Documentation/sound/cards/hdspm.rst - linux/kernel/git/gregkh/usb - Git at Google

 =======================================
 Software Interface ALSA-DSP MADI Driver
 =======================================

 (translated from German, so no good English ;-),

 2004 - winfried ritsch


 Full functionality has been added to the driver. Since some of
 the Controls and startup-options  are ALSA-Standard and only the
 special Controls are described and discussed below.


 Hardware functionality
 ======================

 Audio transmission
 ------------------

 * number of channels --  depends on transmission mode

 		The number of channels chosen is from 1..Nmax. The reason to
 		use for a lower number of channels is only resource allocation,
 		since unused DMA channels are disabled and less memory is
 		allocated. So also the throughput of the PCI system can be
 		scaled. (Only important for low performance boards).

 * Single Speed -- 1..64 channels

 .. note::
 		 (Note: Choosing the 56channel mode for transmission or as
 		 receiver, only 56 are transmitted/received over the MADI, but
 		 all 64 channels are available for the mixer, so channel count
 		 for the driver)

 * Double Speed -- 1..32 channels

 .. note::
 		 Note: Choosing the 56-channel mode for
 		 transmission/receive-mode , only 28 are transmitted/received
 		 over the MADI, but all 32 channels are available for the mixer,
 		 so channel count for the driver


 * Quad Speed -- 1..16 channels

 .. note::
 		 Choosing the 56-channel mode for
 		 transmission/receive-mode , only 14 are transmitted/received
 		 over the MADI, but all 16 channels are available for the mixer,
 		 so channel count for the driver

 * Format -- signed 32 Bit Little Endian (SNDRV_PCM_FMTBIT_S32_LE)

 * Sample Rates --

        Single Speed -- 32000, 44100, 48000

        Double Speed -- 64000, 88200, 96000 (untested)

        Quad Speed -- 128000, 176400, 192000 (untested)

 * access-mode -- MMAP (memory mapped), Not interleaved (PCM_NON-INTERLEAVED)

 * buffer-sizes -- 64,128,256,512,1024,2048,8192 Samples

 * fragments -- 2

 * Hardware-pointer -- 2 Modi


 		 The Card supports the readout of the actual Buffer-pointer,
 		 where DMA reads/writes. Since of the bulk mode of PCI it is only
 		 64 Byte accurate. SO it is not really usable for the
 		 ALSA-mid-level functions (here the buffer-ID gives a better
 		 result), but if MMAP is used by the application. Therefore it
 		 can be configured at load-time with the parameter
 		 precise-pointer.


 .. hint::
 		 (Hint: Experimenting I found that the pointer is maximum 64 to
 		 large never to small. So if you subtract 64 you always have a
 		 safe pointer for writing, which is used on this mode inside
 		 ALSA. In theory now you can get now a latency as low as 16
 		 Samples, which is a quarter of the interrupt possibilities.)

    * Precise Pointer -- off
 					interrupt used for pointer-calculation

    * Precise Pointer -- on
 					hardware pointer used.

 Controller
 ----------

 Since DSP-MADI-Mixer has 8152 Fader, it does not make sense to
 use the standard mixer-controls, since this would break most of
 (especially graphic) ALSA-Mixer GUIs. So Mixer control has be
 provided by a 2-dimensional controller using the
 hwdep-interface.

 Also all 128+256 Peak and RMS-Meter can be accessed via the
 hwdep-interface. Since it could be a performance problem always
 copying and converting Peak and RMS-Levels even if you just need
 one, I decided to export the hardware structure, so that of
 needed some driver-guru can implement a memory-mapping of mixer
 or peak-meters over ioctl, or also to do only copying and no
 conversion. A test-application shows the usage of the controller.

 * Latency Controls --- not implemented !!!

 .. note::
 	   Note: Within the windows-driver the latency is accessible of a
 	   control-panel, but buffer-sizes are controlled with ALSA from
 	   hwparams-calls and should not be changed in run-state, I did not
 	   implement it here.


 * System Clock -- suspended !!!!

   * Name -- "System Clock Mode"

   * Access -- Read Write

   * Values -- "Master" "Slave"

 .. note::
 		  !!!! This is a hardware-function but is in conflict with the
 		  Clock-source controller, which is a kind of ALSA-standard. I
 		  makes sense to set the card to a special mode (master at some
 		  frequency or slave), since even not using an Audio-application
 		  a studio should have working synchronisations setup. So use
 		  Clock-source-controller instead !!!!

 * Clock Source

   * Name -- "Sample Clock Source"

   * Access -- Read Write

   * Values -- "AutoSync", "Internal 32.0 kHz", "Internal 44.1 kHz",
     "Internal 48.0 kHz", "Internal 64.0 kHz", "Internal 88.2 kHz",
     "Internal 96.0 kHz"

 		 Choose between Master at a specific Frequency and so also the
 		 Speed-mode or Slave (Autosync). Also see  "Preferred Sync Ref"

 .. warning::
        !!!! This is no pure hardware function but was implemented by
        ALSA by some ALSA-drivers before, so I use it also. !!!


