Doc/lib/libossaudiodev.tex - platform/external/python/cpython3 - Gitiles

 \section{\module{ossaudiodev} ---
          Access to OSS-compatible audio devices}

 \declaremodule{builtin}{ossaudiodev}
 \platform{Linux, FreeBSD}
 \modulesynopsis{Access to OSS-compatible audio devices.}

 % XXX OSS is standard for Linux and FreeBSD -- what about NetBSD?
 % OpenBSD?  others?
 This module allows you to access the OSS (Open Sound System) audio
 interface.  OSS is available for a wide range of open-source and
 commercial Unices, and is the standard audio interface for Linux (up to
 kernel 2.4) and FreeBSD.

 \begin{seealso}
 \seetitle[http://www.opensound.com/pguide/oss.pdf]
          {Open Sound System Programmer's Guide}
          {the official documentation for the OSS C API}
 \seetext{The module defines a large number of constants supplied by
          the OSS device driver; see \file{<sys/soundcard.h>} on either
          Linux or FreeBSD for a listing .}
 \end{seealso}

 \module{ossaudiodev} defines the following variables and functions:

 \begin{excdesc}{error}
 This exception is raised on certain errors.  The argument is a string
 describing what went wrong.

 (If \module{ossaudiodev} receives an error from a system call such as
 \cfunction{open()}, \cfunction{write()}, or \cfunction{ioctl()}, it
 raises \exception{IOError}.  Errors detected directly by
 \module{ossaudiodev} result in \exception{ossaudiodev.error}.)
 \end{excdesc}

 \begin{funcdesc}{open}{\optional{device, }mode}
 Open an audio device and return an OSS audio device object.  This
 object supports many file-like methods, such as \method{read()},
 \method{write()}, and \method{fileno()} (although there are subtle
 differences between conventional Unix read/write semantics and those of
 OSS audio devices).  It also supports a number of audio-specific
 methods; see below for the complete list of methods.

 Note the unusual calling syntax: the \emph{first} argument is optional,
 and the second is required.  This is a historical artifact for
 compatibility with the older \module{linuxaudiodev} module which
 \module{ossaudiodev} supersedes.  % XXX it might also be motivated
 % by my unfounded-but-still-possibly-true belief that the default
 % audio device varies unpredictably across operating systems.  -GW

 \var{device} is the audio device filename to use.  If it is not
 specified, this module first looks in the environment variable
 \envvar{AUDIODEV} for a device to use.  If not found, it falls back to
 \file{/dev/dsp}.

 \var{mode} is one of \code{'r'} for read-only (record) access,
 \code{'w'} for write-only (playback) access and \code{'rw'} for both.
 Since many soundcards only allow one process to have the recorder or
 player open at a time it is a good idea to open the device only for the
 activity needed.  Further, some soundcards are half-duplex: they can be
 opened for reading or writing, but not both at once.
 \end{funcdesc}

 \begin{funcdesc}{openmixer}{\optional{device}}
 Open a mixer device and return an OSS mixer device object.
 \var{device} is the mixer device filename to use.  If it is
 not specified, this module first looks in the environment variable
 \envvar{MIXERDEV} for a device to use.  If not found, it falls back to
 \file{/dev/mixer}.

 \end{funcdesc}

 \subsection{Audio Device Objects \label{ossaudio-device-objects}}

 Setting up the device

 To set up the device, three functions must be called in the correct
 sequence:
 \begin{enumerate}
 \item \method{setfmt()} to set the output format,
 \item \method{channels()} to set the number of channels, and
 \item \method{speed()} to set the sample rate.
 \end{enumerate}

