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https://github.com/RetroDECK/Duckstation.git
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539 lines
16 KiB
C++
539 lines
16 KiB
C++
//////////////////////////////////////////////////////////////////////////////
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///
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/// SoundTouch - main class for tempo/pitch/rate adjusting routines.
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///
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/// Notes:
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/// - Initialize the SoundTouch object instance by setting up the sound stream
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/// parameters with functions 'setSampleRate' and 'setChannels', then set
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/// desired tempo/pitch/rate settings with the corresponding functions.
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///
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/// - The SoundTouch class behaves like a first-in-first-out pipeline: The
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/// samples that are to be processed are fed into one of the pipe by calling
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/// function 'putSamples', while the ready processed samples can be read
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/// from the other end of the pipeline with function 'receiveSamples'.
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///
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/// - The SoundTouch processing classes require certain sized 'batches' of
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/// samples in order to process the sound. For this reason the classes buffer
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/// incoming samples until there are enough of samples available for
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/// processing, then they carry out the processing step and consequently
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/// make the processed samples available for outputting.
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///
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/// - For the above reason, the processing routines introduce a certain
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/// 'latency' between the input and output, so that the samples input to
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/// SoundTouch may not be immediately available in the output, and neither
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/// the amount of outputtable samples may not immediately be in direct
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/// relationship with the amount of previously input samples.
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///
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/// - The tempo/pitch/rate control parameters can be altered during processing.
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/// Please notice though that they aren't currently protected by semaphores,
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/// so in multi-thread application external semaphore protection may be
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/// required.
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///
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/// - This class utilizes classes 'TDStretch' for tempo change (without modifying
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/// pitch) and 'RateTransposer' for changing the playback rate (that is, both
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/// tempo and pitch in the same ratio) of the sound. The third available control
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/// 'pitch' (change pitch but maintain tempo) is produced by a combination of
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/// combining the two other controls.
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///
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/// Author : Copyright (c) Olli Parviainen
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/// Author e-mail : oparviai 'at' iki.fi
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/// SoundTouch WWW: http://www.surina.net/soundtouch
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///
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////////////////////////////////////////////////////////////////////////////////
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//
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// License :
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//
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// SoundTouch audio processing library
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// Copyright (c) Olli Parviainen
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//
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// This library is free software; you can redistribute it and/or
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// modify it under the terms of the GNU Lesser General Public
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// License as published by the Free Software Foundation; either
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// version 2.1 of the License, or (at your option) any later version.
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//
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// This library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public
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// License along with this library; if not, write to the Free Software
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// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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//
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////////////////////////////////////////////////////////////////////////////////
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#include <assert.h>
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#include <stdlib.h>
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#include <memory.h>
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#include <math.h>
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#include <stdio.h>
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#include "SoundTouch.h"
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#include "TDStretch.h"
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#include "RateTransposer.h"
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#include "cpu_detect.h"
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using namespace soundtouch;
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/// test if two floating point numbers are equal
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#define TEST_FLOAT_EQUAL(a, b) (fabs(a - b) < 1e-10)
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/// Print library version string for autoconf
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extern "C" void soundtouch_ac_test()
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{
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printf("SoundTouch Version: %s\n",SOUNDTOUCH_VERSION);
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}
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SoundTouch::SoundTouch()
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{
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// Initialize rate transposer and tempo changer instances
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pRateTransposer = new RateTransposer();
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pTDStretch = TDStretch::newInstance();
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setOutPipe(pTDStretch);
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rate = tempo = 0;
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virtualPitch =
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virtualRate =
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virtualTempo = 1.0;
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calcEffectiveRateAndTempo();
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samplesExpectedOut = 0;
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samplesOutput = 0;
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channels = 0;
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bSrateSet = false;
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}
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SoundTouch::~SoundTouch()
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{
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delete pRateTransposer;
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delete pTDStretch;
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}
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/// Get SoundTouch library version string
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const char *SoundTouch::getVersionString()
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{
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static const char *_version = SOUNDTOUCH_VERSION;
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return _version;
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}
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/// Get SoundTouch library version Id
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uint SoundTouch::getVersionId()
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{
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return SOUNDTOUCH_VERSION_ID;
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}
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// Sets the number of channels, 1 = mono, 2 = stereo
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void SoundTouch::setChannels(uint numChannels)
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{
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if (!verifyNumberOfChannels(numChannels)) return;
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channels = numChannels;
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pRateTransposer->setChannels((int)numChannels);
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pTDStretch->setChannels((int)numChannels);
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}
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// Sets new rate control value. Normal rate = 1.0, smaller values
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// represent slower rate, larger faster rates.
