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SOUND(4)		    Kernel Interfaces Manual		      SOUND(4)

NAME
       sound, pcm, snd -- FreeBSD PCM audio device infrastructure

SYNOPSIS
       To  compile  this  driver  into the kernel, place the following line in
       your kernel configuration file:

	     device sound

DESCRIPTION
       The sound driver	is the main component of the FreeBSD sound system.  It
       works in	conjunction with a bridge device driver	on  supported  devices
       and  provides  PCM  audio  record  and playback once it attaches.  Each
       bridge device driver supports a specific	 set  of  audio	 chipsets  and
       needs  to  be  enabled together with the	sound driver.  PCI and ISA PnP
       audio devices identify themselves so users are usually not required  to
       add anything to /boot/device.hints.

       Some  of	the main features of the sound driver are: multichannel	audio,
       per-application volume control, dynamic mixing  through	virtual	 sound
       channels,  true	full duplex operation, bit perfect audio, rate conver-
       sion and	low latency modes.

       The sound driver	is enabled by default, along with several  bridge  de-
       vice  drivers.	Those not enabled by default can be loaded during run-
       time with kldload(8) or during boot via loader.conf(5).	The  following
       bridge device drivers are available:

          snd_ai2s(4) (enabled	by default on powerpc)
          snd_als4000(4)
          snd_atiixp(4)
          snd_cmi(4) (enabled by default on amd64, i386)
          snd_cs4281(4)
          snd_csa(4) (enabled by default on amd64, i386)
          snd_davbus(4) (enabled by default on	powerpc)
          snd_emu10k1(4)
          snd_emu10kx(4) (enabled by default on amd64,	i386)
          snd_envy24(4)
          snd_envy24ht(4)
          snd_es137x(4) (enabled by default on	amd64, i386)
          snd_fm801(4)
          snd_hda(4) (enabled by default on amd64, i386)
          snd_hdspe(4)
          snd_ich(4) (enabled by default on amd64, i386)
          snd_maestro3(4)
          snd_neomagic(4)
          snd_solo(4)
          snd_spicds(4)
          snd_uaudio(4) (auto-loaded on device	plug)
          snd_via8233(4) (enabled by default on amd64,	i386)
          snd_via82c686(4)
          snd_vibes(4)

       Refer  to the manual page for each bridge device	driver for driver spe-
       cific settings and information.

   Boot	Variables
       In general, the module snd_foo corresponds to device snd_foo and	can be
       loaded by the boot loader(8) via	loader.conf(5)	or  from  the  command
       line  using  the	kldload(8) utility.  Options which can be specified in
       /boot/loader.conf include:

	     snd_driver_load  ("NO") If	set to "YES", this  option  loads  all
			      available	drivers.

	     snd_hda_load     ("NO") If	set to "YES", only the Intel High Def-
			      inition Audio bridge device driver and dependent
			      modules will be loaded.

	     snd_foo_load     ("NO")   If   set	 to  "YES",  load  driver  for
			      card/chipset foo.

       To define default values	for the	 different  mixer  channels,  set  the
       channel	to the preferred value using hints, e.g.: hint.pcm.0.line="0".
       This will mute the input	channel	per default.

   Multichannel	Audio
       Multichannel audio, popularly referred to as "surround sound"  is  sup-
       ported and enabled by default.  The FreeBSD multichannel	matrix proces-
       sor  supports up	to 18 interleaved channels, but	the limit is currently
       set to 8	channels (as commonly used for 7.1 surround sound).   The  in-
       ternal  matrix mapping can handle reduction, expansion or re-routing of
       channels.  This provides	a  base	 interface  for	 related  multichannel
       ioctl()	support.   Multichannel	 audio	works  both  with  and without
       VCHANs.

       Most bridge device drivers are  still  missing  multichannel  matrixing
       support,	 but  in  most cases this should be trivial to implement.  Use
       the dev.pcm.%d.[play|rec].vchanformat sysctl(8) to adjust the number of
       channels	used.  The  current  multichannel  interleaved	structure  and
       arrangement was implemented by inspecting various popular UNIX applica-
       tions.	There  were no single standard,	so much	care has been taken to
       try to satisfy each possible scenario, despite the fact that  each  ap-
       plication has its own conflicting standard.