 * Preferred Sync Ref

   * Name -- "Preferred Sync Reference"

   * Access -- Read Write

   * Values -- "Word" "MADI"


 		 Within the Auto-sync-Mode the preferred Sync Source can be
 		 chosen. If it is not available another is used if possible.

 .. note::
 		 Note: Since MADI has a much higher bit-rate than word-clock, the
 		 card should synchronise better in MADI Mode. But since the
 		 RME-PLL is very good, there are almost no problems with
 		 word-clock too. I never found a difference.


 * TX 64 channel

   * Name -- "TX 64 channels mode"

   * Access -- Read Write

   * Values -- 0 1

 		 Using 64-channel-modus (1) or 56-channel-modus for
 		 MADI-transmission (0).


 .. note::
 		 Note: This control is for output only. Input-mode is detected
 		 automatically from hardware sending MADI.


 * Clear TMS

   * Name -- "Clear Track Marker"

   * Access -- Read Write

   * Values -- 0 1


 		 Don't use to lower 5 Audio-bits on AES as additional Bits.


 * Safe Mode oder Auto Input

   * Name -- "Safe Mode"

   * Access -- Read Write

   * Values -- 0 1 (default on)

 		 If on (1), then if either the optical or coaxial connection
 		 has a failure, there is a takeover to the working one, with no
 		 sample failure. Its only useful if you use the second as a
 		 backup connection.

 * Input

   * Name -- "Input Select"

   * Access -- Read Write

   * Values -- optical coaxial


 		 Choosing the Input, optical or coaxial. If Safe-mode is active,
 		 this is the preferred Input.

 Mixer
 -----

 * Mixer

   * Name -- "Mixer"

   * Access -- Read Write

   * Values - <channel-number 0-127> <Value 0-65535>


 		 Here as a first value the channel-index is taken to get/set the
 		 corresponding mixer channel, where 0-63 are the input to output
 		 fader and 64-127 the playback to outputs fader. Value 0
 		 is channel muted 0 and 32768 an amplification of  1.

 * Chn 1-64

        fast mixer for the ALSA-mixer utils. The diagonal of the
        mixer-matrix is implemented from playback to output.


 * Line Out

   * Name  -- "Line Out"

   * Access -- Read Write

   * Values -- 0 1

 		 Switching on and off the analog out, which has nothing to do
 		 with mixing or routing. the analog outs reflects channel 63,64.


 Information (only read access)
 ------------------------------

 * Sample Rate

   * Name -- "System Sample Rate"

   * Access -- Read-only

 		 getting the sample rate.


 * External Rate measured

   * Name -- "External Rate"

   * Access -- Read only


 		 Should be "Autosync Rate", but Name used is
 		 ALSA-Scheme. External Sample frequency liked used on Autosync is
 		 reported.


 * MADI Sync Status

   * Name -- "MADI Sync Lock Status"

   * Access -- Read

   * Values -- 0,1,2

        MADI-Input is 0=Unlocked, 1=Locked, or 2=Synced.


 * Word Clock Sync Status

   * Name -- "Word Clock Lock Status"

   * Access -- Read

   * Values -- 0,1,2

        Word Clock Input is 0=Unlocked, 1=Locked, or 2=Synced.

 * AutoSync

   * Name -- "AutoSync Reference"

   * Access -- Read

   * Values -- "WordClock", "MADI", "None"

 		 Sync-Reference is either "WordClock", "MADI" or none.

 * RX 64ch --- noch nicht implementiert

        MADI-Receiver is in 64 channel mode oder 56 channel mode.


 * AB_inp   --- not tested

 		 Used input for Auto-Input.


 * actual Buffer Position --- not implemented

 	   !!! this is a ALSA internal function, so no control is used !!!


 Calling Parameter
 =================

 * index int array (min = 1, max = 8)

      Index value for RME HDSPM interface. card-index within ALSA

      note: ALSA-standard

 * id string array (min = 1, max = 8)

      ID string for RME HDSPM interface.

      note: ALSA-standard

 * enable int array (min = 1, max = 8)

      Enable/disable specific HDSPM sound-cards.

      note: ALSA-standard

 * precise_ptr int array (min = 1, max = 8)

      Enable precise pointer, or disable.

 .. note::
      note: Use only when the application supports this (which is a special case).

 * line_outs_monitor int array (min = 1, max = 8)

      Send playback streams to analog outs by default.

