docs/pwg/building-state.xml - mtk-gstreamer-debian - Git at Google

 <chapter id="chapter-statemanage-states">
   <title>What are states?</title>
   <para>
     A state describes whether the element instance is initialized, whether it
     is ready to transfer data and whether it is currently handling data. There
     are four states defined in &GStreamer;:
   </para>
   <itemizedlist>
     <listitem>
       <para>
         <symbol>GST_STATE_NULL</symbol>
       </para>
     </listitem>
     <listitem>
       <para>
         <symbol>GST_STATE_READY</symbol>
       </para>
     </listitem>
     <listitem>
       <para>
         <symbol>GST_STATE_PAUSED</symbol>
       </para>
     </listitem>
     <listitem>
       <para>
         <symbol>GST_STATE_PLAYING</symbol>
       </para>
     </listitem>
   </itemizedlist>
   <para>
     which will from now on be referred to simply as <quote>NULL</quote>,
     <quote>READY</quote>, <quote>PAUSED</quote> and <quote>PLAYING</quote>.
   </para>
   <para>
     <symbol>GST_STATE_NULL</symbol> is the default state of an element. In this state, it
     has not allocated any runtime resources, it has not loaded any runtime
     libraries and it can obviously not handle data.
   </para>
   <para>
     <symbol>GST_STATE_READY</symbol> is the next state that an element can be in. In the
     READY state, an element has all default resources (runtime-libraries,
     runtime-memory) allocated. However, it has not yet allocated or defined
     anything that is stream-specific. When going from NULL to READY state
     (<symbol>GST_STATE_CHANGE_NULL_TO_READY</symbol>), an element should
     allocate any non-stream-specific resources and should load runtime-loadable
     libraries (if any). When going the other way around (from READY to NULL,
     <symbol>GST_STATE_CHANGE_READY_TO_NULL</symbol>), an element should unload
     these libraries and free all allocated resources. Examples of such
     resources are hardware devices. Note that files are generally streams,
     and these should thus be considered as stream-specific resources; therefore,
     they should <emphasis>not</emphasis> be allocated in this state.
   </para>
   <para>
     <symbol>GST_STATE_PAUSED</symbol> is the state in which an element is
     ready to accept and handle data. For most elements this state is the same
     as PLAYING. The only exception to this rule are sink elements. Sink
     elements only accept one single buffer of data and then block. At this
     point the pipeline is 'prerolled' and ready to render data immediately.
   </para>
   <para>
     <symbol>GST_STATE_PLAYING</symbol> is the highest state that an element
     can be in. For most elements this state is exactly the same as PAUSED,
     they accept and process events and buffers with data. Only sink elements
     need to differentiate between PAUSED and PLAYING state. In PLAYING state,
     sink elements actually render incoming data, e.g. output audio to a sound
     card or render video pictures to an image sink.
   </para>

   <sect1 id="section-statemanage-filters">
   <title>Managing filter state</title>
   <para>
     If at all possible, your element should derive from one of the new base
     classes (<xref linkend="chapter-other-base"/>). There are ready-made
     general purpose base classes for different types of sources, sinks and
     filter/transformation elements. In addition to those, specialised base
     classes exist for audio and video elements and others.
   </para>
   <para>
     If you use a base class, you will rarely have to handle state changes
     yourself. All you have to do is override the base class's start() and
     stop() virtual functions (might be called differently depending on the
     base class) and the base class will take care of everything for you.
   </para>
   <para>
     If, however, you do not derive from a ready-made base class, but from
     GstElement or some other class not built on top of a base class, you
     will most likely have to implement your own state change function to
     be notified of state changes. This is definitively necessary if your
     plugin is a demuxer or a muxer, as there are no base classes for
     muxers or demuxers yet.
   </para>
   <para>
     An element can be notified of state changes through a virtual function
     pointer. Inside this function, the element can initialize any sort of
     specific data needed by the element, and it can optionally fail to
     go from one state to another.
   </para>
   <para>
     Do not g_assert for unhandled state changes; this is taken care of by
     the GstElement base class.
   </para>
   <programlisting>
 static GstStateChangeReturn
 gst_my_filter_change_state (GstElement *element, GstStateChange transition);

 static void
 gst_my_filter_class_init (GstMyFilterClass *klass)
 {
   GstElementClass *element_class = GST_ELEMENT_CLASS (klass);

