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

 \section{\module{audioop} ---
          Manipulate raw audio data}

 \declaremodule{builtin}{audioop}
 \modulesynopsis{Manipulate raw audio data.}


 The \module{audioop} module contains some useful operations on sound
 fragments.  It operates on sound fragments consisting of signed
 integer samples 8, 16 or 32 bits wide, stored in Python strings.  This
 is the same format as used by the \refmodule{al} and \refmodule{sunaudiodev}
 modules.  All scalar items are integers, unless specified otherwise.

 % This para is mostly here to provide an excuse for the index entries...
 This module provides support for u-LAW and Intel/DVI ADPCM encodings.
 \index{Intel/DVI ADPCM}
 \index{ADPCM, Intel/DVI}
 \index{u-LAW}

 A few of the more complicated operations only take 16-bit samples,
 otherwise the sample size (in bytes) is always a parameter of the
 operation.

 The module defines the following variables and functions:

 \begin{excdesc}{error}
 This exception is raised on all errors, such as unknown number of bytes
 per sample, etc.
 \end{excdesc}

 \begin{funcdesc}{add}{fragment1, fragment2, width}
 Return a fragment which is the addition of the two samples passed as
 parameters.  \var{width} is the sample width in bytes, either
 \code{1}, \code{2} or \code{4}.  Both fragments should have the same
 length.
 \end{funcdesc}

 \begin{funcdesc}{adpcm2lin}{adpcmfragment, width, state}
 Decode an Intel/DVI ADPCM coded fragment to a linear fragment.  See
 the description of \function{lin2adpcm()} for details on ADPCM coding.
 Return a tuple \code{(\var{sample}, \var{newstate})} where the sample
 has the width specified in \var{width}.
 \end{funcdesc}

 \begin{funcdesc}{adpcm32lin}{adpcmfragment, width, state}
 Decode an alternative 3-bit ADPCM code.  See \function{lin2adpcm3()}
 for details.
 \end{funcdesc}

 \begin{funcdesc}{avg}{fragment, width}
 Return the average over all samples in the fragment.
 \end{funcdesc}

 \begin{funcdesc}{avgpp}{fragment, width}
 Return the average peak-peak value over all samples in the fragment.
 No filtering is done, so the usefulness of this routine is
 questionable.
 \end{funcdesc}

 \begin{funcdesc}{bias}{fragment, width, bias}
 Return a fragment that is the original fragment with a bias added to
 each sample.
 \end{funcdesc}

 \begin{funcdesc}{cross}{fragment, width}
 Return the number of zero crossings in the fragment passed as an
 argument.
 \end{funcdesc}

 \begin{funcdesc}{findfactor}{fragment, reference}
 Return a factor \var{F} such that
 \code{rms(add(\var{fragment}, mul(\var{reference}, -\var{F})))} is
 minimal, i.e., return the factor with which you should multiply
 \var{reference} to make it match as well as possible to
 \var{fragment}.  The fragments should both contain 2-byte samples.

 The time taken by this routine is proportional to
 \code{len(\var{fragment})}.
 \end{funcdesc}

 \begin{funcdesc}{findfit}{fragment, reference}
 Try to match \var{reference} as well as possible to a portion of
 \var{fragment} (which should be the longer fragment).  This is
 (conceptually) done by taking slices out of \var{fragment}, using
 \function{findfactor()} to compute the best match, and minimizing the
 result.  The fragments should both contain 2-byte samples.  Return a
 tuple \code{(\var{offset}, \var{factor})} where \var{offset} is the
 (integer) offset into \var{fragment} where the optimal match started
 and \var{factor} is the (floating-point) factor as per
 \function{findfactor()}.
 \end{funcdesc}

 \begin{funcdesc}{findmax}{fragment, length}
 Search \var{fragment} for a slice of length \var{length} samples (not
 bytes!)\ with maximum energy, i.e., return \var{i} for which
 \code{rms(fragment[i*2:(i+length)*2])} is maximal.  The fragments
 should both contain 2-byte samples.

 The routine takes time proportional to \code{len(\var{fragment})}.
 \end{funcdesc}

 \begin{funcdesc}{getsample}{fragment, width, index}
 Return the value of sample \var{index} from the fragment.
 \end{funcdesc}

 \begin{funcdesc}{lin2lin}{fragment, width, newwidth}
 Convert samples between 1-, 2- and 4-byte formats.
 \end{funcdesc}

 \begin{funcdesc}{lin2adpcm}{fragment, width, state}
 Convert samples to 4 bit Intel/DVI ADPCM encoding.  ADPCM coding is an
 adaptive coding scheme, whereby each 4 bit number is the difference
 between one sample and the next, divided by a (varying) step.  The
 Intel/DVI ADPCM algorithm has been selected for use by the IMA, so it
 may well become a standard.