 .. note::
 	  note: each playback channel is mixed to the same numbered output
 	  channel (routed). This is against the ALSA-convention, where all
 	  channels have to be muted on after loading the driver, but was
 	  used before on other cards, so i historically use it again)


 * enable_monitor int array (min = 1, max = 8)

      Enable Analog Out on Channel 63/64 by default.

 .. note ::
       note: here the analog output is enabled (but not routed).
	=======================================
	Software Interface ALSA-DSP MADI Driver
	=======================================

	(translated from German, so no good English ;-),

	2004 - winfried ritsch


	Full functionality has been added to the driver. Since some of
	the Controls and startup-options are ALSA-Standard and only the
	special Controls are described and discussed below.


	Hardware functionality
	======================

	Audio transmission
	------------------

	* number of channels -- depends on transmission mode

	The number of channels chosen is from 1..Nmax. The reason to
	use for a lower number of channels is only resource allocation,
	since unused DMA channels are disabled and less memory is
	allocated. So also the throughput of the PCI system can be
	scaled. (Only important for low performance boards).

	* Single Speed -- 1..64 channels

	.. note::
	(Note: Choosing the 56channel mode for transmission or as
	receiver, only 56 are transmitted/received over the MADI, but
	all 64 channels are available for the mixer, so channel count
	for the driver)

	* Double Speed -- 1..32 channels

	.. note::
	Note: Choosing the 56-channel mode for
	transmission/receive-mode , only 28 are transmitted/received
	over the MADI, but all 32 channels are available for the mixer,
	so channel count for the driver


	* Quad Speed -- 1..16 channels

	.. note::
	Choosing the 56-channel mode for
	transmission/receive-mode , only 14 are transmitted/received
	over the MADI, but all 16 channels are available for the mixer,
	so channel count for the driver

	* Format -- signed 32 Bit Little Endian (SNDRV_PCM_FMTBIT_S32_LE)

	* Sample Rates --

	Single Speed -- 32000, 44100, 48000

	Double Speed -- 64000, 88200, 96000 (untested)

	Quad Speed -- 128000, 176400, 192000 (untested)

	* access-mode -- MMAP (memory mapped), Not interleaved (PCM_NON-INTERLEAVED)

	* buffer-sizes -- 64,128,256,512,1024,2048,8192 Samples

	* fragments -- 2

	* Hardware-pointer -- 2 Modi


	The Card supports the readout of the actual Buffer-pointer,
	where DMA reads/writes. Since of the bulk mode of PCI it is only
	64 Byte accurate. SO it is not really usable for the
	ALSA-mid-level functions (here the buffer-ID gives a better
	result), but if MMAP is used by the application. Therefore it
	can be configured at load-time with the parameter
	precise-pointer.


	.. hint::
	(Hint: Experimenting I found that the pointer is maximum 64 to
	large never to small. So if you subtract 64 you always have a
	safe pointer for writing, which is used on this mode inside
	ALSA. In theory now you can get now a latency as low as 16
	Samples, which is a quarter of the interrupt possibilities.)

	* Precise Pointer -- off
	interrupt used for pointer-calculation

	* Precise Pointer -- on
	hardware pointer used.

	Controller
	----------

	Since DSP-MADI-Mixer has 8152 Fader, it does not make sense to
	use the standard mixer-controls, since this would break most of
	(especially graphic) ALSA-Mixer GUIs. So Mixer control has be
	provided by a 2-dimensional controller using the
	hwdep-interface.

	Also all 128+256 Peak and RMS-Meter can be accessed via the
	hwdep-interface. Since it could be a performance problem always
	copying and converting Peak and RMS-Levels even if you just need
	one, I decided to export the hardware structure, so that of
	needed some driver-guru can implement a memory-mapping of mixer
	or peak-meters over ioctl, or also to do only copying and no
	conversion. A test-application shows the usage of the controller.

	* Latency Controls --- not implemented !!!

	.. note::
	Note: Within the windows-driver the latency is accessible of a
	control-panel, but buffer-sizes are controlled with ALSA from
	hwparams-calls and should not be changed in run-state, I did not
	implement it here.


	* System Clock -- suspended !!!!

	* Name -- "System Clock Mode"

	* Access -- Read Write

	* Values -- "Master" "Slave"

	.. note::
	!!!! This is a hardware-function but is in conflict with the
	Clock-source controller, which is a kind of ALSA-standard. I
	makes sense to set the card to a special mode (master at some
	frequency or slave), since even not using an Audio-application
	a studio should have working synchronisations setup. So use
	Clock-source-controller instead !!!!

	* Clock Source

	* Name -- "Sample Clock Source"

	* Access -- Read Write

	* Values -- "AutoSync", "Internal 32.0 kHz", "Internal 44.1 kHz",
	"Internal 48.0 kHz", "Internal 64.0 kHz", "Internal 88.2 kHz",
	"Internal 96.0 kHz"

	Choose between Master at a specific Frequency and so also the
	Speed-mode or Slave (Autosync). Also see "Preferred Sync Ref"

	.. warning::
	!!!! This is no pure hardware function but was implemented by
	ALSA by some ALSA-drivers before, so I use it also. !!!


