Documentation/driver-api/soundwire/stream.rst - linux - Git at Google

 =========================
 Audio Stream in SoundWire
 =========================

 An audio stream is a logical or virtual connection created between

   (1) System memory buffer(s) and Codec(s)

   (2) DSP memory buffer(s) and Codec(s)

   (3) FIFO(s) and Codec(s)

   (4) Codec(s) and Codec(s)

 which is typically driven by a DMA(s) channel through the data link. An
 audio stream contains one or more channels of data. All channels within
 stream must have same sample rate and same sample size.

 Assume a stream with two channels (Left & Right) is opened using SoundWire
 interface. Below are some ways a stream can be represented in SoundWire.

 Stream Sample in memory (System memory, DSP memory or FIFOs) ::

 	-------------------------
 	| L | R | L | R | L | R |
 	-------------------------

 Example 1: Stereo Stream with L and R channels is rendered from Master to
 Slave. Both Master and Slave is using single port. ::

 	+---------------+                    Clock Signal  +---------------+
 	|    Master     +----------------------------------+     Slave     |
 	|   Interface   |                                  |   Interface   |
 	|               |                                  |       1       |
 	|               |                     Data Signal  |               |
 	|    L  +  R    +----------------------------------+    L  +  R    |
 	|     (Data)    |     Data Direction               |     (Data)    |
 	+---------------+  +----------------------->       +---------------+


 Example 2: Stereo Stream with L and R channels is captured from Slave to
 Master. Both Master and Slave is using single port. ::


 	+---------------+                    Clock Signal  +---------------+
 	|    Master     +----------------------------------+     Slave     |
 	|   Interface   |                                  |   Interface   |
 	|               |                                  |       1       |
 	|               |                     Data Signal  |               |
 	|    L  +  R    +----------------------------------+    L  +  R    |
 	|     (Data)    |     Data Direction               |     (Data)    |
 	+---------------+  <-----------------------+       +---------------+


 Example 3: Stereo Stream with L and R channels is rendered by Master. Each
 of the L and R channel is received by two different Slaves. Master and both
 Slaves are using single port. ::

 	+---------------+                    Clock Signal  +---------------+
 	|    Master     +---------+------------------------+     Slave     |
 	|   Interface   |         |                        |   Interface   |
 	|               |         |                        |       1       |
 	|               |         |           Data Signal  |               |
 	|    L  +  R    +---+------------------------------+       L       |
 	|     (Data)    |   |     |    Data Direction      |     (Data)    |
 	+---------------+   |     |   +------------->      +---------------+
 	                    |     |
 	                    |     |
 	                    |     |                        +---------------+
 	                    |     +----------------------> |     Slave     |
 	                    |                              |   Interface   |
 	                    |                              |       2       |
 	                    |                              |               |
 	                    +----------------------------> |       R       |
 	                                                   |     (Data)    |
 	                                                   +---------------+


 Example 4: Stereo Stream with L and R channel is rendered by two different
 Ports of the Master and is received by only single Port of the Slave
 interface. ::

 	+--------------------+
 	|                    |
 	|     +--------------+                             +----------------+
 	|     |             ||                             |                |
 	|     |  Data Port  ||  L Channel                  |                |
 	|     |      1      |------------+                 |                |
 	|     |  L Channel  ||           |                 +-----+----+     |
 	|     |   (Data)    ||           |   L + R Channel ||    Data |     |
 	| Master  +----------+           | +---+---------> ||    Port |     |
 	| Interface          |           |                 ||     1   |     |
 	|     +--------------+           |                 ||         |     |
 	|     |             ||           |                 +----------+     |
 	|     |  Data Port  |------------+                 |                |
 	|     |      2      ||  R Channel                  |     Slave      |
 	|     |  R Channel  ||                             |   Interface    |
 	|     |   (Data)    ||                             |       1        |
 	|     +--------------+         Clock Signal        |     L  +  R    |
 	|                    +---------------------------> |      (Data)    |
 	+--------------------+                             |                |
 							   +----------------+

 SoundWire Stream Management flow
 ================================

 Stream definitions
 ------------------

   (1) Current stream: This is classified as the stream on which operation has
       to be performed like prepare, enable, disable, de-prepare etc.

   (2) Active stream: This is classified as the stream which is already active
       on Bus other than current stream. There can be multiple active streams
       on the Bus.

