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livetrax/libs/rubberband/rubberband/RubberBandStretcher.h
Carl Hetherington d36e6b95c0 GCC 4.6 fixes from oget (#3771).
git-svn-id: svn://localhost/ardour2/branches/3.0@8835 d708f5d6-7413-0410-9779-e7cbd77b26cf
2011-02-13 18:47:13 +00:00

564 lines
23 KiB
C++

/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
/*
Rubber Band
An audio time-stretching and pitch-shifting library.
Copyright 2007-2008 Chris Cannam.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version. See the file
COPYING included with this distribution for more information.
*/
#ifndef _RUBBERBANDSTRETCHER_H_
#define _RUBBERBANDSTRETCHER_H_
#define RUBBERBAND_VERSION "1.3.0-gpl"
#define RUBBERBAND_API_MAJOR_VERSION 2
#define RUBBERBAND_API_MINOR_VERSION 0
#include <cstddef>
#include <vector>
/**
* @mainpage RubberBand
*
* The Rubber Band API is contained in the single class
* RubberBand::RubberBandStretcher.
*
* Threading notes for real-time applications:
*
* Multiple instances of RubberBandStretcher may be created and used
* in separate threads concurrently. However, for any single instance
* of RubberBandStretcher, you may not call process() more than once
* concurrently, and you may not change the time or pitch ratio while
* a process() call is being executed (if the stretcher was created in
* "real-time mode"; in "offline mode" you can't change the ratios
* during use anyway).
*
* So you can run process() in its own thread if you like, but if you
* want to change ratios dynamically from a different thread, you will
* need some form of mutex in your code. Changing the time or pitch
* ratio is real-time safe except in extreme circumstances, so for
* most applications that may change these dynamically it probably
* makes most sense to do so from the same thread as calls process(),
* even if that is a real-time thread.
*/
namespace RubberBand
{
class RubberBandStretcher
{
public:
/**
* Processing options for the timestretcher. The preferred
* options should normally be set in the constructor, as a bitwise
* OR of the option flags. The default value (DefaultOptions) is
* intended to give good results in most situations.
*
* 1. Flags prefixed \c OptionProcess determine how the timestretcher
* will be invoked. These options may not be changed after
* construction.
*
* \li \c OptionProcessOffline - Run the stretcher in offline
* mode. In this mode the input data needs to be provided
* twice, once to study(), which calculates a stretch profile
* for the audio, and once to process(), which stretches it.
*
* \li \c OptionProcessRealTime - Run the stretcher in real-time
* mode. In this mode only process() should be called, and the
* stretcher adjusts dynamically in response to the input audio.
*
* The Process setting is likely to depend on your architecture:
* non-real-time operation on seekable files: Offline; real-time
* or streaming operation: RealTime.
*
* 2. Flags prefixed \c OptionStretch control the profile used for
* variable timestretching. Rubber Band always adjusts the
* stretch profile to minimise stretching of busy broadband
* transient sounds, but the degree to which it does so is
* adjustable. These options may not be changed after
* construction.
*
* \li \c OptionStretchElastic - Only meaningful in offline
* mode, and the default in that mode. The audio will be
* stretched at a variable rate, aimed at preserving the quality
* of transient sounds as much as possible. The timings of low
* activity regions between transients may be less exact than
* when the precise flag is set.
*
* \li \c OptionStretchPrecise - Although still using a variable
* stretch rate, the audio will be stretched so as to maintain
* as close as possible to a linear stretch ratio throughout.
* Timing may be better than when using \c OptionStretchElastic, at
* slight cost to the sound quality of transients. This setting
* is always used when running in real-time mode.
*
* 3. Flags prefixed \c OptionTransients control the component
* frequency phase-reset mechanism that may be used at transient
* points to provide clarity and realism to percussion and other
* significant transient sounds. These options may be changed
* after construction when running in real-time mode, but not when
* running in offline mode.
*
* \li \c OptionTransientsCrisp - Reset component phases at the
* peak of each transient (the start of a significant note or
* percussive event). This, the default setting, usually
* results in a clear-sounding output; but it is not always
* consistent, and may cause interruptions in stable sounds
* present at the same time as transient events.
*
* \li \c OptionTransientsMixed - Reset component phases at the
* peak of each transient, outside a frequency range typical of
* musical fundamental frequencies. The results may be more
* regular for mixed stable and percussive notes than
* \c OptionTransientsCrisp, but with a "phasier" sound. The
* balance may sound very good for certain types of music and
* fairly bad for others.
*
* \li \c OptionTransientsSmooth - Do not reset component phases
* at any point. The results will be smoother and more regular
* but may be less clear than with either of the other
* transients flags.
