Elements
The most important object in &GStreamer; for the application programmer
is the GstElement
object. An element is the basic building block for a media pipeline. All
the different high-level components you will use are derived from
GstElement. Every decoder, encoder, demuxer, video
or audio output is in fact a GstElementWhat are elements?
For the application programmer, elements are best visualized as black
boxes. On the one end, you might put something in, the element does
something with it and something else comes out at the other side. For
a decoder element, for example, you'd put in encoded data, and the
element would output decoded data. In the next chapter (see ), you will learn more about data input and
output in elements, and how you can set that up in your application.
Source elements
Source elements generate data for use by a pipeline, for example
reading from disk or from a sound card. shows how we will visualise
a source element. We always draw a source pad to the right of
the element.
Source elements do not accept data, they only generate data. You can
see this in the figure because it only has a source pad (on the
right). A source pad can only generate data.
Filters, convertors, demuxers, muxers and codecs
Filters and filter-like elements have both input and outputs pads.
They operate on data that they receive on their input (sink) pads,
and will provide data on their output (source) pads. Examples of
such elements are a volume element (filter), a video scaler
(convertor), an Ogg demuxer or a Vorbis decoder.
Filter-like elements can have any number of source or sink pads. A
video demuxer, for example, would have one sink pad and several
(1-N) source pads, one for each elementary stream contained in the
container format. Decoders, on the other hand, will only have one
source and sink pads.
shows how we will
visualise a filter-like element. This specific element has one source
and one sink element. Sink pads, receiving input data, are depicted
at the left of the element; source pads are still on the right.
shows another
filter-like element, this one having more than one output (source)
pad. An example of one such element could, for example, be an Ogg
demuxer for an Ogg stream containing both audio and video. One
source pad will contain the elementary video stream, another will
contain the elementary audio stream. Demuxers will generally fire
signals when a new pad is created. The application programmer can
then handle the new elementary stream in the signal handler.
Sink elements
Sink elements are end points in a media pipeline. They accept
data but do not produce anything. Disk writing, soundcard playback,
and video output would all be implemented by sink elements.
shows a sink element.
Creating a GstElement
The simplest way to create an element is to use gst_element_factory_make
(). This function takes a factory name and an
element name for the newly created element. The name of the element
is something you can use later on to look up the element in a bin,
for example. The name will also be used in debug output. You can
pass NULL as the name argument to get a unique,
default name.
When you don't need the element anymore, you need to unref it using
gst_object_unref
(). This decreases the reference count for the
element by 1. An element has a refcount of 1 when it gets created.
An element gets destroyed completely when the refcount is decreased
to 0.
The following example &EXAFOOT; shows how to create an element named
source from the element factory named
fakesrc. It checks if the creation succeeded.
After checking, it unrefs the element.
int
main (int argc,
char *argv[])
{
GstElement *element;
/* init GStreamer */
gst_init (&argc, &argv);
/* create element */
element = gst_element_factory_make ("fakesrc", "source");
if (!element) {
g_print ("Failed to create element of type 'fakesrc'\n");
return -1;
}
gst_object_unref (GST_OBJECT (element));
return 0;
}
]]>gst_element_factory_make is actually a shorthand
for a combination of two functions. A GstElement
object is created from a factory. To create the element, you have to
get access to a GstElementFactory
object using a unique factory name. This is done with gst_element_factory_find
().
The following code fragment is used to get a factory that can be used
to create the fakesrc element, a fake data source.
The function gst_element_factory_create
() will use the element factory to create an
element with the given name.
int
main (int argc,
char *argv[])
{
GstElementFactory *factory;
GstElement * element;
/* init GStreamer */
gst_init (&argc, &argv);
/* create element, method #2 */
factory = gst_element_factory_find ("fakesrc");
if (!factory) {
g_print ("Failed to find factory of type 'fakesrc'\n");
return -1;
}
element = gst_element_factory_create (factory, "source");
if (!element) {
g_print ("Failed to create element, even though its factory exists!\n");
return -1;
}
gst_object_unref (GST_OBJECT (element));
return 0;
}
]]>Using an element as a GObject
A GstElement
can have several properties which are implemented using standard
GObject properties. The usual
GObject methods to query, set and get
property values and GParamSpecs are
therefore supported.