 SoundWire Bus manages stream operations for each stream getting
 rendered/captured on the SoundWire Bus. This section explains Bus operations
 done for each of the stream allocated/released on Bus. Following are the
 stream states maintained by the Bus for each of the audio stream.


 SoundWire stream states
 -----------------------

 Below shows the SoundWire stream states and state transition diagram. ::

 	+-----------+     +------------+     +----------+     +----------+
 	| ALLOCATED +---->| CONFIGURED +---->| PREPARED +---->| ENABLED  |
 	|   STATE   |     |    STATE   |     |  STATE   |     |  STATE   |
 	+-----------+     +------------+     +----------+     +----+-----+
 	                                                           ^
 	                                                           |
 	                                                           |
 	                                                           v
 	         +----------+           +------------+        +----+-----+
 	         | RELEASED |<----------+ DEPREPARED |<-------+ DISABLED |
 	         |  STATE   |           |   STATE    |        |  STATE   |
 	         +----------+           +------------+        +----------+

 NOTE: State transition between prepare and deprepare is supported in Spec
 but not in the software (subsystem)

 NOTE2: Stream state transition checks need to be handled by caller
 framework, for example ALSA/ASoC. No checks for stream transition exist in
 SoundWire subsystem.

 Stream State Operations
 -----------------------

 Below section explains the operations done by the Bus on Master(s) and
 Slave(s) as part of stream state transitions.

 SDW_STREAM_ALLOCATED
 ~~~~~~~~~~~~~~~~~~~~

 Allocation state for stream. This is the entry state
 of the stream. Operations performed before entering in this state:

   (1) A stream runtime is allocated for the stream. This stream
       runtime is used as a reference for all the operations performed
       on the stream.

   (2) The resources required for holding stream runtime information are
       allocated and initialized. This holds all stream related information
       such as stream type (PCM/PDM) and parameters, Master and Slave
       interface associated with the stream, stream state etc.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_ALLOCATED``.

 Bus implements below API for allocate a stream which needs to be called once
 per stream. From ASoC DPCM framework, this stream state maybe linked to
 .startup() operation.

   .. code-block:: c
   int sdw_alloc_stream(char * stream_name);


 SDW_STREAM_CONFIGURED
 ~~~~~~~~~~~~~~~~~~~~~

 Configuration state of stream. Operations performed before entering in
 this state:

   (1) The resources allocated for stream information in SDW_STREAM_ALLOCATED
       state are updated here. This includes stream parameters, Master(s)
       and Slave(s) runtime information associated with current stream.

   (2) All the Master(s) and Slave(s) associated with current stream provide
       the port information to Bus which includes port numbers allocated by
       Master(s) and Slave(s) for current stream and their channel mask.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_CONFIGURED``.

 Bus implements below APIs for CONFIG state which needs to be called by
 the respective Master(s) and Slave(s) associated with stream. These APIs can
 only be invoked once by respective Master(s) and Slave(s). From ASoC DPCM
 framework, this stream state is linked to .hw_params() operation.

   .. code-block:: c
   int sdw_stream_add_master(struct sdw_bus * bus,
 		struct sdw_stream_config * stream_config,
 		struct sdw_ports_config * ports_config,
 		struct sdw_stream_runtime * stream);

   int sdw_stream_add_slave(struct sdw_slave * slave,
 		struct sdw_stream_config * stream_config,
 		struct sdw_ports_config * ports_config,
 		struct sdw_stream_runtime * stream);


 SDW_STREAM_PREPARED
 ~~~~~~~~~~~~~~~~~~~

 Prepare state of stream. Operations performed before entering in this state:

   (1) Bus parameters such as bandwidth, frame shape, clock frequency,
       are computed based on current stream as well as already active
       stream(s) on Bus. Re-computation is required to accommodate current
       stream on the Bus.

   (2) Transport and port parameters of all Master(s) and Slave(s) port(s) are
       computed for the current as well as already active stream based on frame
       shape and clock frequency computed in step 1.

   (3) Computed Bus and transport parameters are programmed in Master(s) and
       Slave(s) registers. The banked registers programming is done on the
       alternate bank (bank currently unused). Port(s) are enabled for the
       already active stream(s) on the alternate bank (bank currently unused).
       This is done in order to not disrupt already active stream(s).

   (4) Once all the values are programmed, Bus initiates switch to alternate
       bank where all new values programmed gets into effect.

   (5) Ports of Master(s) and Slave(s) for current stream are prepared by
       programming PrepareCtrl register.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_PREPARED``.

 Bus implements below API for PREPARE state which needs to be called once per
 stream. From ASoC DPCM framework, this stream state is linked to
 .prepare() operation.

   .. code-block:: c
   int sdw_prepare_stream(struct sdw_stream_runtime * stream);


 SDW_STREAM_ENABLED
 ~~~~~~~~~~~~~~~~~~