*
* 4. Flags prefixed \c OptionPhase control the adjustment of
* component frequency phases from one analysis window to the next
* during non-transient segments. These options may be changed at
* any time.
*
* \li \c OptionPhaseLaminar - Adjust phases when stretching in
* such a way as to try to retain the continuity of phase
* relationships between adjacent frequency bins whose phases
* are behaving in similar ways. This, the default setting,
* should give good results in most situations.
*
* \li \c OptionPhaseIndependent - Adjust the phase in each
* frequency bin independently from its neighbours. This
* usually results in a slightly softer, phasier sound.
*
* 5. Flags prefixed \c OptionThreading control the threading
* model of the stretcher. These options may not be changed after
* construction.
*
* \li \c OptionThreadingAuto - Permit the stretcher to
* determine its own threading model. Usually this means using
* one processing thread per audio channel in offline mode if
* the stretcher is able to determine that more than one CPU is
* available, and one thread only in realtime mode.
*
* \li \c OptionThreadingNever - Never use more than one thread.
*
* \li \c OptionThreadingAlways - Use multiple threads in any
* situation where \c OptionThreadingAuto would do so, except omit
* the check for multiple CPUs and instead assume it to be true.
*
* 6. Flags prefixed \c OptionWindow control the window size for
* FFT processing. The window size actually used will depend on
* many factors, but it can be influenced. These options may not
* be changed after construction.
*
* \li \c OptionWindowStandard - Use the default window size.
* The actual size will vary depending on other parameters.
* This option is expected to produce better results than the
* other window options in most situations.
*
* \li \c OptionWindowShort - Use a shorter window. This may
* result in crisper sound for audio that depends strongly on
* its timing qualities.
*
* \li \c OptionWindowLong - Use a longer window. This is
* likely to result in a smoother sound at the expense of
* clarity and timing.
*
* 7. Flags prefixed \c OptionFormant control the handling of
* formant shape (spectral envelope) when pitch-shifting. These
* options may be changed at any time.
*
* \li \c OptionFormantShifted - Apply no special formant
* processing. The spectral envelope will be pitch shifted as
* normal.
*
* \li \c OptionFormantPreserved - Preserve the spectral
* envelope of the unshifted signal. This permits shifting the
* note frequency without so substantially affecting the
* perceived pitch profile of the voice or instrument.
*
* 8. Flags prefixed \c OptionPitch control the method used for
* pitch shifting. These options may be changed at any time.
* They are only effective in realtime mode; in offline mode, the
* pitch-shift method is fixed.
*
* \li \c OptionPitchHighSpeed - Use a method with a CPU cost
* that is relatively moderate and predictable. This may
* sound less clear than OptionPitchHighQuality, especially
* for large pitch shifts.
* \li \c OptionPitchHighQuality - Use the highest quality
* method for pitch shifting. This method has a CPU cost
* approximately proportional to the required frequency shift.
* \li \c OptionPitchHighConsistency - Use the method that gives
* greatest consistency when used to create small variations in
* pitch around the 1.0-ratio level. Unlike the previous two
* options, this avoids discontinuities when moving across the
* 1.0 pitch scale in real-time; it also consumes more CPU than
* the others in the case where the pitch scale is exactly 1.0.
*/
enum Option {
OptionProcessOffline = 0x00000000,
OptionProcessRealTime = 0x00000001,
OptionStretchElastic = 0x00000000,
OptionStretchPrecise = 0x00000010,
OptionTransientsCrisp = 0x00000000,
OptionTransientsMixed = 0x00000100,
OptionTransientsSmooth = 0x00000200,
OptionPhaseLaminar = 0x00000000,
OptionPhaseIndependent = 0x00002000,
OptionThreadingAuto = 0x00000000,
OptionThreadingNever = 0x00010000,
OptionThreadingAlways = 0x00020000,
OptionWindowStandard = 0x00000000,
OptionWindowShort = 0x00100000,
OptionWindowLong = 0x00200000,
OptionFormantShifted = 0x00000000,
OptionFormantPreserved = 0x01000000,
OptionPitchHighSpeed = 0x00000000,
OptionPitchHighQuality = 0x02000000,
OptionPitchHighConsistency = 0x04000000
};
typedef int Options;
enum PresetOption {
DefaultOptions = 0x00000000,
PercussiveOptions = 0x00102000
};
/**
* Construct a time and pitch stretcher object to run at the given
* sample rate, with the given number of channels. Processing
* options and the time and pitch scaling ratios may be provided.
