NAME
audio
, audioctl
— device-independent audio
driver layer
SYNOPSIS
audio* at ...
#include <sys/types.h>
#include <sys/ioctl.h>
#include <sys/audioio.h>
#include <string.h>
DESCRIPTION
The audio
driver provides support for
various audio peripherals. It provides a uniform programming interface layer
above different underlying audio hardware drivers.
In addition to hardware mixer controls like those documented in
azalia(4), the audio
driver exposes the
record.enable control. The superuser can change it
with mixerctl(8). It accepts the following values:
There are two types of device files available for audio operation:
- Audio devices are used for recording or playback of digital samples.
- Control devices are used to manipulate audio device parameters like volume
or recording source. They can also read certain
audio
driver variables while it is in use.
AUDIO DEVICES
When audio devices are opened, they attempt to maintain the previous audio sample format and record/playback mode. In addition, if one is opened read-only (write-only) the device is set to record-only (play-only) mode with recording (playing) unpaused.
If a writing process does not call write(2) frequently enough to provide samples at the pace the hardware consumes them silence is inserted. If a reading process does not call read(2) frequently enough, it will simply miss samples.
The following ioctl(2) commands are supported on the sample devices:
AUDIO_GETDEV
audio_device_t *- This command fetches the current hardware device information into the
audio_device_t * argument.
typedef struct audio_device { char name[MAX_AUDIO_DEV_LEN]; char version[MAX_AUDIO_DEV_LEN]; char config[MAX_AUDIO_DEV_LEN]; } audio_device_t;
AUDIO_SETPAR
struct audio_swpar *AUDIO_GETPAR
struct audio_swpar *- Set or get audio parameters as encoded in the
audio_swpar structure.
struct audio_swpar { unsigned int sig; /* if 1, encoding is signed */ unsigned int le; /* if 1, encoding is little-endian */ unsigned int bits; /* bits per sample */ unsigned int bps; /* bytes per sample */ unsigned int msb; /* if 1, bits are msb-aligned */ unsigned int rate; /* common play & rec sample rate */ unsigned int pchan; /* play channels */ unsigned int rchan; /* rec channels */ unsigned int nblks; /* number of blocks in play buffer */ unsigned int round; /* common frames per block */ };
When setting the device parameters with
AUDIO_SETPAR
, the audio_swpar structure should first be initialized withstruct audio_swpar ap; AUDIO_INITPAR(&ap);
and then only the values to be changed should be set. This ensures that the software will work with future versions of the driver. The driver will attempt to set the given parameters; if the device doesn't support them, it will choose other parameters. Then the software must call
AUDIO_GETPAR
to obtain the parameters in use.The parameters are as follows:
- bits
- Number of bits per sample: must be between 1 and 32.
- bps
- Bytes per sample; if specified, it must be large enough to hold all bits. By default it's set to the smallest power of two large enough to hold bits.
- sig
- If set (i.e. non-zero) then the samples are signed, otherwise they are unsigned.
- le
- If set, then the byte order is little endian; if not it is big endian; it's meaningful only if bps > 1.
- msb
- If set, then the bits are aligned in the packet to the most significant bit (i.e. lower bits are padded), otherwise to the least significant bit (i.e. higher bits are padded). It's meaningful only if bits < bps * 8.
- rchan
- The number of recorded channels; meaningful only if the device is opened for reading.
- pchan
- The number of channels playing; meaningful only if the device is opened for writing.
- rate
- The sampling frequency in Hz.
- nblks
- The number of blocks in the play buffer.
- round
- The audio block size.
AUDIO_START
- Start playback and/or recording immediately. If the device is open for
writing (playback), then the play buffer must be filled with the
write(2) syscall. The buffer size is obtained by multiplying the
nblks, round, and
bps parameters obtained with
AUDIO_GETPAR
. AUDIO_STOP
- Stop playback and recording immediately.
AUDIO_GETPOS
struct audio_pos *- Fetch an atomic snapshot of device timing information in the
audio_pos structure.
struct audio_pos { unsigned int play_pos; /* total bytes played */ unsigned int play_xrun; /* bytes of silence inserted */ unsigned int rec_pos; /* total bytes recorded */ unsigned int rec_xrun; /* bytes dropped */ };
The properties have the following meaning:
- play_pos
- Total number of bytes played by the device since playback started (a.k.a the device wall clock).
- play_xrun
- The number of bytes corresponding to silence played because write(2) wasn't called fast enough.
- rec_pos
- Total number of bytes recorded by the device since recording started (a.k.a the device wall clock).
- rec_xrun
- The number of bytes dropped because read(2) wasn't called fast enough.
AUDIO_GETSTATUS
struct audio_status *- Fetch the current device status from the audio driver in the
audio_status structure. This
ioctl(2) is intended for use with diagnostic tools and is of no use
to audio programs.
struct audio_status { #define AUMODE_PLAY 0x01 #define AUMODE_RECORD 0x02 int mode; /* current mode */ int pause; /* not started yet */ int active; /* playing/recording in progress */ };
The properties have the following meaning:
- mode
- The current mode determined by open(2) flags.
- pause
- If set, indicates that
AUDIO_STOP
was called, and the device is not attempting to start. - active
- If set, indicates that the device is playing and/or recording.