 \var{state} is a tuple containing the state of the coder.  The coder
 returns a tuple \code{(\var{adpcmfrag}, \var{newstate})}, and the
 \var{newstate} should be passed to the next call of
 \function{lin2adpcm()}.  In the initial call, \code{None} can be
 passed as the state.  \var{adpcmfrag} is the ADPCM coded fragment
 packed 2 4-bit values per byte.
 \end{funcdesc}

 \begin{funcdesc}{lin2adpcm3}{fragment, width, state}
 This is an alternative ADPCM coder that uses only 3 bits per sample.
 It is not compatible with the Intel/DVI ADPCM coder and its output is
 not packed (due to laziness on the side of the author).  Its use is
 discouraged.
 \end{funcdesc}

 \begin{funcdesc}{lin2ulaw}{fragment, width}
 Convert samples in the audio fragment to u-LAW encoding and return
 this as a Python string.  u-LAW is an audio encoding format whereby
 you get a dynamic range of about 14 bits using only 8 bit samples.  It
 is used by the Sun audio hardware, among others.
 \end{funcdesc}

 \begin{funcdesc}{minmax}{fragment, width}
 Return a tuple consisting of the minimum and maximum values of all
 samples in the sound fragment.
 \end{funcdesc}

 \begin{funcdesc}{max}{fragment, width}
 Return the maximum of the \emph{absolute value} of all samples in a
 fragment.
 \end{funcdesc}

 \begin{funcdesc}{maxpp}{fragment, width}
 Return the maximum peak-peak value in the sound fragment.
 \end{funcdesc}

 \begin{funcdesc}{mul}{fragment, width, factor}
 Return a fragment that has all samples in the original fragment
 multiplied by the floating-point value \var{factor}.  Overflow is
 silently ignored.
 \end{funcdesc}

 \begin{funcdesc}{ratecv}{fragment, width, nchannels, inrate, outrate,
                          state\optional{, weightA\optional{, weightB}}}
 Convert the frame rate of the input fragment.

 \var{state} is a tuple containing the state of the converter.  The
 converter returns a tuple \code{(\var{newfragment}, \var{newstate})},
 and \var{newstate} should be passed to the next call of
 \function{ratecv()}.  The initial call should pass \code{None}
 as the state.

 The \var{weightA} and \var{weightB} arguments are parameters for a
 simple digital filter and default to \code{1} and \code{0} respectively.
 \end{funcdesc}

 \begin{funcdesc}{reverse}{fragment, width}
 Reverse the samples in a fragment and returns the modified fragment.
 \end{funcdesc}

 \begin{funcdesc}{rms}{fragment, width}
 Return the root-mean-square of the fragment, i.e.
 \begin{displaymath}
 \catcode`_=8
 \sqrt{\frac{\sum{{S_{i}}^{2}}}{n}}
 \end{displaymath}
 This is a measure of the power in an audio signal.
 \end{funcdesc}

 \begin{funcdesc}{tomono}{fragment, width, lfactor, rfactor}
 Convert a stereo fragment to a mono fragment.  The left channel is
 multiplied by \var{lfactor} and the right channel by \var{rfactor}
 before adding the two channels to give a mono signal.
 \end{funcdesc}

 \begin{funcdesc}{tostereo}{fragment, width, lfactor, rfactor}
 Generate a stereo fragment from a mono fragment.  Each pair of samples
 in the stereo fragment are computed from the mono sample, whereby left
 channel samples are multiplied by \var{lfactor} and right channel
 samples by \var{rfactor}.
 \end{funcdesc}

 \begin{funcdesc}{ulaw2lin}{fragment, width}
 Convert sound fragments in u-LAW encoding to linearly encoded sound
 fragments.  u-LAW encoding always uses 8 bits samples, so \var{width}
 refers only to the sample width of the output fragment here.
 \end{funcdesc}