   EQ
       The  Parametric	Software Equalizer (EQ)	enables	the use	of "tone" con-
       trols (bass and treble).	 Commonly used for ear-candy or	frequency com-
       pensation due to	the vast difference in hardware	quality.  EQ  is  dis-
       abled by	default, but can be enabled with the hint.pcm.%d.eq tunable.

   VCHANs
       Each device can optionally support more playback	and recording channels
       than  physical hardware provides	by using "virtual channels" or VCHANs.
       VCHAN options can be configured via the	sysctl(8)  interface  but  can
       only be manipulated while the device is inactive.

   VPC
       FreeBSD	supports  independent  and individual volume controls for each
       active application, without touching the	master sound volume.  This  is
       sometimes  referred to as Volume	Per Channel (VPC).  The	VPC feature is
       enabled by default.

   Loader Tunables
       The following loader tunables are used to set driver  configuration  at
       the  loader(8)  prompt before booting the kernel, or they can be	stored
       in /boot/loader.conf in order to	automatically set them before  booting
       the  kernel.   It  is also possible to use kenv(1) to change these tun-
       ables before loading the	sound driver.  The following tunables can  not
       be changed during runtime using sysctl(8).

       hint.pcm.%d.eq
	       Set  to	1  or  0  to  explicitly enable	(1) or disable (0) the
	       equalizer.  Requires a driver reload if changed.	 Enabling this
	       will make bass and treble controls  appear  in  mixer  applica-
	       tions.	This  tunable  is undefined by default.	 Equalizing is
	       disabled	by default.

       hint.pcm.%d.vpc
	       Set to 1	or 0 to	explicitly enable (1) or disable (0)  the  VPC
	       feature.	 This tunable is undefined by default.	VPC is however
	       enabled by default.

   Runtime Configuration
       There  are a number of sysctl(8)	variables available which can be modi-
       fied  during  runtime.	These	values	 can   also   be   stored   in
       /etc/sysctl.conf	 in  order  to	automatically set them during the boot
       process.	 hw.snd.* are global settings and dev.pcm.*  are  device  spe-
       cific.

       hw.snd.compat_linux_mmap
	       Linux  mmap(2)  compatibility.	The  following values are sup-
	       ported (default is 0):

	       -1  Force disabling/denying PROT_EXEC mmap(2) requests.

	       0   Auto	detect proc/ABI	type, allow mmap(2) for	Linux applica-
		   tions, and deny for everything else.

	       1   Always allow	PROT_EXEC page mappings.

       hw.snd.default_auto
	       Automatically assign the	default	 sound	unit.	The  following
	       values are supported (default is	1):

	       0   Do not assign the default sound unit	automatically.

	       1   Use	the  best  available sound device based	on playing and
		   recording capabilities of the device.

	       2   Use the most	recently attached device.

       hw.snd.default_unit
	       Default sound card for systems with multiple sound cards.  When
	       using devfs(5), the default device for /dev/dsp.	 Equivalent to
	       a symlink from /dev/dsp to /dev/dsp${hw.snd.default_unit}.

       hw.snd.feeder_eq_exact_rate
	       Only certain rates are allowed for precise processing.  The de-
	       fault behavior is however to allow sloppy  processing  for  all
	       rates,  even  the  unsupported ones.  Enable to toggle this re-
	       quirement and only allow	processing for supported rates.

       hw.snd.feeder_rate_max
	       Maximum allowable sample	rate.

       hw.snd.feeder_rate_min
	       Minimum allowable sample	rate.

       hw.snd.feeder_rate_polyphase_max
	       Adjust to set the maximum number	of allowed  polyphase  entries
	       during  the  process of building	resampling filters.  Disabling
	       polyphase resampling has	the benefit of reducing	memory	usage,
	       at  the	expense	 of slower and lower quality conversion.  Only
	       applicable when the SINC	interpolator is	used.	Default	 value
	       is 183040.  Set to 0 to disable polyphase resampling.

       hw.snd.feeder_rate_quality
	       Sample  rate converter quality.	Default	value is 1, linear in-
	       terpolation.  Available options include:

	       0   Zero	Order Hold, ZOH.  Very fast, but with poor quality.

	       1   Linear interpolation.  Fast,	quality	is subject to personal
		   preference.	Technically the	quality	is poor	 however,  due
		   to the lack of anti-aliasing	filtering.