 The audio device objects are returned by \function{open()} define the
 following methods:

 \begin{methoddesc}[audio device]{close}{}
 This method explicitly closes the device.  It is useful in situations
 where deleting the object does not immediately close it since there are
 other references to it.  A closed device should not be used again.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{fileno}{}
 Returns the file descriptor associated with the device.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{read}{size}
 Reads \var{size} samples from the audio input and returns them as a
 Python string.  The function blocks until enough data is available.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{write}{data}
 Writes Python string \var{data} to the audio device and returns the
 number of bytes written.  If the audio device is opened in blocking
 mode, the entire string is always written.  If the device is opened in
 nonblocking mode, some data may not be written---see
 \method{writeall()}.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{writeall}{data}
 Writes the entire Python string \var{data} to the audio device.  If the
 device is opened in blocking mode, behaves identially to
 \method{write()}; in nonblocking mode, waits until the device becomes
 available before feeding it more data.  Returns \code{None}, since the
 amount of data written is always equal to the amount of data supplied.
 \end{methoddesc}

 Simple IOCTLs:

 \begin{methoddesc}[audio device]{nonblock}{}
 Attempts to put the device into nonblocking mode.  Once in nonblocking
 mode there is no way to return to blocking mode.

 Raises \exception{IOError} if the IOCTL failed.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{getfmts}{}
 Returns a bitmask of the audio output formats supported by the
 soundcard.  On a typical Linux system, these formats are:

 \begin{tableii}{l|l}{constant}{Format}{Description}
 \lineii{AFMT_MU_LAW}
        {a logarithmic encoding.  This is the default format on
         \file{/dev/audio} and is the format used by Sun .au files.}
 \lineii{AFMT_A_LAW}
        {a logarithmic encoding}
 \lineii{AFMT_IMA_ADPCM}
        {a 4:1 compressed format defined by the Interactive Multimedia
         Association.}
 \lineii{AFMT_U8}
        {Unsigned, 8-bit audio.}
 \lineii{AFMT_S16_LE}
        {Unsigned, 16-bit audio, little-endian byte order (as used by
         Intel processors)}
 \lineii{AFMT_S16_BE}
        {Unsigned, 16-bit audio, big-endian byte order (as used by 68k,
         PowerPC, Sparc)}
 \lineii{AFMT_S8}
        {Signed, 8 bit audio.}
 \lineii{AFMT_U16_LE}
        {Signed, 16-bit little-endian audio}
 \lineii{AFMT_U16_BE}
        {Signed, 16-bit big-endian audio}
 \end{tableii}
 Most systems support only a subset of these formats.  Many devices only
 support \constant{AFMT_U8}; the most common format used today is
 \constant{AFMT_S16_LE}.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{setfmt}{format}
 Used to set the current audio format to \var{format}---see
 \method{getfmts()} for a list.  May also be used to return the current
 audio format---do this by passing an ``audio format'' of
 \constant{AFMT_QUERY}. Returns the audio format that the device was set
 to, which may not be the requested format.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{channels}{num_channels}
 Sets the number of output channels to \var{num_channels}.  A value of 1
 indicates monophonic sound, 2 stereophonic.  Some devices may have more
 than 2 channels, and some high-end devices may not support mono.
 Returns the number of channels the device was set to.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{speed}{samplerate}
 Sets the samplerate to \var{samplerate} samples per second and returns
 the rate actually set.  Most sound devices don't support arbitrary
 sample rates.  Common rates are:

 8000---default rate
 11025---speech recording
 22050
 44100---Audio CD-quality (at 16 bits/sample and 2 channels)
 96000---DVD-quality
 \end{methoddesc}

 \begin{methoddesc}[audio device]{sync}
 Waits until the sound device has played every byte in its buffer and
 returns.  This also occurs when the sound device is closed.  The OSS
 documentation recommends simply closing and re-opening the device rather
 than using \method{sync()}.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{reset}
 Immediately stops and playing or recording and returns the device to a
 state where it can accept commands.  The OSS documentation recommends
 closing and re-opening the device after calling \method{reset()}.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{post}
 To be used like a lightweight \method{sync()}, the \method{post()}
 IOCTL informs the audio device that there is a likely to be a pause in
 the audio output---i.e., after playing a spot sound effect, before
 waiting for user input, or before doing disk I/O.
 \end{methoddesc}