   element_class->change_state = gst_my_filter_change_state;
 }
 <!-- example-begin state.c a --><!--
 #include "init.func"
 #include "caps.func"
 #include "chain.func"
 #include "state.func"
 --><!-- example-end state.c a -->
 <!-- example-begin state.func a --><!--
 static gboolean
 gst_my_filter_allocate_memory (GstMyFilter * filter)
 {
   return TRUE;
 }
 static void
 gst_my_filter_free_memory (GstMyFilter * filter)
 {
 }
 --><!-- example-end state.func a -->
 <!-- example-begin state.func b -->
 static GstStateChangeReturn
 gst_my_filter_change_state (GstElement *element, GstStateChange transition)
 {
   GstStateChangeReturn ret = GST_STATE_CHANGE_SUCCESS;
   GstMyFilter *filter = GST_MY_FILTER (element);

   switch (transition) {
     case GST_STATE_CHANGE_NULL_TO_READY:
       if (!gst_my_filter_allocate_memory (filter))
         return GST_STATE_CHANGE_FAILURE;
       break;
     default:
       break;
   }

   ret = GST_ELEMENT_CLASS (parent_class)-&gt;change_state (element, transition);
   if (ret == GST_STATE_CHANGE_FAILURE)
     return ret;

   switch (transition) {
     case GST_STATE_CHANGE_READY_TO_NULL:
       gst_my_filter_free_memory (filter);
       break;
     default:
       break;
   }

   return ret;
 }
 <!-- example-end state.func b -->
 <!-- example-begin state.c b --><!--
 #include "register.func"
   --><!-- example-end state.c b --></programlisting>
   <para>
     Note that upwards (NULL=&gt;READY, READY=&gt;PAUSED, PAUSED=&gt;PLAYING)
     and downwards (PLAYING=&gt;PAUSED, PAUSED=&gt;READY, READY=&gt;NULL) state
     changes are handled in two separate blocks with the downwards state change
     handled only after we have chained up to the parent class's state
     change function. This is necessary in order to safely handle concurrent
     access by multiple threads.
   </para>
   <para>
     The reason for this is that in the case of downwards state changes
     you don't want to destroy allocated resources while your plugin's
     chain function (for example) is still accessing those resources in
     another thread. Whether your chain function might be running or not
     depends on the state of your plugin's pads, and the state of those
     pads is closely linked to the state of the element. Pad states are
     handled in the GstElement class's state change function, including
     proper locking, that's why it is essential to chain up before
     destroying allocated resources.
   </para>
   </sect1>
 </chapter>
	<chapter id="chapter-statemanage-states">
	<title>What are states?</title>
	<para>
	A state describes whether the element instance is initialized, whether it
	is ready to transfer data and whether it is currently handling data. There
	are four states defined in &GStreamer;:
	</para>
	<itemizedlist>
	<listitem>
	<para>
	<symbol>GST_STATE_NULL</symbol>
	</para>
	</listitem>
	<listitem>
	<para>
	<symbol>GST_STATE_READY</symbol>
	</para>
	</listitem>
	<listitem>
	<para>
	<symbol>GST_STATE_PAUSED</symbol>
	</para>
	</listitem>
	<listitem>
	<para>
	<symbol>GST_STATE_PLAYING</symbol>
	</para>
	</listitem>
	</itemizedlist>
	<para>
	which will from now on be referred to simply as <quote>NULL</quote>,
	<quote>READY</quote>, <quote>PAUSED</quote> and <quote>PLAYING</quote>.
	</para>
	<para>
	<symbol>GST_STATE_NULL</symbol> is the default state of an element. In this state, it
	has not allocated any runtime resources, it has not loaded any runtime
	libraries and it can obviously not handle data.
	</para>
	<para>
	<symbol>GST_STATE_READY</symbol> is the next state that an element can be in. In the
	READY state, an element has all default resources (runtime-libraries,
	runtime-memory) allocated. However, it has not yet allocated or defined
	anything that is stream-specific. When going from NULL to READY state
	(<symbol>GST_STATE_CHANGE_NULL_TO_READY</symbol>), an element should
	allocate any non-stream-specific resources and should load runtime-loadable
	libraries (if any). When going the other way around (from READY to NULL,
	<symbol>GST_STATE_CHANGE_READY_TO_NULL</symbol>), an element should unload
	these libraries and free all allocated resources. Examples of such
	resources are hardware devices. Note that files are generally streams,
	and these should thus be considered as stream-specific resources; therefore,
	they should <emphasis>not</emphasis> be allocated in this state.
	</para>
	<para>
	<symbol>GST_STATE_PAUSED</symbol> is the state in which an element is
	ready to accept and handle data. For most elements this state is the same
	as PLAYING. The only exception to this rule are sink elements. Sink
	elements only accept one single buffer of data and then block. At this
	point the pipeline is 'prerolled' and ready to render data immediately.
	</para>
	<para>
	<symbol>GST_STATE_PLAYING</symbol> is the highest state that an element
	can be in. For most elements this state is exactly the same as PAUSED,
	they accept and process events and buffers with data. Only sink elements
	need to differentiate between PAUSED and PLAYING state. In PLAYING state,
	sink elements actually render incoming data, e.g. output audio to a sound
	card or render video pictures to an image sink.
	</para>