	* Preferred Sync Ref

	* Name -- "Preferred Sync Reference"

	* Access -- Read Write

	* Values -- "Word" "MADI"


	Within the Auto-sync-Mode the preferred Sync Source can be
	chosen. If it is not available another is used if possible.

	.. note::
	Note: Since MADI has a much higher bit-rate than word-clock, the
	card should synchronise better in MADI Mode. But since the
	RME-PLL is very good, there are almost no problems with
	word-clock too. I never found a difference.


	* TX 64 channel

	* Name -- "TX 64 channels mode"

	* Access -- Read Write

	* Values -- 0 1

	Using 64-channel-modus (1) or 56-channel-modus for
	MADI-transmission (0).


	.. note::
	Note: This control is for output only. Input-mode is detected
	automatically from hardware sending MADI.


	* Clear TMS

	* Name -- "Clear Track Marker"

	* Access -- Read Write

	* Values -- 0 1


	Don't use to lower 5 Audio-bits on AES as additional Bits.


	* Safe Mode oder Auto Input

	* Name -- "Safe Mode"

	* Access -- Read Write

	* Values -- 0 1 (default on)

	If on (1), then if either the optical or coaxial connection
	has a failure, there is a takeover to the working one, with no
	sample failure. Its only useful if you use the second as a
	backup connection.

	* Input

	* Name -- "Input Select"

	* Access -- Read Write

	* Values -- optical coaxial


	Choosing the Input, optical or coaxial. If Safe-mode is active,
	this is the preferred Input.

	Mixer
	-----

	* Mixer

	* Name -- "Mixer"

	* Access -- Read Write

	* Values - <channel-number 0-127> <Value 0-65535>


	Here as a first value the channel-index is taken to get/set the
	corresponding mixer channel, where 0-63 are the input to output
	fader and 64-127 the playback to outputs fader. Value 0
	is channel muted 0 and 32768 an amplification of 1.

	* Chn 1-64

	fast mixer for the ALSA-mixer utils. The diagonal of the
	mixer-matrix is implemented from playback to output.


	* Line Out

	* Name -- "Line Out"

	* Access -- Read Write

	* Values -- 0 1

	Switching on and off the analog out, which has nothing to do
	with mixing or routing. the analog outs reflects channel 63,64.


	Information (only read access)
	------------------------------

	* Sample Rate

	* Name -- "System Sample Rate"

	* Access -- Read-only

	getting the sample rate.


	* External Rate measured

	* Name -- "External Rate"

	* Access -- Read only


	Should be "Autosync Rate", but Name used is
	ALSA-Scheme. External Sample frequency liked used on Autosync is
	reported.


	* MADI Sync Status

	* Name -- "MADI Sync Lock Status"

	* Access -- Read

	* Values -- 0,1,2

	MADI-Input is 0=Unlocked, 1=Locked, or 2=Synced.


	* Word Clock Sync Status

	* Name -- "Word Clock Lock Status"

	* Access -- Read

	* Values -- 0,1,2

	Word Clock Input is 0=Unlocked, 1=Locked, or 2=Synced.

	* AutoSync

	* Name -- "AutoSync Reference"

	* Access -- Read

	* Values -- "WordClock", "MADI", "None"

	Sync-Reference is either "WordClock", "MADI" or none.

	* RX 64ch --- noch nicht implementiert

	MADI-Receiver is in 64 channel mode oder 56 channel mode.


	* AB_inp --- not tested

	Used input for Auto-Input.


	* actual Buffer Position --- not implemented

	!!! this is a ALSA internal function, so no control is used !!!



	Calling Parameter
	=================

	* index int array (min = 1, max = 8)

	Index value for RME HDSPM interface. card-index within ALSA

	note: ALSA-standard

	* id string array (min = 1, max = 8)

	ID string for RME HDSPM interface.

	note: ALSA-standard

	* enable int array (min = 1, max = 8)

	Enable/disable specific HDSPM sound-cards.

	note: ALSA-standard

	* precise_ptr int array (min = 1, max = 8)

	Enable precise pointer, or disable.

	.. note::
	note: Use only when the application supports this (which is a special case).

	* line_outs_monitor int array (min = 1, max = 8)

	Send playback streams to analog outs by default.

	.. note::
	note: each playback channel is mixed to the same numbered output
	channel (routed). This is against the ALSA-convention, where all
	channels have to be muted on after loading the driver, but was
	used before on other cards, so i historically use it again)



	* enable_monitor int array (min = 1, max = 8)

	Enable Analog Out on Channel 63/64 by default.

	.. note ::
	note: here the analog output is enabled (but not routed).