 Convenience methods

 \begin{methoddesc}[audio device]{setparameters}{samplerate,num_channels,format,emulate}
 Initialise the sound device in one method.  \var{samplerate},
 \var{channels} and \var{format} should be as specified in the
 \method{speed()}, \method{channels()} and \method{setfmt()}
 methods.  If \var{emulate} is true, attempt to find the closest matching
 format instead, otherwise raise ValueError if the device does not
 support the format.  The default is to raise ValueError on unsupported
 formats.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{bufsize}{}
 Returns the size of the hardware buffer, in samples.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{obufcount}{}
 Returns the number of samples that are in the hardware buffer yet to be
 played.
 \end{methoddesc}

 \begin{methoddesc}[audio device]{obuffree}{}
 Returns the number of samples that could be queued into the hardware
 buffer to be played without blocking.
 \end{methoddesc}

 \subsection{Mixer Device Objects \label{mixer-device-objects}}

 File-like interface

 \begin{methoddesc}[mixer device]{close}{}
 This method closes the open mixer device file.  Any further attempts to
 use the mixer after this file is closed will raise an IOError.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{fileno}{}
 Returns the file handle number of the open mixer device file.
 \end{methoddesc}

 Mixer interface

 \begin{methoddesc}[mixer device]{controls}{}
 This method returns a bitmask specifying the available mixer controls
 (``Control'' being a specific mixable ``channel'', such as
 \constant{SOUND_MIXER_PCM} or \constant{SOUND_MIXER_SYNTH}).  This
 bitmask indicates a subset of all available mixer channels---the
 \constant{SOUND_MIXER_*} constants defined at module level.  To determine if,
 for example, the current mixer object supports a PCM mixer, use the
 following Python code:

 \begin{verbatim}
 mixer=ossaudiodev.openmixer()
 if mixer.channels() & (1 << ossaudiodev.SOUND_MIXER_PCM):
 	# PCM is supported
 	<code>
 \end{verbatim}

 For most purposes, the \constant{SOUND_MIXER_VOLUME} (Master volume) and
 \constant{SOUND_MIXER_PCM} channels should suffice---but code that uses the
 mixer should be flexible when it comes to choosing sound channels.  On
 the Gravis Ultrasound, for example, \constant{SOUND_MIXER_VOLUME} does not
 exist.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{stereocontrols}{}
 Returns a bitmask indicating stereo mixer channels.  If a bit is set,
 the corresponding channel is stereo; if it is unset, the channel is
 either monophonic or not supported by the mixer (use in combination with
 \method{channels()} to determine which).

 See the code example for the \method{channels()} function for an example
 of getting data from a bitmask.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{reccontrols}{}
 Returns a bitmask specifying the mixer controls that may be used to
 record.  See the code example for \method{controls()} for an example of
 reading from a bitmask.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{get}{channel}
 Returns the volume of a given mixer channel.  The returned volume is a
 2-tuple \code{(left_volume,right_volume)}.  Volumes are specified as
 numbers from 0 (silent) to 100 (full volume).  If the channel is
 monophonic, a 2-tuple is still returned, but both channel volumes are
 the same.

 If an unknown channel is specified, \exception{error} is raised.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{set}{channel, (left, right)}
 Sets the volume for a given mixer channel to \code{(left,right)}.
 \code{left} and \code{right} must be ints and between 0 (silent) and 100
 (full volume).  On success, the new volume is returned as a 2-tuple.
 Note that this may not be exactly the same as the volume specified,
 because of the limited resolution of some soundcard's mixers.

 Raises \exception{IOError} if an invalid mixer channel was specified;
 \exception{TypeError} if the argument format was incorrect, and
 \exception{error} if the specified volumes were out-of-range.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{get_recsrc}{}
 This method returns a bitmask indicating which channel or channels are
 currently being used as a recording source.
 \end{methoddesc}

 \begin{methoddesc}[mixer device]{set_recsrc}{bitmask}
 Call this function to specify a recording source.  Returns a bitmask
 indicating the new recording source (or sources) if successful; raises
 \exception{IOError} if an invalid source was specified.  To set the current
 recording source to the microphone input:

 \begin{verbatim}
 mixer.setrecsrc (1 << ossaudiodev.SOUND_MIXER_MIC)
 \end{verbatim}
 \end{methoddesc}
	\section{\module{ossaudiodev} ---
	Access to OSS-compatible audio devices}

