this
works. The only tool that looks like the ones cited there is
<filename>gst-plugins/tools/filterstamp.sh</filename>
-->
<para>
The first thing to do when making a new element is to specify some basic
details about it: what its name is, who wrote it, what version number it
is, etc. We also need to define an object to represent the element and to
store the data the element needs. These details are collectively known as
the <emphasis>boilerplate</emphasis>.
</para>
<para>
The standard way of defining the boilerplate is simply to write some code,
and fill in some structures. As mentioned in the previous section, the
easiest way to do this is to copy a template and add functionality
according to your needs. To help you do so, there are some tools in the
<filename class="directory">./gst-plugins/tools/</filename> directory.
One tool, <filename>gst-quick-stamp</filename>, is a quick command line
tool. The other, <filename>gst-project-stamp</filename>, is a full GNOME
druid application that takes you through the steps of creating a new
project (either a plugin or an application).
</para>
<para>
To use <command>pluginstamp.sh</command>, first open up a terminal window.
Change to the <filename class="directory">gst-template</filename>
directory, and then run the <command>pluginstamp.sh</command> command. The
arguments to the <command>pluginstamp.sh</command> are:
</para>
<orderedlist>
<listitem>
<para>the name of the plugin, and</para>
</listitem>
<listitem>
<para>
the directory that should hold a new subdirectory for the source tree
of the plugin.
</para>
</listitem>
</orderedlist>
<para>
Note that capitalization is important for the name of the plugin. Under
some operating systems, capitalization is also important when specifying
directory names. For example, the following commands create the
ExampleFilter plugin based on the plugin template and put the output files
in a new directory called <filename
class="directory">~/src/examplefilter/</filename>:
</para>
<screen>
<prompt>shell $ </prompt><userinput>cd gst-template</userinput>
<prompt>shell $ </prompt><userinput>tools/pluginstamp.sh ExampleFilter ~/src</userinput>
</screen>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-examine">
<title>Examining the Basic Code</title>
<para>
First we will examine the code you would be likely to place in a header
file (although since the interface to the code is entirely defined by the
gst/gstelement.c (gst_element_dispose): Protect against multiple invocations. Original commit message from CVS: 2004-02-24 Andy Wingo <wingo@pobox.com> * gst/gstelement.c (gst_element_dispose): Protect against multiple invocations. * gst/schedulers/gstoptimalscheduler.c I added a mess of prototypes at the top of the file by way of documentation. Some of the operations on chains and groups were re-organized. (create_group): Added a type argument so if the group is enabled, the setup_group_scheduler knows what to do. (group_elements): Added a type argument here, too, to be passed on to create_group. (group_element_set_enabled): If an unlinked PLAYING element is added to a bin, we have to create a new group to hold the element, and this function will be called before the group is added to the chain. Thus we have a valid case for group->chain==NULL. Instead of calling chain_group_set_enabled, just set the flag on the group (the chain's status will be set when the group is added to it). (gst_opt_scheduler_state_transition, chain_group_set_enabled): Setup the group scheduler when the group is enabled, not specifically when an element goes PAUSED->PLAYING. This means PLAYING elements can be added, linked, and scheduled into a PLAYING pipeline, as was intended. (add_to_group): Don't ref the group twice. I don't know when this double-ref got in here. Removing it has the potential to cause segfaults if other parts of the scheduler are buggy. If you find that the scheduler is segfaulting for you, put in an extra ref here and see if that hacks over the underlying issue. Of course, then find out what code is unreffing a group it doesn't own... (create_group): Make the extra refcount floating, and remove it after adding the element. This means that... (unref_group): Destroy when the refcount reaches 0, not 1, like every other refcounted object in the known universe. (remove_from_group): When a group becomes empty, set it to be not active, and remove it from its chain. Don't unref it again, there's no floating reference any more. (destroy_group): We have to remove the group from the chain in remove_from_group (rather than here) to break refcounting cycles (the chain always has a ref on the group). So assert that group->chain==NULL. (ref_group_by_count): Removed, it was commented out anyway. (merge_chains): Use