CONTROL DEVICES
Control devices support the following ioctl(2) commands:
AUDIO_GETDEV
audio_device_t *AUDIO_GETPOS
struct audio_pos *AUDIO_GETSTATUS
struct audio_status *AUDIO_GETPAR
struct audio_swpar *AUDIO_SETPAR
struct audio_swpar *- These commands are the same as described above for the audio devices.
While the audio device is open,
AUDIO_SETPAR
may not be used. AUDIO_MIXER_READ
mixer_ctrl_t *AUDIO_MIXER_WRITE
mixer_ctrl_t *- These commands read the current mixer state or set new mixer state for the
specified device dev. type
identifies which type of value is supplied in the
mixer_ctrl_t * argument.
#define AUDIO_MIXER_CLASS 0 #define AUDIO_MIXER_ENUM 1 #define AUDIO_MIXER_SET 2 #define AUDIO_MIXER_VALUE 3 typedef struct mixer_ctrl { int dev; /* input: nth device */ int type; union { int ord; /* enum */ int mask; /* set */ mixer_level_t value; /* value */ } un; } mixer_ctrl_t; #define AUDIO_MIN_GAIN 0 #define AUDIO_MAX_GAIN 255 typedef struct mixer_level { int num_channels; u_char level[8]; /* [num_channels] */ } mixer_level_t; #define AUDIO_MIXER_LEVEL_MONO 0 #define AUDIO_MIXER_LEVEL_LEFT 0 #define AUDIO_MIXER_LEVEL_RIGHT 1
For a mixer value, the value field specifies both the number of channels and the values for each channel. If the channel count does not match the current channel count, the attempt to change the setting may fail (depending on the hardware device driver implementation). For an enumeration value, the ord field should be set to one of the possible values as returned by a prior
AUDIO_MIXER_DEVINFO
command. The typeAUDIO_MIXER_CLASS
is only used for classifying particularmixer
device types and is not used forAUDIO_MIXER_READ
orAUDIO_MIXER_WRITE
. AUDIO_MIXER_DEVINFO
mixer_devinfo_t *- This command is used iteratively to fetch audio
mixer
device information into the input/output mixer_devinfo_t * argument. To query all the supported devices, start with an index field of 0 and continue with successive devices (1, 2, ...) until the command returns an error.typedef struct mixer_devinfo { int index; /* input: nth mixer device */ audio_mixer_name_t label; int type; int mixer_class; int next, prev; #define AUDIO_MIXER_LAST -1 union { struct audio_mixer_enum { int num_mem; struct { audio_mixer_name_t label; int ord; } member[32]; } e; struct audio_mixer_set { int num_mem; struct { audio_mixer_name_t label; int mask; } member[32]; } s; struct audio_mixer_value { audio_mixer_name_t units; int num_channels; int delta; } v; } un; } mixer_devinfo_t;
The label field identifies the name of this particular mixer control. The index field may be used as the dev field in
AUDIO_MIXER_READ
andAUDIO_MIXER_WRITE
commands. The type field identifies the type of this mixer control. Enumeration types are typically used for on/off style controls (e.g., a mute control) or for input/output device selection (e.g., select recording input source from CD, line in, or microphone). Set types are similar to enumeration types but any combination of the mask bits can be used.The mixer_class field identifies what class of control this is. This value is set to the index value used to query the class itself. The (arbitrary) value set by the hardware driver may be determined by examining the mixer_class field of the class itself, a mixer of type
AUDIO_MIXER_CLASS
. For example, a mixer level controlling the input gain on the “line in” circuit would have a mixer_class that matches an input class device with the name “inputs” (AudioCinputs
) and would have a label of “line” (AudioNline
). Mixer controls which control audio circuitry for a particular audio source (e.g., line-in, CD in, DAC output) are collected under the input class, while those which control all audio sources (e.g., master volume, equalization controls) are under the output class. Hardware devices capable of recording typically also have a record class, for controls that only affect recording, and also a monitor class.The next and prev may be used by the hardware device driver to provide hints for the next and previous devices in a related set (for example, the line in level control would have the line in mute as its “next” value). If there is no relevant next or previous value,
AUDIO_MIXER_LAST
is specified.For
AUDIO_MIXER_ENUM
mixer control types, the enumeration values and their corresponding names are filled in. For example, a mute control would return appropriate values paired withAudioNon
andAudioNoff
. For theAUDIO_MIXER_VALUE
andAUDIO_MIXER_SET
mixer control types, the channel count is returned; the units name specifies what the level controls (typical values areAudioNvolume
,AudioNtreble
, andAudioNbass
).
A process may read the control device to get notifications about
mixer changes. Whenever a control changes, the
read(2) function fetches an integer identifying the control. It may
be used in the dev field of the
mixer_ctrl structure to call
AUDIO_MIXER_READ
.
In contrast to audio devices, which have the exclusive open property, control devices can be opened at any time in write-only mode. Only one reader is allowed at a time.
FILES
- /dev/audioN
- Audio device.
- /dev/audioctlN
- Control device.
SEE ALSO
aucat(1), cdio(1), sndioctl(1), ioctl(2), sio_open(3), sioctl_open(3), ac97(4), uaudio(4), sndio(7), audioctl(8), mixerctl(8), sndiod(8), audio(9)