	\declaremodule{builtin}{ossaudiodev}
	\platform{Linux, FreeBSD}
	\modulesynopsis{Access to OSS-compatible audio devices.}

	% XXX OSS is standard for Linux and FreeBSD -- what about NetBSD?
	% OpenBSD? others?
	This module allows you to access the OSS (Open Sound System) audio
	interface. OSS is available for a wide range of open-source and
	commercial Unices, and is the standard audio interface for Linux (up to
	kernel 2.4) and FreeBSD.

	\begin{seealso}
	\seetitle[http://www.opensound.com/pguide/oss.pdf]
	{Open Sound System Programmer's Guide}
	{the official documentation for the OSS C API}
	\seetext{The module defines a large number of constants supplied by
	the OSS device driver; see \file{<sys/soundcard.h>} on either
	Linux or FreeBSD for a listing .}
	\end{seealso}

	\module{ossaudiodev} defines the following variables and functions:

	\begin{excdesc}{error}
	This exception is raised on certain errors. The argument is a string
	describing what went wrong.

	(If \module{ossaudiodev} receives an error from a system call such as
	\cfunction{open()}, \cfunction{write()}, or \cfunction{ioctl()}, it
	raises \exception{IOError}. Errors detected directly by
	\module{ossaudiodev} result in \exception{ossaudiodev.error}.)
	\end{excdesc}

	\begin{funcdesc}{open}{\optional{device, }mode}
	Open an audio device and return an OSS audio device object. This
	object supports many file-like methods, such as \method{read()},
	\method{write()}, and \method{fileno()} (although there are subtle
	differences between conventional Unix read/write semantics and those of
	OSS audio devices). It also supports a number of audio-specific
	methods; see below for the complete list of methods.

	Note the unusual calling syntax: the \emph{first} argument is optional,
	and the second is required. This is a historical artifact for
	compatibility with the older \module{linuxaudiodev} module which
	\module{ossaudiodev} supersedes. % XXX it might also be motivated
	% by my unfounded-but-still-possibly-true belief that the default
	% audio device varies unpredictably across operating systems. -GW

	\var{device} is the audio device filename to use. If it is not
	specified, this module first looks in the environment variable
	\envvar{AUDIODEV} for a device to use. If not found, it falls back to
	\file{/dev/dsp}.

	\var{mode} is one of \code{'r'} for read-only (record) access,
	\code{'w'} for write-only (playback) access and \code{'rw'} for both.
	Since many soundcards only allow one process to have the recorder or
	player open at a time it is a good idea to open the device only for the
	activity needed. Further, some soundcards are half-duplex: they can be
	opened for reading or writing, but not both at once.
	\end{funcdesc}

	\begin{funcdesc}{openmixer}{\optional{device}}
	Open a mixer device and return an OSS mixer device object.
	\var{device} is the mixer device filename to use. If it is
	not specified, this module first looks in the environment variable
	\envvar{MIXERDEV} for a device to use. If not found, it falls back to
	\file{/dev/mixer}.

	\end{funcdesc}

	\subsection{Audio Device Objects \label{ossaudio-device-objects}}

	Setting up the device

	To set up the device, three functions must be called in the correct
	sequence:
	\begin{enumerate}
	\item \method{setfmt()} to set the output format,
	\item \method{channels()} to set the number of channels, and
	\item \method{speed()} to set the sample rate.
	\end{enumerate}