 Enable state of stream. The data port(s) are enabled upon entering this state.
 Operations performed before entering in this state:

   (1) All the values computed in SDW_STREAM_PREPARED state are programmed
       in alternate bank (bank currently unused). It includes programming of
       already active stream(s) as well.

   (2) All the Master(s) and Slave(s) port(s) for the current stream are
       enabled on alternate bank (bank currently unused) by programming
       ChannelEn register.

   (3) Once all the values are programmed, Bus initiates switch to alternate
       bank where all new values programmed gets into effect and port(s)
       associated with current stream are enabled.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_ENABLED``.

 Bus implements below API for ENABLE state which needs to be called once per
 stream. From ASoC DPCM framework, this stream state is linked to
 .trigger() start operation.

   .. code-block:: c
   int sdw_enable_stream(struct sdw_stream_runtime * stream);

 SDW_STREAM_DISABLED
 ~~~~~~~~~~~~~~~~~~~

 Disable state of stream. The data port(s) are disabled upon exiting this state.
 Operations performed before entering in this state:

   (1) All the Master(s) and Slave(s) port(s) for the current stream are
       disabled on alternate bank (bank currently unused) by programming
       ChannelEn register.

   (2) All the current configuration of Bus and active stream(s) are programmed
       into alternate bank (bank currently unused).

   (3) Once all the values are programmed, Bus initiates switch to alternate
       bank where all new values programmed gets into effect and port(s) associated
       with current stream are disabled.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_DISABLED``.

 Bus implements below API for DISABLED state which needs to be called once
 per stream. From ASoC DPCM framework, this stream state is linked to
 .trigger() stop operation.

   .. code-block:: c
   int sdw_disable_stream(struct sdw_stream_runtime * stream);


 SDW_STREAM_DEPREPARED
 ~~~~~~~~~~~~~~~~~~~~~

 De-prepare state of stream. Operations performed before entering in this
 state:

   (1) All the port(s) of Master(s) and Slave(s) for current stream are
       de-prepared by programming PrepareCtrl register.

   (2) The payload bandwidth of current stream is reduced from the total
       bandwidth requirement of bus and new parameters calculated and
       applied by performing bank switch etc.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_DEPREPARED``.

 Bus implements below API for DEPREPARED state which needs to be called once
 per stream. From ASoC DPCM framework, this stream state is linked to
 .trigger() stop operation.

   .. code-block:: c
   int sdw_deprepare_stream(struct sdw_stream_runtime * stream);