the remove_from_chain and add_to_chain primitives to do the reparenting, instead of rolling our own implementation. (add_to_chain): The first non-disabled group in the chain's group list will be the entry point for the chain. Because buffers can accumulate in loop elements' peer bufpens, we preferentially schedule loop groups before get groups to avoid unnecessary execution of get-based groups when the bufpens are already full. (gst_opt_scheduler_schedule_run_queue): Debug fixes. (get_group_schedule_function): Ditto. (loop_group_schedule_function): Ditto. (gst_opt_scheduler_loop_wrapper): Ditto. (gst_opt_scheduler_iterate): Ditto. I understand the opt scheduler now, yippee! * gst/gstpad.c: All throughout, added FIXMEs to look at for 0.9. (gst_pad_get_name, gst_pad_set_chain_function) (gst_pad_set_get_function, gst_pad_set_event_function) (gst_pad_set_event_mask_function, gst_pad_get_event_masks) (gst_pad_get_event_masks_default, gst_pad_set_convert_function) (gst_pad_set_query_function, gst_pad_get_query_types) (gst_pad_get_query_types_default) (gst_pad_set_internal_link_function) (gst_pad_set_formats_function, gst_pad_set_link_function) (gst_pad_set_fixate_function, gst_pad_set_getcaps_function) (gst_pad_set_bufferalloc_function, gst_pad_unlink) (gst_pad_renegotiate, gst_pad_set_parent, gst_pad_get_parent) (gst_pad_add_ghost_pad, gst_pad_proxy_getcaps) (gst_pad_proxy_pad_link, gst_pad_proxy_fixate) (gst_pad_get_pad_template_caps, gst_pad_check_compatibility) (gst_pad_get_peer, gst_pad_get_allowed_caps) (gst_pad_alloc_buffer, gst_pad_push, gst_pad_pull) (gst_pad_selectv, gst_pad_select, gst_pad_template_get_caps) (gst_pad_event_default_dispatch, gst_pad_event_default) (gst_pad_dispatcher, gst_pad_send_event, gst_pad_convert_default) (gst_pad_convert, gst_pad_query_default, gst_pad_query) (gst_pad_get_formats_default, gst_pad_get_formats): Better argument checks, and some doc fixes. (gst_pad_custom_new_from_template): Um, does anyone use these functions? Actually make a custom pad instead of a normal one. (gst_pad_try_set_caps): Transpose some checks. (gst_pad_try_set_caps_nonfixed): Same, and use a macro to check if the pad is in negotiation. (gst_pad_try_relink_filtered): Use pad_link_prepare. * gst/gstelement.c: Remove prototypes also defined in gstclock.h. * gst/gstelement.h: * gst/gstclock.h: Un-deprecate the old clocking API, as discussed on the list.
2004-02-25 13:16:12 +00:00
plugin system, and doesn't depend on reading a header file, this is not
crucial.)
The code here can be found in
<filename>examples/pwg/examplefilter/boiler/gstexamplefilter.h</filename>.
</para>
<example id="ex-boiler-examine-h">
<title>Example Plugin Header File</title>
<programlisting><!-- example-begin filter.h a -->
#include &lt;gst/gst.h&gt;
/* Definition of structure storing data for this element. */
typedef struct _GstMyFilter {
GstElement element;
GstPad *sinkpad, *srcpad;
gboolean silent;
<!-- example-end filter.h a -->
<!-- example-begin filter.h b --><!--
gint samplerate, channels;
gint from_samplerate, to_samplerate;
gboolean passthrough;
guint64 offset;
--><!-- example-end filter.h b -->
<!-- example-begin filter.h c -->
} GstMyFilter;
/* Standard definition defining a class for this element. */
typedef struct _GstMyFilterClass {
GstElementClass parent_class;
} GstMyFilterClass;
/* Standard macros for defining types for this element. */
#define GST_TYPE_MY_FILTER \
(gst_my_filter_get_type())
#define GST_MY_FILTER(obj) \
(G_TYPE_CHECK_INSTANCE_CAST((obj),GST_TYPE_MY_FILTER,GstMyFilter))
#define GST_MY_FILTER_CLASS(klass) \
(G_TYPE_CHECK_CLASS_CAST((klass),GST_TYPE_MY_FILTER,GstMyFilterClass))
#define GST_IS_MY_FILTER(obj) \
(G_TYPE_CHECK_INSTANCE_TYPE((obj),GST_TYPE_MY_FILTER))
#define GST_IS_MY_FILTER_CLASS(obj) \
(G_TYPE_CHECK_CLASS_TYPE((klass),GST_TYPE_MY_FILTER))
/* Standard function returning type information. */
GType gst_my_filter_get_type (void);
<!-- example-end filter.h c --></programlisting>
</example>
<para>
Using this header file, you can use the following macro to setup
the <classname>GObject</classname> basics in your source file so
that all functions will be called appropriately:
</para>
<programlisting><!-- example-begin boilerplate.c a -->
#include "filter.h"
GST_BOILERPLATE (GstMyFilter, gst_my_filter, GstElement, GST_TYPE_ELEMENT);
<!-- example-end boilerplate.c a --></programlisting>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-details">
<title>GstElementDetails</title>
<para>
The GstElementDetails structure gives a hierarchical type for the element,
a human-readable description of the element, as well as author and version
data. The entries are:
</para>
<itemizedlist>
<listitem><para>
A long, english, name for the element.