	The audio device objects are returned by \function{open()} define the
	following methods:

	\begin{methoddesc}[audio device]{close}{}
	This method explicitly closes the device. It is useful in situations
	where deleting the object does not immediately close it since there are
	other references to it. A closed device should not be used again.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{fileno}{}
	Returns the file descriptor associated with the device.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{read}{size}
	Reads \var{size} samples from the audio input and returns them as a
	Python string. The function blocks until enough data is available.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{write}{data}
	Writes Python string \var{data} to the audio device and returns the
	number of bytes written. If the audio device is opened in blocking
	mode, the entire string is always written. If the device is opened in
	nonblocking mode, some data may not be written---see
	\method{writeall()}.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{writeall}{data}
	Writes the entire Python string \var{data} to the audio device. If the
	device is opened in blocking mode, behaves identially to
	\method{write()}; in nonblocking mode, waits until the device becomes
	available before feeding it more data. Returns \code{None}, since the
	amount of data written is always equal to the amount of data supplied.
	\end{methoddesc}

	Simple IOCTLs:

	\begin{methoddesc}[audio device]{nonblock}{}
	Attempts to put the device into nonblocking mode. Once in nonblocking
	mode there is no way to return to blocking mode.

	Raises \exception{IOError} if the IOCTL failed.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{getfmts}{}
	Returns a bitmask of the audio output formats supported by the
	soundcard. On a typical Linux system, these formats are:

	\begin{tableii}{l\|l}{constant}{Format}{Description}
	\lineii{AFMT_MU_LAW}
	{a logarithmic encoding. This is the default format on
	\file{/dev/audio} and is the format used by Sun .au files.}
	\lineii{AFMT_A_LAW}
	{a logarithmic encoding}
	\lineii{AFMT_IMA_ADPCM}
	{a 4:1 compressed format defined by the Interactive Multimedia
	Association.}
	\lineii{AFMT_U8}
	{Unsigned, 8-bit audio.}
	\lineii{AFMT_S16_LE}
	{Unsigned, 16-bit audio, little-endian byte order (as used by
	Intel processors)}
	\lineii{AFMT_S16_BE}
	{Unsigned, 16-bit audio, big-endian byte order (as used by 68k,
	PowerPC, Sparc)}
	\lineii{AFMT_S8}
	{Signed, 8 bit audio.}
	\lineii{AFMT_U16_LE}
	{Signed, 16-bit little-endian audio}
	\lineii{AFMT_U16_BE}
	{Signed, 16-bit big-endian audio}
	\end{tableii}
	Most systems support only a subset of these formats. Many devices only
	support \constant{AFMT_U8}; the most common format used today is
	\constant{AFMT_S16_LE}.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{setfmt}{format}
	Used to set the current audio format to \var{format}---see
	\method{getfmts()} for a list. May also be used to return the current
	audio format---do this by passing an ``audio format'' of
	\constant{AFMT_QUERY}. Returns the audio format that the device was set
	to, which may not be the requested format.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{channels}{num_channels}
	Sets the number of output channels to \var{num_channels}. A value of 1
	indicates monophonic sound, 2 stereophonic. Some devices may have more
	than 2 channels, and some high-end devices may not support mono.
	Returns the number of channels the device was set to.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{speed}{samplerate}
	Sets the samplerate to \var{samplerate} samples per second and returns
	the rate actually set. Most sound devices don't support arbitrary
	sample rates. Common rates are:

	8000---default rate
	11025---speech recording
	22050
	44100---Audio CD-quality (at 16 bits/sample and 2 channels)
	96000---DVD-quality
	\end{methoddesc}

	\begin{methoddesc}[audio device]{sync}
	Waits until the sound device has played every byte in its buffer and
	returns. This also occurs when the sound device is closed. The OSS
	documentation recommends simply closing and re-opening the device rather
	than using \method{sync()}.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{reset}
	Immediately stops and playing or recording and returns the device to a
	state where it can accept commands. The OSS documentation recommends
	closing and re-opening the device after calling \method{reset()}.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{post}
	To be used like a lightweight \method{sync()}, the \method{post()}
	IOCTL informs the audio device that there is a likely to be a pause in
	the audio output---i.e., after playing a spot sound effect, before
	waiting for user input, or before doing disk I/O.
	\end{methoddesc}