* The time and pitch ratios may be changed after construction,
* but most of the options may not. See the option documentation
* above for more details.
*/
RubberBandStretcher(size_t sampleRate,
size_t channels,
Options options = DefaultOptions,
double initialTimeRatio = 1.0,
double initialPitchScale = 1.0);
~RubberBandStretcher();
/**
* Reset the stretcher's internal buffers. The stretcher should
* subsequently behave as if it had just been constructed
* (although retaining the current time and pitch ratio).
*/
void reset();
/**
* Set the time ratio for the stretcher. This is the ratio of
* stretched to unstretched duration -- not tempo. For example, a
* ratio of 2.0 would make the audio twice as long (i.e. halve the
* tempo); 0.5 would make it half as long (i.e. double the tempo);
* 1.0 would leave the duration unaffected.
*
* If the stretcher was constructed in Offline mode, the time
* ratio is fixed throughout operation; this function may be
* called any number of times between construction (or a call to
* reset()) and the first call to study() or process(), but may
* not be called after study() or process() has been called.
*
* If the stretcher was constructed in RealTime mode, the time
* ratio may be varied during operation; this function may be
* called at any time, so long as it is not called concurrently
* with process(). You should either call this function from the
* same thread as process(), or provide your own mutex or similar
* mechanism to ensure that setTimeRatio and process() cannot be
* run at once (there is no internal mutex for this purpose).
*/
void setTimeRatio(double ratio);
/**
* Set the pitch scaling ratio for the stretcher. This is the
* ratio of target frequency to source frequency. For example, a
* ratio of 2.0 would shift up by one octave; 0.5 down by one
* octave; or 1.0 leave the pitch unaffected.
*
* To put this in musical terms, a pitch scaling ratio
* corresponding to a shift of S equal-tempered semitones (where S
* is positive for an upwards shift and negative for downwards) is
* pow(2.0, S / 12.0).
*
* If the stretcher was constructed in Offline mode, the pitch
* scaling ratio is fixed throughout operation; this function may
* be called any number of times between construction (or a call
* to reset()) and the first call to study() or process(), but may
* not be called after study() or process() has been called.
*
* If the stretcher was constructed in RealTime mode, the pitch
* scaling ratio may be varied during operation; this function may
* be called at any time, so long as it is not called concurrently
* with process(). You should either call this function from the
* same thread as process(), or provide your own mutex or similar
* mechanism to ensure that setPitchScale and process() cannot be
* run at once (there is no internal mutex for this purpose).
*/
void setPitchScale(double scale);
/**
* Return the last time ratio value that was set (either on
* construction or with setTimeRatio()).
*/
double getTimeRatio() const;
/**
* Return the last pitch scaling ratio value that was set (either
* on construction or with setPitchScale()).
*/
double getPitchScale() const;
/**
* Return the processing latency of the stretcher. This is the
* number of audio samples that one would have to discard at the
* start of the output in order to ensure that the resulting audio
* aligned with the input audio at the start. In Offline mode,
* latency is automatically adjusted for and the result is zero.
* In RealTime mode, the latency may depend on the time and pitch
* ratio and other options.
*/
size_t getLatency() const;
/**
* Change an OptionTransients configuration setting. This may be
* called at any time in RealTime mode. It may not be called in
* Offline mode (for which the transients option is fixed on
* construction).
*/
void setTransientsOption(Options options);
/**
* Change an OptionPhase configuration setting. This may be
* called at any time in any mode.
*
* Note that if running multi-threaded in Offline mode, the change
* may not take effect immediately if processing is already under
* way when this function is called.
*/
void setPhaseOption(Options options);
/**
* Change an OptionFormant configuration setting. This may be
* called at any time in any mode.
*
* Note that if running multi-threaded in Offline mode, the change
* may not take effect immediately if processing is already under
* way when this function is called.
*/
void setFormantOption(Options options);
/**
* Change an OptionPitch configuration setting. This may be
* called at any time in RealTime mode. It may not be called in
* Offline mode (for which the transients option is fixed on
* construction).
*/
void setPitchOption(Options options);
/**
* Tell the stretcher exactly how many input samples it will
* receive. This is only useful in Offline mode, when it allows
* the stretcher to ensure that the number of output samples is
* exactly correct. In RealTime mode no such guarantee is
* possible and this value is ignored.
*/
void setExpectedInputDuration(size_t samples);
/**
* Ask the stretcher how many audio sample frames should be
* provided as input in order to ensure that some more output
* becomes available. Normal usage consists of querying this
* function, providing that number of samples to process(),
* reading the output using available() and retrieve(), and then
* repeating.