</para></listitem><listitem><para>
The type of the element, as a hierarchy. The hierarchy is defined by
specifying the top level category, followed by a "/", followed by the
next level category, etc. The type should be defined according to the
guidelines elsewhere in this document. (FIXME: write the guidelines, and
give a better reference to them)
</para></listitem><listitem><para>
A brief description of the purpose of the element.
</para></listitem><listitem><para>
The name of the author of the element, optionally followed by a contact
email address in angle brackets.
</para></listitem>
</itemizedlist>
<para>
For example:
</para>
<programlisting><!-- example-begin boilerplate.c b -->
static GstElementDetails my_filter_details = {
"An example plugin",
"Example/FirstExample",
"Shows the basic structure of a plugin",
"your name &lt;your.name@your.isp&gt;"
};
<!-- example-end boilerplate.c b --></programlisting>
<para>
The element details are registered with the plugin during
the <function>_base_init ()</function> function, which is part of
the GObject system. The <function>_base_init ()</function> function
should be set for this GObject in the function where you register
the type with Glib.
</para>
<programlisting><!-- example-begin boilerplate.c c -->
static void
gst_my_filter_base_init (gpointer klass)
{
GstElementClass *element_class = GST_ELEMENT_CLASS (klass);
<!-- example-end boilerplate.c c -->
static GstElementDetails my_filter_details = {
[..]
};
[..]<!-- example-begin boilerplate.c d -->
gst_element_class_set_details (element_class, &amp;my_filter_details);
<!-- example-end boilerplate.c d -->
}
</programlisting>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-padtemplates">
<title>GstStaticPadTemplate</title>
<para>
A GstStaticPadTemplate is a description of a pad that the element will
(or might) create and use. It contains:
</para>
<itemizedlist>
<listitem>
<para>A short name for the pad.</para>
</listitem>
<listitem>
<para>Pad direction.</para>
</listitem>
<listitem>
<para>
Existence property. This indicates whether the pad exists always (an
<quote>always</quote> pad), only in some cases (a
<quote>sometimes</quote> pad) or only if the application requested
such a pad (a <quote>request</quote> pad).
</para>
</listitem>
<listitem>
<para>Supported types by this element (capabilities).</para>
</listitem>
</itemizedlist>
<para>
For example:
</para>
<programlisting><!-- example-begin boilerplate.c e -->
static GstStaticPadTemplate sink_factory =
GST_STATIC_PAD_TEMPLATE (
"sink",
GST_PAD_SINK,
GST_PAD_ALWAYS,
GST_STATIC_CAPS ("ANY")
);
<!-- example-end boilerplate.c e -->
<!-- example-begin boilerplate.c f --><!--
static GstStaticPadTemplate src_factory =
GST_STATIC_PAD_TEMPLATE (
"src",
GST_PAD_SRC,
GST_PAD_ALWAYS,
GST_STATIC_CAPS ("ANY")
);
--><!-- example-end boilerplate.c f -->
</programlisting>
<para>
Those pad templates are registered during the
<function>_base_init ()</function> function. Pads are created from these
templates in the element's <function>_init ()</function> function using
<function>gst_pad_new_from_template ()</function>. The template can be
retrieved from the element class using
<function>gst_element_class_get_pad_template ()</function>. See below
for more details on this. In order to create a new pad from this
template using <function>gst_pad_new_from_template ()</function>, you
will need to declare the pad template as a global variable. More on
this subject in <xref linkend="chapter-building-pads"/>.