	Convenience methods

	\begin{methoddesc}[audio device]{setparameters}{samplerate,num_channels,format,emulate}
	Initialise the sound device in one method. \var{samplerate},
	\var{channels} and \var{format} should be as specified in the
	\method{speed()}, \method{channels()} and \method{setfmt()}
	methods. If \var{emulate} is true, attempt to find the closest matching
	format instead, otherwise raise ValueError if the device does not
	support the format. The default is to raise ValueError on unsupported
	formats.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{bufsize}{}
	Returns the size of the hardware buffer, in samples.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{obufcount}{}
	Returns the number of samples that are in the hardware buffer yet to be
	played.
	\end{methoddesc}

	\begin{methoddesc}[audio device]{obuffree}{}
	Returns the number of samples that could be queued into the hardware
	buffer to be played without blocking.
	\end{methoddesc}

	\subsection{Mixer Device Objects \label{mixer-device-objects}}

	File-like interface

	\begin{methoddesc}[mixer device]{close}{}
	This method closes the open mixer device file. Any further attempts to
	use the mixer after this file is closed will raise an IOError.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{fileno}{}
	Returns the file handle number of the open mixer device file.
	\end{methoddesc}

	Mixer interface

	\begin{methoddesc}[mixer device]{controls}{}
	This method returns a bitmask specifying the available mixer controls
	(``Control'' being a specific mixable ``channel'', such as
	\constant{SOUND_MIXER_PCM} or \constant{SOUND_MIXER_SYNTH}). This
	bitmask indicates a subset of all available mixer channels---the
	\constant{SOUND_MIXER_*} constants defined at module level. To determine if,
	for example, the current mixer object supports a PCM mixer, use the
	following Python code:

	\begin{verbatim}
	mixer=ossaudiodev.openmixer()
	if mixer.channels() & (1 << ossaudiodev.SOUND_MIXER_PCM):
	# PCM is supported
	<code>
	\end{verbatim}

	For most purposes, the \constant{SOUND_MIXER_VOLUME} (Master volume) and
	\constant{SOUND_MIXER_PCM} channels should suffice---but code that uses the
	mixer should be flexible when it comes to choosing sound channels. On
	the Gravis Ultrasound, for example, \constant{SOUND_MIXER_VOLUME} does not
	exist.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{stereocontrols}{}
	Returns a bitmask indicating stereo mixer channels. If a bit is set,
	the corresponding channel is stereo; if it is unset, the channel is
	either monophonic or not supported by the mixer (use in combination with
	\method{channels()} to determine which).

	See the code example for the \method{channels()} function for an example
	of getting data from a bitmask.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{reccontrols}{}
	Returns a bitmask specifying the mixer controls that may be used to
	record. See the code example for \method{controls()} for an example of
	reading from a bitmask.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{get}{channel}
	Returns the volume of a given mixer channel. The returned volume is a
	2-tuple \code{(left_volume,right_volume)}. Volumes are specified as
	numbers from 0 (silent) to 100 (full volume). If the channel is
	monophonic, a 2-tuple is still returned, but both channel volumes are
	the same.

	If an unknown channel is specified, \exception{error} is raised.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{set}{channel, (left, right)}
	Sets the volume for a given mixer channel to \code{(left,right)}.
	\code{left} and \code{right} must be ints and between 0 (silent) and 100
	(full volume). On success, the new volume is returned as a 2-tuple.
	Note that this may not be exactly the same as the volume specified,
	because of the limited resolution of some soundcard's mixers.

	Raises \exception{IOError} if an invalid mixer channel was specified;
	\exception{TypeError} if the argument format was incorrect, and
	\exception{error} if the specified volumes were out-of-range.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{get_recsrc}{}
	This method returns a bitmask indicating which channel or channels are
	currently being used as a recording source.
	\end{methoddesc}

	\begin{methoddesc}[mixer device]{set_recsrc}{bitmask}
	Call this function to specify a recording source. Returns a bitmask
	indicating the new recording source (or sources) if successful; raises
	\exception{IOError} if an invalid source was specified. To set the current
	recording source to the microphone input:

	\begin{verbatim}
	mixer.setrecsrc (1 << ossaudiodev.SOUND_MIXER_MIC)
	\end{verbatim}
	\end{methoddesc}