	       2   Bandlimited	SINC interpolator.  Implements polyphase bank-
		   ing to boost	the conversion speed, at the  cost  of	memory
		   usage,  with	multiple high quality polynomial interpolators
		   to improve the  conversion  accuracy.   100%	 fixed	point,
		   64bit  accumulator  with 32bit coefficients and high	preci-
		   sion	sample buffering.  Quality values are 100dB  stopband,
		   8 taps and 85% bandwidth.

	       3   Continuation	 of  the  bandlimited  SINC interpolator, with
		   100dB stopband, 36 taps and 90% bandwidth as	 quality  val-
		   ues.

	       4   Continuation	 of  the  bandlimited SINC interprolator, with
		   100dB stopband, 164 taps and	97% bandwidth as quality  val-
		   ues.

       hw.snd.feeder_rate_round
	       Sample  rate  rounding threshold, to avoid large	prime division
	       at the cost of accuracy.	 All requested sample  rates  will  be
	       rounded	to the nearest threshold value.	 Possible values range
	       between 0 (disabled) and	500.  Default is 25.

       hw.snd.latency
	       Configure the buffering	latency.   Only	 affects  applications
	       that  do	 not  explicitly  request blocksize / fragments.  This
	       tunable	   provides	finer	  granularity	  than	   the
	       hw.snd.latency_profile  tunable.	 Possible values range between
	       0 (lowest latency) and 10 (highest latency).

       hw.snd.latency_profile
	       Define sets of buffering	 latency  conversion  tables  for  the
	       hw.snd.latency  tunable.	  A  value of 0	will use a low and ag-
	       gressive	latency	profile	which can result in possible underruns
	       if the application cannot keep up with a	rapid irq rate,	 espe-
	       cially  during high workload.  The default value	is 1, which is
	       considered a moderate/safe latency profile.

       hw.snd.maxautovchans
	       Global VCHAN setting that only affects devices  with  at	 least
	       one  playback or	recording channel available.  The sound	system
	       will dynamically	create up to this many VCHANs.	Set to "0"  if
	       no VCHANs are desired.  Maximum value is	256.

       hw.snd.report_soft_formats
	       Controls	 the  internal	format	conversion  if it is available
	       transparently to	the application	software.   When  disabled  or
	       not available, the application will only	be able	to select for-
	       mats the	device natively	supports.

       hw.snd.report_soft_matrix
	       Enable seamless channel matrixing even if the hardware does not
	       support	it.   Makes  it	 possible to play multichannel streams
	       even with a simple stereo sound card.

       hw.snd.verbose
	       Level of	verbosity for the /dev/sndstat device.	Higher	values
	       include more output and the highest level, four,	should be used
	       when reporting problems.	 Other options include:

	       0   Installed devices and their allocated bus resources.

	       1   The number of playback, record, virtual channels, and flags
		   per device.

	       2   Channel information per device including the	channel's cur-
		   rent	 format,  speed,  and pseudo device statistics such as
		   buffer overruns and buffer underruns.

	       3   File	names and versions of the currently loaded sound  mod-
		   ules.

	       4   Various messages intended for debugging.

       hw.snd.vpc_0db
	       Default value for sound volume.	Increase to give more room for
	       attenuation control.  Decrease for more amplification, with the
	       possible	cost of	sound clipping.

       hw.snd.vpc_autoreset
	       When  a	channel	 is closed the channel volume will be reset to
	       0db.  This means	that any changes to the	volume will  be	 lost.
	       Enabling	this will preserve the volume, at the cost of possible
	       confusion when applications tries to re-open the	same device.

       hw.snd.vpc_mixer_bypass
	       The recommended way to use the VPC feature is to	teach applica-
	       tions   to  use	the  correct  ioctl():	SNDCTL_DSP_GETPLAYVOL,
	       SNDCTL_DSP_SETPLAYVOL,			 SNDCTL_DSP_SETRECVOL,
	       SNDCTL_DSP_SETRECVOL.   This  is	 however  not always possible.
	       Enable this to allow applications to  use  their	 own  existing
	       mixer logic to control their own	channel	volume.