*
* Note that this value is only relevant to process(), not to
* study() (to which you may pass any number of samples at a time,
* and from which there is no output).
*/
size_t getSamplesRequired() const;
/**
* Tell the stretcher the maximum number of sample frames that you
* will ever be passing in to a single process() call. If you
* don't call this function, the stretcher will assume that you
* never pass in more samples than getSamplesRequired() suggested
* you should. You should not pass in more samples than that
* unless you have called setMaxProcessSize first.
*
* This function may not be called after the first call to study()
* or process().
*
* Note that this value is only relevant to process(), not to
* study() (to which you may pass any number of samples at a time,
* and from which there is no output).
*/
void setMaxProcessSize(size_t samples);
/**
* Provide a block of "samples" sample frames for the stretcher to
* study and calculate a stretch profile from.
*
* This is only meaningful in Offline mode, and is required if
* running in that mode. You should pass the entire input through
* study() before any process() calls are made, as a sequence of
* blocks in individual study() calls, or as a single large block.
*
* "input" should point to de-interleaved audio data with one
* float array per channel. "samples" supplies the number of
* audio sample frames available in "input". If "samples" is
* zero, "input" may be NULL.
*
* Set "final" to true if this is the last block of data that will
* be provided to study() before the first process() call.
*/
void study(const float *const *input, size_t samples, bool final);
/**
* Provide a block of "samples" sample frames for processing.
* See also getSamplesRequired() and setMaxProcessSize().
*
* Set "final" to true if this is the last block of input data.
*/
void process(const float *const *input, size_t samples, bool final);
/**
* Ask the stretcher how many audio sample frames of output data
* are available for reading (via retrieve()).
*
* This function returns 0 if no frames are available: this
* usually means more input data needs to be provided, but if the
* stretcher is running in threaded mode it may just mean that not
* enough data has yet been processed. Call getSamplesRequired()
* to discover whether more input is needed.
*
* This function returns -1 if all data has been fully processed
* and all output read, and the stretch process is now finished.
*/
int available() const;
/**
* Obtain some processed output data from the stretcher. Up to
* "samples" samples will be stored in the output arrays (one per
* channel for de-interleaved audio data) pointed to by "output".
* The return value is the actual number of sample frames
* retrieved.
*/
size_t retrieve(float *const *output, size_t samples) const;
/**
* Return the value of internal frequency cutoff value n.
*
* This function is not for general use.
*/
float getFrequencyCutoff(int n) const;
/**
* Set the value of internal frequency cutoff n to f Hz.
*
* This function is not for general use.
*/
void setFrequencyCutoff(int n, float f);
/**
* Retrieve the value of the internal input block increment value.
*
* This function is provided for diagnostic purposes only.
*/
size_t getInputIncrement() const;
/**
* In offline mode, retrieve the sequence of internal block
* increments for output, for the entire audio data, provided the
* stretch profile has been calculated. In realtime mode,
* retrieve any output increments that have accumulated since the
* last call to getOutputIncrements, to a limit of 16.
*
* This function is provided for diagnostic purposes only.
*/
std::vector<int> getOutputIncrements() const;
/**
* In offline mode, retrieve the sequence of internal phase reset
* detection function values, for the entire audio data, provided
* the stretch profile has been calculated. In realtime mode,
* retrieve any phase reset points that have accumulated since the
* last call to getPhaseResetCurve, to a limit of 16.
*
* This function is provided for diagnostic purposes only.
*/
std::vector<float> getPhaseResetCurve() const;
/**
* In offline mode, retrieve the sequence of internal frames for
* which exact timing has been sought, for the entire audio data,
* provided the stretch profile has been calculated. In realtime
* mode, return an empty sequence.
*
* This function is provided for diagnostic purposes only.
*/
std::vector<int> getExactTimePoints() const;
/**
* Return the number of channels this stretcher was constructed
* with.
*/
size_t getChannelCount() const;
/**
* Force the stretcher to calculate a stretch profile. Normally
* this happens automatically for the first process() call in
* offline mode.
*
* This function is provided for diagnostic purposes only.
*/
void calculateStretch();
/**
* Set the level of debug output. The value may be from 0 (errors
* only) to 3 (very verbose, with audible ticks in the output at
* phase reset points). The default is whatever has been set
* using setDefaultDebugLevel, or 0 if that function has not been
* called.
*/
void setDebugLevel(int level);
/**
* Set the default level of debug output for subsequently
* constructed stretchers.
*
* @see setDebugLevel
*/
static void setDefaultDebugLevel(int level);
protected:
class Impl;
Impl *m_d;
};
}
#endif