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void SoundTouch::setRate(double newRate)
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{
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virtualRate = newRate;
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calcEffectiveRateAndTempo();
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}
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// Sets new rate control value as a difference in percents compared
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// to the original rate (-50 .. +100 %)
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void SoundTouch::setRateChange(double newRate)
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{
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virtualRate = 1.0 + 0.01 * newRate;
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calcEffectiveRateAndTempo();
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}
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// Sets new tempo control value. Normal tempo = 1.0, smaller values
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// represent slower tempo, larger faster tempo.
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void SoundTouch::setTempo(double newTempo)
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{
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virtualTempo = newTempo;
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calcEffectiveRateAndTempo();
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}
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// Sets new tempo control value as a difference in percents compared
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// to the original tempo (-50 .. +100 %)
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void SoundTouch::setTempoChange(double newTempo)
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{
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virtualTempo = 1.0 + 0.01 * newTempo;
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calcEffectiveRateAndTempo();
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}
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// Sets new pitch control value. Original pitch = 1.0, smaller values
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// represent lower pitches, larger values higher pitch.
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void SoundTouch::setPitch(double newPitch)
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{
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virtualPitch = newPitch;
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calcEffectiveRateAndTempo();
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}
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// Sets pitch change in octaves compared to the original pitch
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// (-1.00 .. +1.00)
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void SoundTouch::setPitchOctaves(double newPitch)
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{
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virtualPitch = exp(0.69314718056 * newPitch);
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calcEffectiveRateAndTempo();
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}
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// Sets pitch change in semi-tones compared to the original pitch
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// (-12 .. +12)
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void SoundTouch::setPitchSemiTones(int newPitch)
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{
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setPitchOctaves((double)newPitch / 12.0);
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}
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void SoundTouch::setPitchSemiTones(double newPitch)
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{
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setPitchOctaves(newPitch / 12.0);
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}
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// Calculates 'effective' rate and tempo values from the
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// nominal control values.
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void SoundTouch::calcEffectiveRateAndTempo()
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{
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double oldTempo = tempo;
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double oldRate = rate;
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tempo = virtualTempo / virtualPitch;
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rate = virtualPitch * virtualRate;
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if (!TEST_FLOAT_EQUAL(rate,oldRate)) pRateTransposer->setRate(rate);
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if (!TEST_FLOAT_EQUAL(tempo, oldTempo)) pTDStretch->setTempo(tempo);
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#ifndef SOUNDTOUCH_PREVENT_CLICK_AT_RATE_CROSSOVER
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if (rate <= 1.0f)
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{
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if (output != pTDStretch)
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{
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FIFOSamplePipe *tempoOut;
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assert(output == pRateTransposer);
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// move samples in the current output buffer to the output of pTDStretch
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tempoOut = pTDStretch->getOutput();
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tempoOut->moveSamples(*output);
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// move samples in pitch transposer's store buffer to tempo changer's input
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// deprecated : pTDStretch->moveSamples(*pRateTransposer->getStore());
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output = pTDStretch;
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}
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}
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else
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#endif
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{
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if (output != pRateTransposer)
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{
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FIFOSamplePipe *transOut;
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assert(output == pTDStretch);
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// move samples in the current output buffer to the output of pRateTransposer
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transOut = pRateTransposer->getOutput();
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transOut->moveSamples(*output);
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// move samples in tempo changer's input to pitch transposer's input
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pRateTransposer->moveSamples(*pTDStretch->getInput());
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output = pRateTransposer;
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}
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}
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}
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// Sets sample rate.
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void SoundTouch::setSampleRate(uint srate)
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{
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// set sample rate, leave other tempo changer parameters as they are.