       hw.snd.vpc_reset
	       Enable to restore all channel volumes back to the default value
	       of 0db.

       dev.pcm.%d.bitperfect
	       Enable or disable bitperfect mode.  When	enabled, channels will
	       skip  all  dsp processing, such as channel matrixing, rate con-
	       verting and equalizing.	The pure sound stream will be fed  di-
	       rectly  to the hardware.	 If VCHANs are enabled,	the bitperfect
	       mode will use the VCHAN	format/rate  as	 the  definitive  for-
	       mat/rate	target.	 The recommended way to	use bitperfect mode is
	       to disable VCHANs and enable this sysctl.  Default is disabled.

       dev.pcm.%d.[play|rec].vchans
	       The current number of VCHANs allocated per device.  This	can be
	       set  to	preallocate  a certain number of VCHANs.  Setting this
	       value to	"0" will disable VCHANs	for this device.

       dev.pcm.%d.[play|rec].vchanformat
	       Format for VCHAN	mixing.	 All playback paths will be  converted
	       to  this	 format	 before	the mixing process begins.  By default
	       only 2 channels are enabled.  Available options include:

	       s16le:1.0
		   Mono.

	       s16le:2.0
		   Stereo, 2 channels (left, right).

	       s16le:2.1
		   3 channels (left, right, LFE).

	       s16le:3.0
		   3 channels (left, right, rear center).

	       s16le:4.0
		   Quadraphonic, 4 channels (front/rear	left and right).

	       s16le:4.1
		   5 channels (4.0 + LFE).

	       s16le:5.0
		   5 channels (4.0 + center).

	       s16le:5.1
		   6 channels (4.0 + center + LFE).

	       s16le:6.0
		   6 channels (4.0 + front/rear	center).

	       s16le:6.1
		   7 channels (6.0 + LFE).

	       s16le:7.1
		   8 channels (4.0 + center + LFE + left and right side).

       dev.pcm.%d.[play|rec].vchanmode
	       VCHAN format/rate selection.  Available options include:

	       fixed
		   Channel mixing is done using	fixed  format/rate.   Advanced
		   operations  such as digital passthrough will	not work.  Can
		   be considered as a "legacy" mode.  This is the default mode
		   for hardware	channels which lack support for	 digital  for-
		   mats.

	       passthrough
		   Channel  mixing  is	done  using fixed format/rate, but ad-
		   vanced operations such as digital  passthrough  also	 work.
		   All	channels  will	produce	sound as usual until a digital
		   format playback is requested.  When this happens all	 other
		   channels will be muted and the latest incoming digital for-
		   mat	will be	allowed	to pass	through	undisturbed.  Multiple
		   concurrent digital streams are supported,  but  the	latest
		   stream will take precedence and mute	all other streams.

	       adaptive
		   Works  like	the  "passthrough" mode, but is	a bit smarter,
		   especially for multiple sound channels with different  for-
		   mat/rate.  When a new channel is about to start, the	entire
		   list	 of  virtual channels will be scanned, and the channel
		   with	the best  format/rate  (usually	 the  highest/biggest)
		   will	be selected.  This ensures that	mixing quality depends
		   on the best channel.	 The downside is that the hardware DMA
		   mode	 needs	to be restarted, which may cause annoying pops
		   or clicks.

       dev.pcm.%d.[play|rec].vchanrate
	       Sample rate speed for VCHAN mixing.  All	playback paths will be
	       converted to this sample	rate before the	mixing process begins.

       dev.pcm.%d.polling
	       Experimental polling mode support where the driver operates  by
	       querying	the device state on each tick using a callout(9) mech-
	       anism.	Disabled by default and	currently only available for a
	       few device drivers.

   Statistics
       Channel statistics are only kept	while the device  is  open.   So  with
       situations  involving overruns and underruns, consider the output while
       the errant application is open and running.

   IOCTL Support
       The driver supports most	of the OSS ioctl() functions, and most	appli-
       cations	work unmodified.  A few	differences exist, while memory	mapped
       playback	is supported natively and in Linux  emulation,	memory	mapped
       recording  is  not due to VM system design.  As a consequence, some ap-
       plications may need to be recompiled with  a  slightly  modified	 audio
       module.	 See  <sys/soundcard.h>	 for  a	complete list of the supported
       ioctl() functions.