 SDW_STREAM_RELEASED
 ~~~~~~~~~~~~~~~~~~~

 Release state of stream. Operations performed before entering in this state:

   (1) Release port resources for all Master(s) and Slave(s) port(s)
       associated with current stream.

   (2) Release Master(s) and Slave(s) runtime resources associated with
       current stream.

   (3) Release stream runtime resources associated with current stream.

 After all above operations are successful, stream state is set to
 ``SDW_STREAM_RELEASED``.

 Bus implements below APIs for RELEASE state which needs to be called by
 all the Master(s) and Slave(s) associated with stream. From ASoC DPCM
 framework, this stream state is linked to .hw_free() operation.

   .. code-block:: c
   int sdw_stream_remove_master(struct sdw_bus * bus,
 		struct sdw_stream_runtime * stream);
   int sdw_stream_remove_slave(struct sdw_slave * slave,
 		struct sdw_stream_runtime * stream);


 The .shutdown() ASoC DPCM operation calls below Bus API to release
 stream assigned as part of ALLOCATED state.

 In .shutdown() the data structure maintaining stream state are freed up.

   .. code-block:: c
   void sdw_release_stream(struct sdw_stream_runtime * stream);

 Not Supported
 =============

 1. A single port with multiple channels supported cannot be used between two
 streams or across stream. For example a port with 4 channels cannot be used
 to handle 2 independent stereo streams even though it's possible in theory
 in SoundWire.
	=========================
	Audio Stream in SoundWire
	=========================

	An audio stream is a logical or virtual connection created between

	(1) System memory buffer(s) and Codec(s)

	(2) DSP memory buffer(s) and Codec(s)

	(3) FIFO(s) and Codec(s)

	(4) Codec(s) and Codec(s)

	which is typically driven by a DMA(s) channel through the data link. An
	audio stream contains one or more channels of data. All channels within
	stream must have same sample rate and same sample size.

	Assume a stream with two channels (Left & Right) is opened using SoundWire
	interface. Below are some ways a stream can be represented in SoundWire.

	Stream Sample in memory (System memory, DSP memory or FIFOs) ::

	-------------------------
	\| L \| R \| L \| R \| L \| R \|
	-------------------------

	Example 1: Stereo Stream with L and R channels is rendered from Master to
	Slave. Both Master and Slave is using single port. ::

	+---------------+ Clock Signal +---------------+
	\| Master +----------------------------------+ Slave \|
	\| Interface \| \| Interface \|
	\| \| \| 1 \|
	\| \| Data Signal \| \|
	\| L + R +----------------------------------+ L + R \|
	\| (Data) \| Data Direction \| (Data) \|
	+---------------+ +-----------------------> +---------------+


	Example 2: Stereo Stream with L and R channels is captured from Slave to
	Master. Both Master and Slave is using single port. ::


	+---------------+ Clock Signal +---------------+
	\| Master +----------------------------------+ Slave \|
	\| Interface \| \| Interface \|
	\| \| \| 1 \|
	\| \| Data Signal \| \|
	\| L + R +----------------------------------+ L + R \|
	\| (Data) \| Data Direction \| (Data) \|
	+---------------+ <-----------------------+ +---------------+


	Example 3: Stereo Stream with L and R channels is rendered by Master. Each
	of the L and R channel is received by two different Slaves. Master and both
	Slaves are using single port. ::

	+---------------+ Clock Signal +---------------+
	\| Master +---------+------------------------+ Slave \|
	\| Interface \| \| \| Interface \|
	\| \| \| \| 1 \|
	\| \| \| Data Signal \| \|
	\| L + R +---+------------------------------+ L \|
	\| (Data) \| \| \| Data Direction \| (Data) \|
	+---------------+ \| \| +-------------> +---------------+
	\| \|
	\| \|
	\| \| +---------------+
	\| +----------------------> \| Slave \|
	\| \| Interface \|
	\| \| 2 \|
	\| \| \|
	+----------------------------> \| R \|
	\| (Data) \|
	+---------------+


	Example 4: Stereo Stream with L and R channel is rendered by two different
	Ports of the Master and is received by only single Port of the Slave
	interface. ::

	+--------------------+
	\| \|
	\| +--------------+ +----------------+
	\| \| \|\| \| \|
	\| \| Data Port \|\| L Channel \| \|
	\| \| 1 \|------------+ \| \|
	\| \| L Channel \|\| \| +-----+----+ \|
	\| \| (Data) \|\| \| L + R Channel \|\| Data \| \|
	\| Master +----------+ \| +---+---------> \|\| Port \| \|
	\| Interface \| \| \|\| 1 \| \|
	\| +--------------+ \| \|\| \| \|
	\| \| \|\| \| +----------+ \|
	\| \| Data Port \|------------+ \| \|
	\| \| 2 \|\| R Channel \| Slave \|
	\| \| R Channel \|\| \| Interface \|
	\| \| (Data) \|\| \| 1 \|
	\| +--------------+ Clock Signal \| L + R \|
	\| +---------------------------> \| (Data) \|
	+--------------------+ \| \|
	+----------------+

	SoundWire Stream Management flow
	================================

	Stream definitions
	------------------

	(1) Current stream: This is classified as the stream on which operation has
	to be performed like prepare, enable, disable, de-prepare etc.

	(2) Active stream: This is classified as the stream which is already active
	on Bus other than current stream. There can be multiple active streams
	on the Bus.

	SoundWire Bus manages stream operations for each stream getting
	rendered/captured on the SoundWire Bus. This section explains Bus operations
	done for each of the stream allocated/released on Bus. Following are the
	stream states maintained by the Bus for each of the audio stream.


	SoundWire stream states
	-----------------------

	Below shows the SoundWire stream states and state transition diagram. ::

	+-----------+ +------------+ +----------+ +----------+
	\| ALLOCATED +---->\| CONFIGURED +---->\| PREPARED +---->\| ENABLED \|
	\| STATE \| \| STATE \| \| STATE \| \| STATE \|
	+-----------+ +------------+ +----------+ +----+-----+
	^
	\|
	\|
	v
	+----------+ +------------+ +----+-----+
	\| RELEASED \|<----------+ DEPREPARED \|<-------+ DISABLED \|
	\| STATE \| \| STATE \| \| STATE \|
	+----------+ +------------+ +----------+

	NOTE: State transition between prepare and deprepare is supported in Spec
	but not in the software (subsystem)

	NOTE2: Stream state transition checks need to be handled by caller
	framework, for example ALSA/ASoC. No checks for stream transition exist in
	SoundWire subsystem.

	Stream State Operations
	-----------------------

	Below section explains the operations done by the Bus on Master(s) and
	Slave(s) as part of stream state transitions.

	SDW_STREAM_ALLOCATED
	~~~~~~~~~~~~~~~~~~~~