</para>
<programlisting>
static GstStaticPadTemplate sink_factory = [..],
src_factory = [..];
static void
gst_my_filter_base_init (gpointer klass)
{
GstElementClass *element_class = GST_ELEMENT_CLASS (klass);
[..]
<!-- example-begin boilerplate.c g -->
gst_element_class_add_pad_template (element_class,
gst_static_pad_template_get (&amp;src_factory));
gst_element_class_add_pad_template (element_class,
gst_static_pad_template_get (&amp;sink_factory));
}
<!-- example-end boilerplate.c g -->
<!-- example-begin boilerplate.c h --><!--
static void
gst_my_filter_class_init (GstMyFilterClass * klass)
{
}
static void
gst_my_filter_init (GstMyFilter * filter)
{
}
#include "register.func"
--><!-- example-end boilerplate.c h --></programlisting>
<para>
The last argument in a template is its type
or list of supported types. In this example, we use 'ANY', which means
that this element will accept all input. In real-life situations, you
would set a mimetype and optionally a set of properties to make sure
that only supported input will come in. This representation should be
a string that starts with a mimetype, then a set of comma-separates
properties with their supported values. In case of an audio filter that
supports raw integer 16-bit audio, mono or stereo at any samplerate, the
correct template would look like this:
</para>
<programlisting>
static GstStaticPadTemplate sink_factory =
GST_STATIC_PAD_TEMPLATE (
"sink",
GST_PAD_SINK,
GST_PAD_ALWAYS,
GST_STATIC_CAPS (
"audio/x-raw-int, "
"width = (int) 16, "
"depth = (int) 16, "
"endianness = (int) BYTE_ORDER, "
"channels = (int) { 1, 2 }, "
"rate = (int) [ 8000, 96000 ]"
)
);
</programlisting>
<para>
Values surrounded by curly brackets (<quote>{</quote> and
<quote>}</quote>) are lists, values surrounded by square brackets
(<quote>[</quote> and <quote>]</quote>) are ranges.
Multiple sets of types are supported too, and should be separated by
a semicolon (<quote>;</quote>). Later, in the chapter on pads, we will
see how to use types to know the exact format of a stream:
<xref linkend="chapter-building-pads"/>.
</para>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-constructors">
<title>Constructor Functions</title>
<para>
Each element has three functions which are used for construction of an
element. These are the <function>_base_init()</function> function which
is meant to initialize class and child class properties during each new
child class creation; the <function>_class_init()</function> function,
which is used to initialise the class only once (specifying what signals,
arguments and virtual functions the class has and setting up global
state); and the <function>_init()</function> function, which is used to
initialise a specific instance of this type.
</para>
</sect1>
<!-- ############ sect1 ############# -->
<sect1 id="section-boiler-plugininit">
<title>The plugin_init function</title>
<para>
Once we have written code defining all the parts of the plugin, we need to
write the plugin_init() function. This is a special function, which is
called as soon as the plugin is loaded, and should return TRUE or FALSE
depending on whether it loaded initialized any dependencies correctly.
Also, in this function, any supported element type in the plugin should
be registered.
</para>
<programlisting><!-- example-begin register.func -->
static gboolean
plugin_init (GstPlugin *plugin)
{
return gst_element_register (plugin, "my_filter",
GST_RANK_NONE,
GST_TYPE_MY_FILTER);
}
GST_PLUGIN_DEFINE (
GST_VERSION_MAJOR,
GST_VERSION_MINOR,
"my_filter",
"My filter plugin",
plugin_init,
VERSION,
"LGPL",
"GStreamer",
"http://gstreamer.net/"
)
<!-- example-end register.func --></programlisting>
<para>
Note that the information returned by the plugin_init() function will be
cached in a central registry. For this reason, it is important that the
same information is always returned by the function: for example, it
must not make element factories available based on runtime conditions.
If an element can only work in certain conditions (for example, if the
soundcard is not being used by some other process) this must be reflected
by the element being unable to enter the READY state if unavailable,
rather than the plugin attempting to deny existence of the plugin.
</para>
</sect1>
</chapter>