 Note that operations such as \function{mul()} or \function{max()} make
 no distinction between mono and stereo fragments, i.e.\ all samples
 are treated equal.  If this is a problem the stereo fragment should be
 split into two mono fragments first and recombined later.  Here is an
 example of how to do that:

 \begin{verbatim}
 def mul_stereo(sample, width, lfactor, rfactor):
     lsample = audioop.tomono(sample, width, 1, 0)
     rsample = audioop.tomono(sample, width, 0, 1)
     lsample = audioop.mul(sample, width, lfactor)
     rsample = audioop.mul(sample, width, rfactor)
     lsample = audioop.tostereo(lsample, width, 1, 0)
     rsample = audioop.tostereo(rsample, width, 0, 1)
     return audioop.add(lsample, rsample, width)
 \end{verbatim}

 If you use the ADPCM coder to build network packets and you want your
 protocol to be stateless (i.e.\ to be able to tolerate packet loss)
 you should not only transmit the data but also the state.  Note that
 you should send the \var{initial} state (the one you passed to
 \function{lin2adpcm()}) along to the decoder, not the final state (as
 returned by the coder).  If you want to use \function{struct.struct()}
 to store the state in binary you can code the first element (the
 predicted value) in 16 bits and the second (the delta index) in 8.

 The ADPCM coders have never been tried against other ADPCM coders,
 only against themselves.  It could well be that I misinterpreted the
 standards in which case they will not be interoperable with the
 respective standards.

 The \function{find*()} routines might look a bit funny at first sight.
 They are primarily meant to do echo cancellation.  A reasonably
 fast way to do this is to pick the most energetic piece of the output
 sample, locate that in the input sample and subtract the whole output
 sample from the input sample:

 \begin{verbatim}
 def echocancel(outputdata, inputdata):
     pos = audioop.findmax(outputdata, 800)    # one tenth second
     out_test = outputdata[pos*2:]
     in_test = inputdata[pos*2:]
     ipos, factor = audioop.findfit(in_test, out_test)
     # Optional (for better cancellation):
     # factor = audioop.findfactor(in_test[ipos*2:ipos*2+len(out_test)],
     #              out_test)
     prefill = '\0'*(pos+ipos)*2
     postfill = '\0'*(len(inputdata)-len(prefill)-len(outputdata))
     outputdata = prefill + audioop.mul(outputdata,2,-factor) + postfill
     return audioop.add(inputdata, outputdata, 2)
 \end{verbatim}
	\section{\module{audioop} ---
	Manipulate raw audio data}

	\declaremodule{builtin}{audioop}
	\modulesynopsis{Manipulate raw audio data.}


	The \module{audioop} module contains some useful operations on sound
	fragments. It operates on sound fragments consisting of signed
	integer samples 8, 16 or 32 bits wide, stored in Python strings. This
	is the same format as used by the \refmodule{al} and \refmodule{sunaudiodev}
	modules. All scalar items are integers, unless specified otherwise.

	% This para is mostly here to provide an excuse for the index entries...
	This module provides support for u-LAW and Intel/DVI ADPCM encodings.
	\index{Intel/DVI ADPCM}
	\index{ADPCM, Intel/DVI}
	\index{u-LAW}

	A few of the more complicated operations only take 16-bit samples,
	otherwise the sample size (in bytes) is always a parameter of the
	operation.

	The module defines the following variables and functions:

	\begin{excdesc}{error}
	This exception is raised on all errors, such as unknown number of bytes
	per sample, etc.
	\end{excdesc}

	\begin{funcdesc}{add}{fragment1, fragment2, width}
	Return a fragment which is the addition of the two samples passed as
	parameters. \var{width} is the sample width in bytes, either
	\code{1}, \code{2} or \code{4}. Both fragments should have the same
	length.
	\end{funcdesc}

	\begin{funcdesc}{adpcm2lin}{adpcmfragment, width, state}
	Decode an Intel/DVI ADPCM coded fragment to a linear fragment. See
	the description of \function{lin2adpcm()} for details on ADPCM coding.
	Return a tuple \code{(\var{sample}, \var{newstate})} where the sample
	has the width specified in \var{width}.
	\end{funcdesc}

	\begin{funcdesc}{adpcm32lin}{adpcmfragment, width, state}
	Decode an alternative 3-bit ADPCM code. See \function{lin2adpcm3()}
	for details.
	\end{funcdesc}

	\begin{funcdesc}{avg}{fragment, width}
	Return the average over all samples in the fragment.
	\end{funcdesc}