	Allocation state for stream. This is the entry state
	of the stream. Operations performed before entering in this state:

	(1) A stream runtime is allocated for the stream. This stream
	runtime is used as a reference for all the operations performed
	on the stream.

	(2) The resources required for holding stream runtime information are
	allocated and initialized. This holds all stream related information
	such as stream type (PCM/PDM) and parameters, Master and Slave
	interface associated with the stream, stream state etc.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_ALLOCATED``.

	Bus implements below API for allocate a stream which needs to be called once
	per stream. From ASoC DPCM framework, this stream state maybe linked to
	.startup() operation.

	.. code-block:: c
	int sdw_alloc_stream(char * stream_name);


	SDW_STREAM_CONFIGURED
	~~~~~~~~~~~~~~~~~~~~~

	Configuration state of stream. Operations performed before entering in
	this state:

	(1) The resources allocated for stream information in SDW_STREAM_ALLOCATED
	state are updated here. This includes stream parameters, Master(s)
	and Slave(s) runtime information associated with current stream.

	(2) All the Master(s) and Slave(s) associated with current stream provide
	the port information to Bus which includes port numbers allocated by
	Master(s) and Slave(s) for current stream and their channel mask.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_CONFIGURED``.

	Bus implements below APIs for CONFIG state which needs to be called by
	the respective Master(s) and Slave(s) associated with stream. These APIs can
	only be invoked once by respective Master(s) and Slave(s). From ASoC DPCM
	framework, this stream state is linked to .hw_params() operation.

	.. code-block:: c
	int sdw_stream_add_master(struct sdw_bus * bus,
	struct sdw_stream_config * stream_config,
	struct sdw_ports_config * ports_config,
	struct sdw_stream_runtime * stream);

	int sdw_stream_add_slave(struct sdw_slave * slave,
	struct sdw_stream_config * stream_config,
	struct sdw_ports_config * ports_config,
	struct sdw_stream_runtime * stream);


	SDW_STREAM_PREPARED
	~~~~~~~~~~~~~~~~~~~

	Prepare state of stream. Operations performed before entering in this state:

	(1) Bus parameters such as bandwidth, frame shape, clock frequency,
	are computed based on current stream as well as already active
	stream(s) on Bus. Re-computation is required to accommodate current
	stream on the Bus.

	(2) Transport and port parameters of all Master(s) and Slave(s) port(s) are
	computed for the current as well as already active stream based on frame
	shape and clock frequency computed in step 1.

	(3) Computed Bus and transport parameters are programmed in Master(s) and
	Slave(s) registers. The banked registers programming is done on the
	alternate bank (bank currently unused). Port(s) are enabled for the
	already active stream(s) on the alternate bank (bank currently unused).
	This is done in order to not disrupt already active stream(s).

	(4) Once all the values are programmed, Bus initiates switch to alternate
	bank where all new values programmed gets into effect.

