gstreamer/examples/plugins/example.c

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/* Gnome-Streamer
* Copyright (C) <1999> Erik Walthinsen <omega@cse.ogi.edu>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
/* First, include the header file for the plugin, to bring in the
* object definition and other useful things.
*/
#include "example.h"
/* The ElementDetails structure gives a human-readable description
* of the plugin, as well as author and version data.
*/
static GstElementDetails example_details = {
"An example plugin",
"Example",
"Shows the basic structure of a plugin",
VERSION,
"your name <your.name@your.isp>",
"(C) 2000",
};
/* These are the signals that this element can fire. They are zero-
* based because the numbers themselves are private to the object.
* LAST_SIGNAL is used for initialization of the signal array.
*/
enum {
ASDF,
/* FILL ME */
LAST_SIGNAL
};
/* Arguments are identified the same way, but cannot be zero, so you
* must leave the ARG_0 entry in as a placeholder.
*/
enum {
ARG_0,
ARG_ACTIVE,
/* FILL ME */
};
/* The PadFactory structures describe what pads the element has or
* can have. They can be quite complex, but for this example plugin
* they are rather simple.
*/
static GstPadFactory sink_factory = {
"sink", /* The name of the pad */
GST_PAD_FACTORY_SINK, /* Direction of the pad */
GST_PAD_FACTORY_ALWAYS, /* The pad exists for every instance */
GST_PAD_FACTORY_CAPS( /* This factory has specific capabilities */
"example_sink", /* The name of the caps */
"unknown/unknown", /* The overall MIME/type */
"foo", GST_PROPS_INT (1), /* An integer property */
"bar", GST_PROPS_BOOLEAN (TRUE), /* A boolean */
"baz", GST_PROPS_LIST ( /* A list of values for */
GST_PROPS_INT (1),
GST_PROPS_INT (3)
)
),
NULL /* All factories must be NULL-terminated */
};
/* This factory is much simpler, and defines the source pad. */
static GstPadFactory src_factory = {
"src",
GST_PAD_FACTORY_SRC,
GST_PAD_FACTORY_ALWAYS,
GST_PAD_FACTORY_CAPS(
"example_src",
"unknown/unknown"
),
NULL
};
/* A number of functon prototypes are given so we can refer to them later. */
static void gst_example_class_init (GstExampleClass *klass);
static void gst_example_init (GstExample *example);
static void gst_example_chain (GstPad *pad, GstBuffer *buf);
static void gst_example_set_arg (GtkObject *object,GtkArg *arg,guint id);
static void gst_example_get_arg (GtkObject *object,GtkArg *arg,guint id);
/* These hold the constructed pad templates, which are created during
* plugin load, and used during element instantiation.
*/
static GstPadTemplate *src_template, *sink_template;
/* The parent class pointer needs to be kept around for some object
* operations.
*/
static GstElementClass *parent_class = NULL;
/* This array holds the ids of the signals registered for this object.
* The array indexes are based on the enum up above.
*/
static guint gst_example_signals[LAST_SIGNAL] = { 0 };
/* This function is used to register and subsequently return the type
* identifier for this object class. On first invocation, it will
* register the type, providing the name of the class, struct sizes,
* and pointers to the various functions that define the class.
*/
GtkType
gst_example_get_type(void)
{
static GtkType example_type = 0;
if (!example_type) {
static const GtkTypeInfo example_info = {
"GstExample",
sizeof(GstExample),
sizeof(GstExampleClass),
(GtkClassInitFunc)gst_example_class_init,
(GtkObjectInitFunc)gst_example_init,
(GtkArgSetFunc)NULL, /* These last three are depracated */
(GtkArgGetFunc)NULL,
(GtkClassInitFunc)NULL,
};
example_type = gtk_type_unique(GST_TYPE_ELEMENT,&example_info);
}
return example_type;
}
/* In order to create an instance of an object, the class must be
* initialized by this function. GtkObject will take care of running
* it, based on the pointer to the function provided above.