	\begin{funcdesc}{avgpp}{fragment, width}
	Return the average peak-peak value over all samples in the fragment.
	No filtering is done, so the usefulness of this routine is
	questionable.
	\end{funcdesc}

	\begin{funcdesc}{bias}{fragment, width, bias}
	Return a fragment that is the original fragment with a bias added to
	each sample.
	\end{funcdesc}

	\begin{funcdesc}{cross}{fragment, width}
	Return the number of zero crossings in the fragment passed as an
	argument.
	\end{funcdesc}

	\begin{funcdesc}{findfactor}{fragment, reference}
	Return a factor \var{F} such that
	\code{rms(add(\var{fragment}, mul(\var{reference}, -\var{F})))} is
	minimal, i.e., return the factor with which you should multiply
	\var{reference} to make it match as well as possible to
	\var{fragment}. The fragments should both contain 2-byte samples.

	The time taken by this routine is proportional to
	\code{len(\var{fragment})}.
	\end{funcdesc}

	\begin{funcdesc}{findfit}{fragment, reference}
	Try to match \var{reference} as well as possible to a portion of
	\var{fragment} (which should be the longer fragment). This is
	(conceptually) done by taking slices out of \var{fragment}, using
	\function{findfactor()} to compute the best match, and minimizing the
	result. The fragments should both contain 2-byte samples. Return a
	tuple \code{(\var{offset}, \var{factor})} where \var{offset} is the
	(integer) offset into \var{fragment} where the optimal match started
	and \var{factor} is the (floating-point) factor as per
	\function{findfactor()}.
	\end{funcdesc}

	\begin{funcdesc}{findmax}{fragment, length}
	Search \var{fragment} for a slice of length \var{length} samples (not
	bytes!)\ with maximum energy, i.e., return \var{i} for which
	\code{rms(fragment[i2:(i+length)2])} is maximal. The fragments
	should both contain 2-byte samples.

	The routine takes time proportional to \code{len(\var{fragment})}.
	\end{funcdesc}

	\begin{funcdesc}{getsample}{fragment, width, index}
	Return the value of sample \var{index} from the fragment.
	\end{funcdesc}

	\begin{funcdesc}{lin2lin}{fragment, width, newwidth}
	Convert samples between 1-, 2- and 4-byte formats.
	\end{funcdesc}

	\begin{funcdesc}{lin2adpcm}{fragment, width, state}
	Convert samples to 4 bit Intel/DVI ADPCM encoding. ADPCM coding is an
	adaptive coding scheme, whereby each 4 bit number is the difference
	between one sample and the next, divided by a (varying) step. The
	Intel/DVI ADPCM algorithm has been selected for use by the IMA, so it
	may well become a standard.

	\var{state} is a tuple containing the state of the coder. The coder
	returns a tuple \code{(\var{adpcmfrag}, \var{newstate})}, and the
	\var{newstate} should be passed to the next call of
	\function{lin2adpcm()}. In the initial call, \code{None} can be
	passed as the state. \var{adpcmfrag} is the ADPCM coded fragment
	packed 2 4-bit values per byte.
	\end{funcdesc}

	\begin{funcdesc}{lin2adpcm3}{fragment, width, state}
	This is an alternative ADPCM coder that uses only 3 bits per sample.
	It is not compatible with the Intel/DVI ADPCM coder and its output is
	not packed (due to laziness on the side of the author). Its use is
	discouraged.
	\end{funcdesc}

	\begin{funcdesc}{lin2ulaw}{fragment, width}
	Convert samples in the audio fragment to u-LAW encoding and return
	this as a Python string. u-LAW is an audio encoding format whereby
	you get a dynamic range of about 14 bits using only 8 bit samples. It
	is used by the Sun audio hardware, among others.
	\end{funcdesc}

	\begin{funcdesc}{minmax}{fragment, width}
	Return a tuple consisting of the minimum and maximum values of all
	samples in the sound fragment.
	\end{funcdesc}

	\begin{funcdesc}{max}{fragment, width}
	Return the maximum of the \emph{absolute value} of all samples in a
	fragment.
	\end{funcdesc}

	\begin{funcdesc}{maxpp}{fragment, width}
	Return the maximum peak-peak value in the sound fragment.
	\end{funcdesc}

	\begin{funcdesc}{mul}{fragment, width, factor}
	Return a fragment that has all samples in the original fragment
	multiplied by the floating-point value \var{factor}. Overflow is
	silently ignored.
	\end{funcdesc}

	\begin{funcdesc}{ratecv}{fragment, width, nchannels, inrate, outrate,
	state\optional{, weightA\optional{, weightB}}}
	Convert the frame rate of the input fragment.