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pTDStretch->setParameters((int)srate);
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bSrateSet = true;
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}
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// Adds 'numSamples' pcs of samples from the 'samples' memory position into
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// the input of the object.
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void SoundTouch::putSamples(const SAMPLETYPE *samples, uint nSamples)
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{
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if (bSrateSet == false)
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{
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ST_THROW_RT_ERROR("SoundTouch : Sample rate not defined");
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}
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else if (channels == 0)
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{
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ST_THROW_RT_ERROR("SoundTouch : Number of channels not defined");
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}
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// accumulate how many samples are expected out from processing, given the current
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// processing setting
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samplesExpectedOut += (double)nSamples / ((double)rate * (double)tempo);
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#ifndef SOUNDTOUCH_PREVENT_CLICK_AT_RATE_CROSSOVER
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if (rate <= 1.0f)
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{
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// transpose the rate down, output the transposed sound to tempo changer buffer
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assert(output == pTDStretch);
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pRateTransposer->putSamples(samples, nSamples);
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pTDStretch->moveSamples(*pRateTransposer);
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}
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else
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#endif
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{
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// evaluate the tempo changer, then transpose the rate up,
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assert(output == pRateTransposer);
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pTDStretch->putSamples(samples, nSamples);
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pRateTransposer->moveSamples(*pTDStretch);
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}
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}
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// Flushes the last samples from the processing pipeline to the output.
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// Clears also the internal processing buffers.
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//
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// Note: This function is meant for extracting the last samples of a sound
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// stream. This function may introduce additional blank samples in the end
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// of the sound stream, and thus it's not recommended to call this function
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// in the middle of a sound stream.
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void SoundTouch::flush()
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{
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int i;
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int numStillExpected;
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SAMPLETYPE *buff = new SAMPLETYPE[128 * channels];
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// how many samples are still expected to output
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numStillExpected = (int)((long)(samplesExpectedOut + 0.5) - samplesOutput);
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if (numStillExpected < 0) numStillExpected = 0;
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memset(buff, 0, 128 * channels * sizeof(SAMPLETYPE));
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// "Push" the last active samples out from the processing pipeline by
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// feeding blank samples into the processing pipeline until new,
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// processed samples appear in the output (not however, more than
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// 24ksamples in any case)
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for (i = 0; (numStillExpected > (int)numSamples()) && (i < 200); i ++)
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{
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putSamples(buff, 128);
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}
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adjustAmountOfSamples(numStillExpected);
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delete[] buff;
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// Clear input buffers
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pTDStretch->clearInput();
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// yet leave the output intouched as that's where the
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// flushed samples are!
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}
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// Changes a setting controlling the processing system behaviour. See the
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// 'SETTING_...' defines for available setting ID's.
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bool SoundTouch::setSetting(int settingId, int value)
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{
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int sampleRate, sequenceMs, seekWindowMs, overlapMs;
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// read current tdstretch routine parameters
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pTDStretch->getParameters(&sampleRate, &sequenceMs, &seekWindowMs, &overlapMs);
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switch (settingId)
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{
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case SETTING_USE_AA_FILTER :
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// enables / disabless anti-alias filter
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pRateTransposer->enableAAFilter((value != 0) ? true : false);
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return true;
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case SETTING_AA_FILTER_LENGTH :
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// sets anti-alias filter length
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pRateTransposer->getAAFilter()->setLength(value);
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return true;
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case SETTING_USE_QUICKSEEK :
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// enables / disables tempo routine quick seeking algorithm
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pTDStretch->enableQuickSeek((value != 0) ? true : false);
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return true;
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case SETTING_SEQUENCE_MS:
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// change time-stretch sequence duration parameter
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pTDStretch->setParameters(sampleRate, value, seekWindowMs, overlapMs);
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return true;
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case SETTING_SEEKWINDOW_MS:
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// change time-stretch seek window length parameter
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pTDStretch->setParameters(sampleRate, sequenceMs, value, overlapMs);
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return true;
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case SETTING_OVERLAP_MS:
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// change time-stretch overlap length parameter
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pTDStretch->setParameters(sampleRate, sequenceMs, seekWindowMs, value);
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return true;
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default :
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return false;
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}
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}
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// Reads a setting controlling the processing system behaviour. See the
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// 'SETTING_...' defines for available setting ID's.