*/
static void
gst_example_class_init (GstExampleClass *klass)
{
/* Class pointers are needed to supply pointers to the private
* implementations of parent class methods.
*/
GtkObjectClass *gtkobject_class;
GstElementClass *gstelement_class;
/* Since the example class contains the parent classes, you can simply
* cast the pointer to get access to the parent classes.
*/
gtkobject_class = (GtkObjectClass*)klass;
gstelement_class = (GstElementClass*)klass;
/* The parent class is needed for class method overrides. */
parent_class = gtk_type_class(GST_TYPE_ELEMENT);
/* Here we add an argument to the object. This argument is an integer,
* and can be both read and written.
*/
gtk_object_add_arg_type("GstExample::active", GTK_TYPE_INT,
GTK_ARG_READWRITE, ARG_ACTIVE);
/* Here we add a signal to the object. This is avery useless signal
* called asdf. The signal will also pass a pointer to the listeners
* which happens to be the example element itself */
gst_example_signals[ASDF] =
gtk_signal_new("asdf", GTK_RUN_LAST, gtkobject_class->type,
GTK_SIGNAL_OFFSET (GstExampleClass, asdf),
gtk_marshal_NONE__POINTER, GTK_TYPE_NONE, 1,
GST_TYPE_EXAMPLE);
gtk_object_class_add_signals (gtkobject_class, gst_example_signals,
LAST_SIGNAL);
/* The last thing is to provide the functions that implement get and set
* of arguments.
*/
gtkobject_class->set_arg = gst_example_set_arg;
gtkobject_class->get_arg = gst_example_get_arg;
}
/* This function is responsible for initializing a specific instance of
* the plugin.
*/
static void
gst_example_init(GstExample *example)
{
/* First we create the sink pad, which is the input to the element.
* We will use the sink_template constructed in the plugin_init function
* (below) to quickly generate the pad we need.
*/
example->sinkpad = gst_pad_new_from_template (sink_template, "sink");
/* Setting the chain function allows us to supply the function that will
* actually be performing the work. Without this, the element would do
* nothing, with undefined results (assertion failures and such).
*/
gst_pad_set_chain_function(example->sinkpad,gst_example_chain);
/* We then must add this pad to the element's list of pads. The base
* element class manages the list of pads, and provides accessors to it.
*/
gst_element_add_pad(GST_ELEMENT(example),example->sinkpad);
/* The src pad, the output of the element, is created and registered
* in the same way, with the exception of the chain function. Source
* pads don't have chain functions, because they can't accept buffers,
* they only produce them.
*/
example->srcpad = gst_pad_new_from_template (src_template, "src");
gst_element_add_pad(GST_ELEMENT(example),example->srcpad);
/* Initialization of element's private variables. */
example->active = FALSE;
}
/* The chain function is the heart of the element. It's where all the
* work is done. It is passed a pointer to the pad in question, as well
* as the buffer provided by the peer element.
*/
static void
gst_example_chain (GstPad *pad, GstBuffer *buf)
{
GstExample *example;
GstBuffer *outbuf;
/* Some of these checks are of dubious value, since if there were not
* already true, the chain function would never be called.
*/
g_return_if_fail(pad != NULL);
g_return_if_fail(GST_IS_PAD(pad));
g_return_if_fail(buf != NULL);
/* We need to get a pointer to the element this pad belogs to. */
example = GST_EXAMPLE(gst_pad_get_parent (pad));
/* A few more sanity checks to make sure that the element that owns
* this pad is the right kind of element, in case something got confused.