Every GstElement inherits at least one
property from its parent GstObject: the
"name" property. This is the name you provide to the functions
gst_element_factory_make () or
gst_element_factory_create (). You can get
and set this property using the functions
gst_object_set_name and
gst_object_get_name or use the
GObject property mechanism as shown below.
int
main (int argc,
char *argv[])
{
GstElement *element;
gchar *name;
/* init GStreamer */
gst_init (&argc, &argv);
/* create element */
element = gst_element_factory_make ("fakesrc", "source");
/* get name */
g_object_get (G_OBJECT (element), "name", &name, NULL);
g_print ("The name of the element is '%s'.\n", name);
g_free (name);
gst_object_unref (GST_OBJECT (element));
return 0;
}
]]>
Most plugins provide additional properties to provide more information
about their configuration or to configure the element.
gst-inspect is a useful tool to query the properties
of a particular element, it will also use property introspection to give
a short explanation about the function of the property and about the
parameter types and ranges it supports. See
in the appendix for details about gst-inspect.
For more information about GObject
properties we recommend you read the GObject manual and an introduction to
The Glib Object system.
A GstElement also provides various
GObject signals that can be used as a flexible
callback mechanism. Here, too, you can use gst-inspect
to see which signals a specific element supports. Together, signals
and properties are the most basic way in which elements and
applications interact.
More about element factories
In the previous section, we briefly introduced the GstElementFactory
object already as a way to create instances of an element. Element
factories, however, are much more than just that. Element factories
are the basic types retrieved from the &GStreamer; registry, they
describe all plugins and elements that &GStreamer; can create. This
means that element factories are useful for automated element
instancing, such as what autopluggers do, and for creating lists
of available elements, such as what pipeline editing applications
(e.g. &GStreamer;
Editor) do.
Getting information about an element using a factory
Tools like gst-inspect will provide some generic
information about an element, such as the person that wrote the
plugin, a descriptive name (and a shortname), a rank and a category.
The category can be used to get the type of the element that can
be created using this element factory. Examples of categories include
Codec/Decoder/Video (video decoder),
Codec/Encoder/Video (video encoder),
Source/Video (a video generator),
Sink/Video (a video output), and all these
exist for audio as well, of course. Then, there's also
Codec/Demuxer and
Codec/Muxer and a whole lot more.
gst-inspect will give a list of all factories, and
gst-inspect <factory-name> will list all
of the above information, and a lot more.
int
main (int argc,
char *argv[])
{
GstElementFactory *factory;
/* init GStreamer */
gst_init (&argc, &argv);
/* get factory */
factory = gst_element_factory_find ("fakesrc");
if (!factory) {
g_print ("You don't have the 'fakesrc' element installed!\n");
return -1;
}
/* display information */
g_print ("The '%s' element is a member of the category %s.\n"
"Description: %s\n",
gst_plugin_feature_get_name (GST_PLUGIN_FEATURE (factory)),
gst_element_factory_get_klass (factory),
gst_element_factory_get_description (factory));
return 0;
}
]]>
You can use gst_registry_pool_feature_list (GST_TYPE_ELEMENT_FACTORY)
to get a list of all the element factories that &GStreamer; knows
about.
Finding out what pads an element can contain
Perhaps the most powerful feature of element factories is that
they contain a full description of the pads that the element
can generate, and the capabilities of those pads (in layman words:
what types of media can stream over those pads), without actually
having to load those plugins into memory. This can be used
to provide a codec selection list for encoders, or it can be used
for autoplugging purposes for media players. All current
&GStreamer;-based media players and autopluggers work this way.
We'll look closer at these features as we learn about
GstPad and GstCaps
in the next chapter: Linking elements
By linking a source element with zero or more filter-like
elements and finally a sink element, you set up a media
pipeline. Data will flow through the elements. This is the
basic concept of media handling in &GStreamer;.