FILES
       The sound drivers may create the	following device nodes:

       /dev/dsp%d    Audio device.  The	number represents the unit  number  of
		     the device.
       /dev/dsp	     Alias  of /dev/dsp${hw.snd.default_unit}.	Available only
		     if	hw.snd.basename_clone is set.
       /dev/sndstat  Current sound status, including all channels and drivers.

       All sound devices are listed in /dev/sndstat.  Additional messages  are
       sometimes  recorded  when the device is probed and attached, these mes-
       sages can be viewed with	the dmesg(8) utility.

EXAMPLES
       Use the sound metadriver	to load	all sound  bridge  device  drivers  at
       once (for example if it is unclear which	the correct driver to use is):

	     kldload snd_driver

       Load a specific bridge device driver, in	this case the Intel High Defi-
       nition Audio driver:

	     kldload snd_hda

       Check the status	of all detected	sound devices:

	     cat /dev/sndstat

       Change  the  default  sound  device, in this case to the	second device.
       This is handy if	there are multiple sound devices available:

	     mixer -d pcm1

DIAGNOSTICS
       pcm%d:play:%d:dsp%d.p%d:	play interrupt	timeout,  channel  dead	   The
       hardware	 does not generate interrupts to serve incoming	(play) or out-
       going (record) data.

       unsupported subdevice XX	 A device node is not created properly.

SEE ALSO
       snd_ai2s(4), snd_als4000(4), snd_atiixp(4), snd_cmi(4),	snd_cs4281(4),
       snd_csa(4),	snd_davbus(4),	   snd_emu10k1(4),     snd_emu10kx(4),
       snd_envy24(4),	 snd_envy24ht(4),     snd_es137x(4),	 snd_fm801(4),
       snd_hda(4), snd_hdspe(4), snd_ich(4), snd_maestro3(4), snd_neomagic(4),
       snd_solo(4),	 snd_spicds(4),	    snd_t4dwave(4),	snd_uaudio(4),
       snd_via8233(4),	   snd_via82c686(4),	  snd_vibes(4),	     devfs(5),
       device.hints(5),	  loader.conf(5),   dmesg(8),	kldload(8),  mixer(8),
       sysctl(8)

       Cookbook	formulae for audio EQ biquad  filter  coefficients  (Audio-EQ-
       Cookbook.txt),		by	     Robert	      Bristow-Johnson,
       https://www.musicdsp.org/en/latest/Filters/197-rbj-audio-eq-
       cookbook.html.

       Julius	     O'Smith's	      Digital	     Audio	   Resampling,
       http://ccrma.stanford.edu/~jos/resample/.

       Polynomial  Interpolators  for  High-Quality  Resampling	of Oversampled
       Audio,	   by	   Olli	     Niemitalo,	     http://yehar.com/blog/wp-
       content/uploads/2009/08/deip.pdf.

       The OSS API, http://www.opensound.com/pguide/oss.pdf.

HISTORY
       The sound device	driver first appeared in FreeBSD 2.2.6 as pcm, written
       by  Luigi  Rizzo.   It  was  later  rewritten in	FreeBSD	4.0 by Cameron
       Grant.  The API evolved from the	VOXWARE	standard  which	 later	became
       OSS standard.

AUTHORS
       Luigi  Rizzo <luigi@iet.unipi.it> initially wrote the pcm device	driver
       and this	manual page.  Cameron Grant <gandalf@vilnya.demon.co.uk> later
       revised	the  device  driver   for   FreeBSD   4.0.    Seigo   Tanimura
       <tanimura@r.dl.itc.u-tokyo.ac.jp>  revised  this	 manual	 page.	It was
       then rewritten for FreeBSD 5.2.

BUGS
       Some features of	your sound card	(e.g., global  volume  control)	 might
       not be supported	on all devices.

FreeBSD	13.2			March 24, 2024			      SOUND(4)
NAME | SYNOPSIS | DESCRIPTION | FILES | EXAMPLES | DIAGNOSTICS | SEE ALSO | HISTORY | AUTHORS | BUGS

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