*/
g_return_if_fail(example != NULL);
g_return_if_fail(GST_IS_EXAMPLE(example));
/* If we are supposed to be doing something, here's where it happens. */
if (example->active) {
/* In this example we're going to copy the buffer to another one,
* so we need to allocate a new buffer first. */
outbuf = gst_buffer_new();
/* We need to copy the size and offset of the buffer at a minimum. */
GST_BUFFER_SIZE (outbuf) = GST_BUFFER_SIZE (buf);
GST_BUFFER_OFFSET (outbuf) = GST_BUFFER_OFFSET (buf);
/* Then allocate the memory for the new buffer */
GST_BUFFER_DATA (outbuf) = (guchar *)g_malloc (GST_BUFFER_SIZE (outbuf));
/* Then copy the data in the incoming buffer into the new buffer. */
memcpy (GST_BUFFER_DATA (outbuf), GST_BUFFER_DATA (buf), GST_BUFFER_SIZE (outbuf));
/* When we're done with the buffer, we push it on to the next element
* in the pipeline, through the element's source pad, which is stored
* in the element's structure.
*/
gst_pad_push(example->srcpad,outbuf);
/* For fun we'll emit our useless signal here */
gtk_signal_emit (GTK_OBJECT (example), gst_example_signals[ASDF],
example);
/* If we're not doing something, just send the original incoming buffer. */
} else {
gst_pad_push(example->srcpad,buf);
}
}
/* Arguments are part of the Gtk+ object system, and these functions
* enable the element to respond to various arguments.
*/
static void
gst_example_set_arg (GtkObject *object,GtkArg *arg,guint id)
{
GstExample *example;
/* It's not null if we got it, but it might not be ours */
g_return_if_fail(GST_IS_EXAMPLE(object));
/* Get a pointer of the right type. */
example = GST_EXAMPLE(object);
/* Check the argument id to see which argument we're setting. */
switch (id) {
case ARG_ACTIVE:
/* Here we simply copy the value of the argument to our private
* storage. More complex operations can be done, but beware that
* they may occur at any time, possibly even while your chain function
* is running, if you are using threads.
*/
example->active = GTK_VALUE_INT(*arg);
g_print("example: set active to %d\n",example->active);
break;
default:
break;
}
}
/* The set function is simply the inverse of the get fuction. */
static void
gst_example_get_arg (GtkObject *object,GtkArg *arg,guint id)
{
GstExample *example;
/* It's not null if we got it, but it might not be ours */
g_return_if_fail(GST_IS_EXAMPLE(object));
example = GST_EXAMPLE(object);
switch (id) {
case ARG_ACTIVE:
GTK_VALUE_INT(*arg) = example->active;
break;
default:
arg->type = GTK_TYPE_INVALID;
break;
}
}
/* This is the entry into the plugin itself. When the plugin loads,
* this function is called to register everything that the plugin provides.
*/
GstPlugin*
plugin_init (GModule *module)
{
GstPlugin *plugin;
GstElementFactory *factory;
/* First we try to create a new Plugin structure. */
plugin = gst_plugin_new("example");
/* If we get a NULL back, chances are we're already loaded. */
g_return_val_if_fail(plugin != NULL, NULL);
/* We need to create an ElementFactory for each element we provide.
* This consists of the name of the element, the GtkType identifier,
* and a pointer to the details structure at the top of the file.
*/
factory = gst_elementfactory_new("example", GST_TYPE_EXAMPLE, &example_details);
g_return_val_if_fail(factory != NULL, NULL);
/* The pad templates can be easily generated from the factories above,
* and then added to the list of padtemplates for the elementfactory.
* Note that the generated padtemplates are stored in static global
* variables, for the gst_example_init function to use later on.
*/
sink_template = gst_padtemplate_new (&sink_factory);
gst_elementfactory_add_padtemplate (factory, sink_template);
src_template = gst_padtemplate_new (&src_factory);
gst_elementfactory_add_padtemplate (factory, src_template);
/* The very last thing is to register the elementfactory with the plugin. */
gst_plugin_add_factory (plugin, factory);
/* Now we can return the pointer to the newly created Plugin object. */
return plugin;
/* At this point, the GStreamer core registers the plugin, its
* elementfactories, padtemplates, etc., for use in you application.
*/
}