	(5) Ports of Master(s) and Slave(s) for current stream are prepared by
	programming PrepareCtrl register.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_PREPARED``.

	Bus implements below API for PREPARE state which needs to be called once per
	stream. From ASoC DPCM framework, this stream state is linked to
	.prepare() operation.

	.. code-block:: c
	int sdw_prepare_stream(struct sdw_stream_runtime * stream);


	SDW_STREAM_ENABLED
	~~~~~~~~~~~~~~~~~~

	Enable state of stream. The data port(s) are enabled upon entering this state.
	Operations performed before entering in this state:

	(1) All the values computed in SDW_STREAM_PREPARED state are programmed
	in alternate bank (bank currently unused). It includes programming of
	already active stream(s) as well.

	(2) All the Master(s) and Slave(s) port(s) for the current stream are
	enabled on alternate bank (bank currently unused) by programming
	ChannelEn register.

	(3) Once all the values are programmed, Bus initiates switch to alternate
	bank where all new values programmed gets into effect and port(s)
	associated with current stream are enabled.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_ENABLED``.

	Bus implements below API for ENABLE state which needs to be called once per
	stream. From ASoC DPCM framework, this stream state is linked to
	.trigger() start operation.

	.. code-block:: c
	int sdw_enable_stream(struct sdw_stream_runtime * stream);

	SDW_STREAM_DISABLED
	~~~~~~~~~~~~~~~~~~~

	Disable state of stream. The data port(s) are disabled upon exiting this state.
	Operations performed before entering in this state:

	(1) All the Master(s) and Slave(s) port(s) for the current stream are
	disabled on alternate bank (bank currently unused) by programming
	ChannelEn register.

	(2) All the current configuration of Bus and active stream(s) are programmed
	into alternate bank (bank currently unused).

	(3) Once all the values are programmed, Bus initiates switch to alternate
	bank where all new values programmed gets into effect and port(s) associated
	with current stream are disabled.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_DISABLED``.

	Bus implements below API for DISABLED state which needs to be called once
	per stream. From ASoC DPCM framework, this stream state is linked to
	.trigger() stop operation.

	.. code-block:: c
	int sdw_disable_stream(struct sdw_stream_runtime * stream);


	SDW_STREAM_DEPREPARED
	~~~~~~~~~~~~~~~~~~~~~

	De-prepare state of stream. Operations performed before entering in this
	state:

	(1) All the port(s) of Master(s) and Slave(s) for current stream are
	de-prepared by programming PrepareCtrl register.

	(2) The payload bandwidth of current stream is reduced from the total
	bandwidth requirement of bus and new parameters calculated and
	applied by performing bank switch etc.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_DEPREPARED``.

	Bus implements below API for DEPREPARED state which needs to be called once
	per stream. From ASoC DPCM framework, this stream state is linked to
	.trigger() stop operation.

	.. code-block:: c
	int sdw_deprepare_stream(struct sdw_stream_runtime * stream);


	SDW_STREAM_RELEASED
	~~~~~~~~~~~~~~~~~~~

	Release state of stream. Operations performed before entering in this state:

	(1) Release port resources for all Master(s) and Slave(s) port(s)
	associated with current stream.

	(2) Release Master(s) and Slave(s) runtime resources associated with
	current stream.

	(3) Release stream runtime resources associated with current stream.

	After all above operations are successful, stream state is set to
	``SDW_STREAM_RELEASED``.

	Bus implements below APIs for RELEASE state which needs to be called by
	all the Master(s) and Slave(s) associated with stream. From ASoC DPCM
	framework, this stream state is linked to .hw_free() operation.

	.. code-block:: c
	int sdw_stream_remove_master(struct sdw_bus * bus,
	struct sdw_stream_runtime * stream);
	int sdw_stream_remove_slave(struct sdw_slave * slave,
	struct sdw_stream_runtime * stream);


	The .shutdown() ASoC DPCM operation calls below Bus API to release
	stream assigned as part of ALLOCATED state.

	In .shutdown() the data structure maintaining stream state are freed up.

	.. code-block:: c
	void sdw_release_stream(struct sdw_stream_runtime * stream);

	Not Supported
	=============

	1. A single port with multiple channels supported cannot be used between two
	streams or across stream. For example a port with 4 channels cannot be used
	to handle 2 independent stereo streams even though it's possible in theory
	in SoundWire.