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//
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// Returns the setting value.
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int SoundTouch::getSetting(int settingId) const
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{
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int temp;
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switch (settingId)
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{
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case SETTING_USE_AA_FILTER :
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return (uint)pRateTransposer->isAAFilterEnabled();
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case SETTING_AA_FILTER_LENGTH :
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return pRateTransposer->getAAFilter()->getLength();
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case SETTING_USE_QUICKSEEK :
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return (uint)pTDStretch->isQuickSeekEnabled();
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case SETTING_SEQUENCE_MS:
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pTDStretch->getParameters(NULL, &temp, NULL, NULL);
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return temp;
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case SETTING_SEEKWINDOW_MS:
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pTDStretch->getParameters(NULL, NULL, &temp, NULL);
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return temp;
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case SETTING_OVERLAP_MS:
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pTDStretch->getParameters(NULL, NULL, NULL, &temp);
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return temp;
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case SETTING_NOMINAL_INPUT_SEQUENCE :
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{
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int size = pTDStretch->getInputSampleReq();
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#ifndef SOUNDTOUCH_PREVENT_CLICK_AT_RATE_CROSSOVER
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if (rate <= 1.0)
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{
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// transposing done before timestretch, which impacts latency
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return (int)(size * rate + 0.5);
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}
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#endif
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return size;
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}
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case SETTING_NOMINAL_OUTPUT_SEQUENCE :
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{
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int size = pTDStretch->getOutputBatchSize();
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if (rate > 1.0)
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{
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// transposing done after timestretch, which impacts latency
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return (int)(size / rate + 0.5);
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}
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return size;
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}
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case SETTING_INITIAL_LATENCY:
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{
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double latency = pTDStretch->getLatency();
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int latency_tr = pRateTransposer->getLatency();
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#ifndef SOUNDTOUCH_PREVENT_CLICK_AT_RATE_CROSSOVER
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if (rate <= 1.0)
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{
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// transposing done before timestretch, which impacts latency
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latency = (latency + latency_tr) * rate;
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}
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else
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#endif
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{
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latency += (double)latency_tr / rate;
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}
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return (int)(latency + 0.5);
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}
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default :
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return 0;
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}
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}
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// Clears all the samples in the object's output and internal processing
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// buffers.
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void SoundTouch::clear()
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{
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samplesExpectedOut = 0;
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samplesOutput = 0;
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pRateTransposer->clear();
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pTDStretch->clear();
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}
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/// Returns number of samples currently unprocessed.
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uint SoundTouch::numUnprocessedSamples() const
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{
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FIFOSamplePipe * psp;
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if (pTDStretch)
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{
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psp = pTDStretch->getInput();
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if (psp)
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{
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return psp->numSamples();
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}
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}
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return 0;
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}
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/// Output samples from beginning of the sample buffer. Copies requested samples to
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/// output buffer and removes them from the sample buffer. If there are less than
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/// 'numsample' samples in the buffer, returns all that available.
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///
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/// \return Number of samples returned.
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uint SoundTouch::receiveSamples(SAMPLETYPE *output, uint maxSamples)
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{
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uint ret = FIFOProcessor::receiveSamples(output, maxSamples);
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samplesOutput += (long)ret;
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return ret;
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}
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/// Adjusts book-keeping so that given number of samples are removed from beginning of the
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/// sample buffer without copying them anywhere.
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///
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/// Used to reduce the number of samples in the buffer when accessing the sample buffer directly
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/// with 'ptrBegin' function.
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uint SoundTouch::receiveSamples(uint maxSamples)
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{
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uint ret = FIFOProcessor::receiveSamples(maxSamples);
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samplesOutput += (long)ret;
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return ret;
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}
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/// Get ratio between input and output audio durations, useful for calculating
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/// processed output duration: if you'll process a stream of N samples, then
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/// you can expect to get out N * getInputOutputSampleRatio() samples.
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double SoundTouch::getInputOutputSampleRatio()
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{
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return 1.0 / (tempo * rate);
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}
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