	<sect1 id="section-statemanage-filters">
	<title>Managing filter state</title>
	<para>
	If at all possible, your element should derive from one of the new base
	classes (<xref linkend="chapter-other-base"/>). There are ready-made
	general purpose base classes for different types of sources, sinks and
	filter/transformation elements. In addition to those, specialised base
	classes exist for audio and video elements and others.
	</para>
	<para>
	If you use a base class, you will rarely have to handle state changes
	yourself. All you have to do is override the base class's start() and
	stop() virtual functions (might be called differently depending on the
	base class) and the base class will take care of everything for you.
	</para>
	<para>
	If, however, you do not derive from a ready-made base class, but from
	GstElement or some other class not built on top of a base class, you
	will most likely have to implement your own state change function to
	be notified of state changes. This is definitively necessary if your
	plugin is a demuxer or a muxer, as there are no base classes for
	muxers or demuxers yet.
	</para>
	<para>
	An element can be notified of state changes through a virtual function
	pointer. Inside this function, the element can initialize any sort of
	specific data needed by the element, and it can optionally fail to
	go from one state to another.
	</para>
	<para>
	Do not g_assert for unhandled state changes; this is taken care of by
	the GstElement base class.
	</para>
	<programlisting>
	static GstStateChangeReturn
	gst_my_filter_change_state (GstElement *element, GstStateChange transition);

	static void
	gst_my_filter_class_init (GstMyFilterClass *klass)
	{
	GstElementClass *element_class = GST_ELEMENT_CLASS (klass);

	element_class->change_state = gst_my_filter_change_state;
	}
	<!-- example-begin state.c a --><!--
	#include "init.func"
	#include "caps.func"
	#include "chain.func"
	#include "state.func"
	--><!-- example-end state.c a -->
	<!-- example-begin state.func a --><!--
	static gboolean
	gst_my_filter_allocate_memory (GstMyFilter * filter)
	{
	return TRUE;
	}
	static void
	gst_my_filter_free_memory (GstMyFilter * filter)
	{
	}
	--><!-- example-end state.func a -->
	<!-- example-begin state.func b -->
	static GstStateChangeReturn
	gst_my_filter_change_state (GstElement *element, GstStateChange transition)
	{
	GstStateChangeReturn ret = GST_STATE_CHANGE_SUCCESS;
	GstMyFilter *filter = GST_MY_FILTER (element);

	switch (transition) {
	case GST_STATE_CHANGE_NULL_TO_READY:
	if (!gst_my_filter_allocate_memory (filter))
	return GST_STATE_CHANGE_FAILURE;
	break;
	default:
	break;
	}

	ret = GST_ELEMENT_CLASS (parent_class)->change_state (element, transition);
	if (ret == GST_STATE_CHANGE_FAILURE)
	return ret;

	switch (transition) {
	case GST_STATE_CHANGE_READY_TO_NULL:
	gst_my_filter_free_memory (filter);
	break;
	default:
	break;
	}

	return ret;
	}
	<!-- example-end state.func b -->
	<!-- example-begin state.c b --><!--
	#include "register.func"
	--><!-- example-end state.c b --></programlisting>
	<para>
	Note that upwards (NULL=>READY, READY=>PAUSED, PAUSED=>PLAYING)
	and downwards (PLAYING=>PAUSED, PAUSED=>READY, READY=>NULL) state
	changes are handled in two separate blocks with the downwards state change
	handled only after we have chained up to the parent class's state
	change function. This is necessary in order to safely handle concurrent
	access by multiple threads.
	</para>
	<para>
	The reason for this is that in the case of downwards state changes
	you don't want to destroy allocated resources while your plugin's
	chain function (for example) is still accessing those resources in
	another thread. Whether your chain function might be running or not
	depends on the state of your plugin's pads, and the state of those
	pads is closely linked to the state of the element. Pad states are
	handled in the GstElement class's state change function, including
	proper locking, that's why it is essential to chain up before
	destroying allocated resources.
	</para>
	</sect1>
	</chapter>