By linking these three elements, we have created a very simple
chain of elements. The effect of this will be that the output of
the source element (element1) will be used as input
for the filter-like element (element2). The
filter-like element will do something with the data and send the
result to the final sink element (element3).
Imagine the above graph as a simple Ogg/Vorbis audio decoder. The
source is a disk source which reads the file from disc. The second
element is a Ogg/Vorbis audio decoder. The sink element is your
soundcard, playing back the decoded audio data. We will use this
simple graph to construct an Ogg/Vorbis player later in this manual.
In code, the above graph is written like this:
#include <gst/gst.h>
int
main (int argc,
char *argv[])
{
GstElement *pipeline;
GstElement *source, *filter, *sink;
/* init */
gst_init (&argc, &argv);
/* create pipeline */
pipeline = gst_pipeline_new ("my-pipeline");
/* create elements */
source = gst_element_factory_make ("fakesrc", "source");
filter = gst_element_factory_make ("identity", "filter");
sink = gst_element_factory_make ("fakesink", "sink");
/* must add elements to pipeline before linking them */
gst_bin_add_many (GST_BIN (pipeline), source, filter, sink, NULL);
/* link */
if (!gst_element_link_many (source, filter, sink, NULL)) {
g_warning ("Failed to link elements!");
}
[..]
}
For more specific behaviour, there are also the functions
gst_element_link () and
gst_element_link_pads (). You can also obtain
references to individual pads and link those using various
gst_pad_link_* () functions. See the API
references for more details.
Important: you must add elements to a bin or pipeline
before linking them, since adding an element to
a bin will disconnect any already existing links. Also, you cannot
directly link elements that are not in the same bin or pipeline; if
you want to link elements or pads at different hierarchy levels, you
will need to use ghost pads (more about ghost pads later).
Element States
After being created, an element will not actually perform any actions
yet. You need to change elements state to make it do something.
&GStreamer; knows four element states, each with a very specific
meaning. Those four states are:
GST_STATE_NULL: this is the default state.
No resources are allocated in this state, so, transitioning to it
will free all resources. The element must be in this state when
its refcount reaches 0 and it is freed.
GST_STATE_READY: in the ready state, an
element has allocated all of its global resources, that is,
resources that can be kept within streams. You can think about
opening devices, allocating buffers and so on. However, the
stream is not opened in this state, so the stream positions is
automatically zero. If a stream was previously opened, it should
be closed in this state, and position, properties and such should
be reset.
GST_STATE_PAUSED: in this state, an
element has opened the stream, but is not actively processing
it. An element is allowed to modify a stream's position, read
and process data and such to prepare for playback as soon as
state is changed to PLAYING, but it is not
allowed to play the data which would make the clock run.
In summary, PAUSED is the same as PLAYING but without a running
clock.
Elements going into the PAUSED state should prepare themselves
for moving over to the PLAYING state as soon as possible. Video
or audio outputs would, for example, wait for data to arrive and
queue it so they can play it right after the state change. Also,
video sinks can already play the first frame (since this does
not affect the clock yet). Autopluggers could use this same
state transition to already plug together a pipeline. Most other
elements, such as codecs or filters, do not need to explicitely
do anything in this state, however.
GST_STATE_PLAYING: in the PLAYING state,
an element does exactly the same as in the PAUSED state, except
that the clock now runs.
You can change the state of an element using the function
gst_element_set_state (). If you set an element
to another state, &GStreamer; will internally traverse all intermediate
states. So if you set an element from NULL to PLAYING, &GStreamer;
will internally set the element to READY and PAUSED in between.
When moved to GST_STATE_PLAYING, pipelines
will process data automatically. They do not need to be iterated in
any form. Internally, &GStreamer; will start threads that take this
task on to them. &GStreamer; will also take care of switching
messages from the pipeline's thread into the application's own
thread, by using a GstBus. See
for details.