	\var{state} is a tuple containing the state of the converter. The
	converter returns a tuple \code{(\var{newfragment}, \var{newstate})},
	and \var{newstate} should be passed to the next call of
	\function{ratecv()}. The initial call should pass \code{None}
	as the state.

	The \var{weightA} and \var{weightB} arguments are parameters for a
	simple digital filter and default to \code{1} and \code{0} respectively.
	\end{funcdesc}

	\begin{funcdesc}{reverse}{fragment, width}
	Reverse the samples in a fragment and returns the modified fragment.
	\end{funcdesc}

	\begin{funcdesc}{rms}{fragment, width}
	Return the root-mean-square of the fragment, i.e.
	\begin{displaymath}
	\catcode`_=8
	\sqrt{\frac{\sum{{S_{i}}^{2}}}{n}}
	\end{displaymath}
	This is a measure of the power in an audio signal.
	\end{funcdesc}

	\begin{funcdesc}{tomono}{fragment, width, lfactor, rfactor}
	Convert a stereo fragment to a mono fragment. The left channel is
	multiplied by \var{lfactor} and the right channel by \var{rfactor}
	before adding the two channels to give a mono signal.
	\end{funcdesc}

	\begin{funcdesc}{tostereo}{fragment, width, lfactor, rfactor}
	Generate a stereo fragment from a mono fragment. Each pair of samples
	in the stereo fragment are computed from the mono sample, whereby left
	channel samples are multiplied by \var{lfactor} and right channel
	samples by \var{rfactor}.
	\end{funcdesc}

	\begin{funcdesc}{ulaw2lin}{fragment, width}
	Convert sound fragments in u-LAW encoding to linearly encoded sound
	fragments. u-LAW encoding always uses 8 bits samples, so \var{width}
	refers only to the sample width of the output fragment here.
	\end{funcdesc}

	Note that operations such as \function{mul()} or \function{max()} make
	no distinction between mono and stereo fragments, i.e.\ all samples
	are treated equal. If this is a problem the stereo fragment should be
	split into two mono fragments first and recombined later. Here is an
	example of how to do that:

	\begin{verbatim}
	def mul_stereo(sample, width, lfactor, rfactor):
	lsample = audioop.tomono(sample, width, 1, 0)
	rsample = audioop.tomono(sample, width, 0, 1)
	lsample = audioop.mul(sample, width, lfactor)
	rsample = audioop.mul(sample, width, rfactor)
	lsample = audioop.tostereo(lsample, width, 1, 0)
	rsample = audioop.tostereo(rsample, width, 0, 1)
	return audioop.add(lsample, rsample, width)
	\end{verbatim}

	If you use the ADPCM coder to build network packets and you want your
	protocol to be stateless (i.e.\ to be able to tolerate packet loss)
	you should not only transmit the data but also the state. Note that
	you should send the \var{initial} state (the one you passed to
	\function{lin2adpcm()}) along to the decoder, not the final state (as
	returned by the coder). If you want to use \function{struct.struct()}
	to store the state in binary you can code the first element (the
	predicted value) in 16 bits and the second (the delta index) in 8.

	The ADPCM coders have never been tried against other ADPCM coders,
	only against themselves. It could well be that I misinterpreted the
	standards in which case they will not be interoperable with the
	respective standards.

	The \function{find*()} routines might look a bit funny at first sight.
	They are primarily meant to do echo cancellation. A reasonably
	fast way to do this is to pick the most energetic piece of the output
	sample, locate that in the input sample and subtract the whole output
	sample from the input sample:

	\begin{verbatim}
	def echocancel(outputdata, inputdata):
	pos = audioop.findmax(outputdata, 800) # one tenth second
	out_test = outputdata[pos*2:]
	in_test = inputdata[pos*2:]
	ipos, factor = audioop.findfit(in_test, out_test)
	# Optional (for better cancellation):
	# factor = audioop.findfactor(in_test[ipos2:ipos2+len(out_test)],
	# out_test)
	prefill = '\0'(pos+ipos)2
	postfill = '\0'*(len(inputdata)-len(prefill)-len(outputdata))
	outputdata = prefill + audioop.mul(outputdata,2,-factor) + postfill
	return audioop.add(inputdata, outputdata, 2)
	\end{verbatim}