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Resampler.cpp
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Resampler.cpp
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/* Audio Library for Teensy 3.X
* Copyright (c) 2019, Paul Stoffregen, paul@pjrc.com
*
* Development of this audio library was funded by PJRC.COM, LLC by sales of
* Teensy and Audio Adaptor boards. Please support PJRC's efforts to develop
* open source software by purchasing Teensy or other PJRC products.
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice, development funding notice, and this permission
* notice shall be included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
/*
by Alexander Walch
*/
#include "Resampler.h"
#include <math.h>
Resampler::Resampler(float attenuation, int32_t minHalfFilterLength, int32_t maxHalfFilterLength, StepAdaptionParameters settings): _targetAttenuation(attenuation)
{
_maxHalfFilterLength=max(1, min(MAX_HALF_FILTER_LENGTH, maxHalfFilterLength));
_minHalfFilterLength=max(1, min(maxHalfFilterLength, minHalfFilterLength));
#ifdef DEBUG_RESAMPLER
while (!Serial);
#endif
_settings=settings;
kaiserWindowSamples[0]=1.;
double step=1./(NO_EXACT_KAISER_SAMPLES-1);
double* xSq=kaiserWindowXsq;
for (uint16_t i = 1; i <NO_EXACT_KAISER_SAMPLES; i++){
double x=(double)i*step;
*xSq++=(1.-x*x);
}
}
void Resampler::getKaiserExact(double beta){
const double thres=1e-10;
double* winS=&kaiserWindowSamples[1];
double* t=tempRes;
for (uint16_t i = 1; i <NO_EXACT_KAISER_SAMPLES; i++){
*winS++=1.;
*t++=1.;
}
double denomLastSummand=1.;
const double halfBetaSq=beta*beta/4.;
double denom=1.;
double i=1.;
while(i < 1000){
denomLastSummand*=(halfBetaSq/(i*i));
i+=1.;
denom+=denomLastSummand;
t=tempRes;
winS=&kaiserWindowSamples[1];
double* xSq=kaiserWindowXsq;
for (uint16_t j=0; j< NO_EXACT_KAISER_SAMPLES-1;j++){
(*t)*=(*xSq);
double summand=(denomLastSummand*(*t));
(*winS)+=summand;
if (summand< thres){
break;
}
++winS;
++t;
++xSq;
}
if (denomLastSummand< thres){
break;
}
}
winS=&kaiserWindowSamples[1];
for (int32_t i = 0; i <NO_EXACT_KAISER_SAMPLES-1; i++){
*winS++/=denom;
}
}
void Resampler::setKaiserWindow(double beta, int32_t noSamples){
getKaiserExact(beta);
double step=(double)(NO_EXACT_KAISER_SAMPLES-1)/(double)(noSamples-1);
double xPos=step;
float* filterCoeff=filter;
*filterCoeff=1.;
++filterCoeff;
int32_t lower=(int)(xPos);
double* windowLower=&kaiserWindowSamples[lower];
double* windowUpper=&kaiserWindowSamples[lower+1];
for (int32_t i =0; i< noSamples-2; i++){
double lambda=xPos-lower;
if (lambda > 1.){
lambda-=1.;
++windowLower;
++windowUpper;
lower++;
}
*filterCoeff++=(float)(lambda*(*windowUpper)+(1.-lambda)*(*windowLower));
xPos+=step;
if (xPos>=NO_EXACT_KAISER_SAMPLES-1 || lower >=NO_EXACT_KAISER_SAMPLES-1){
break;
}
}
*filterCoeff=*windowUpper;
}
void Resampler::setFilter(int32_t halfFiltLength,int32_t overSampling, double cutOffFrequ, double kaiserBeta){
const int32_t noSamples=halfFiltLength*overSampling+1;
setKaiserWindow(kaiserBeta, noSamples);
float* filterCoeff=filter;
*filterCoeff++=(float)cutOffFrequ;
double step=halfFiltLength/(noSamples-1.);
double xPos=step;
double factor=M_PI*cutOffFrequ;
for (int32_t i = 0; i<noSamples-1; i++ ){
*filterCoeff++*=(float)((sin(xPos*factor)/(xPos*M_PI)));
xPos+=step;
}
}
double Resampler::getStep() const {
return _stepAdapted;
}
double Resampler::getAttenuation() const {
return _attenuation;
}
int32_t Resampler::getHalfFilterLength() const{
return _halfFilterLength;
}
void Resampler::reset(){
_initialized=false;
}
void Resampler::configure(float fs, float newFs){
// Serial.print("configure, fs: ");
// Serial.println(fs);
if (fs<=0.f || newFs <=0.f){
_attenuation=0.;
_halfFilterLength=0;
_initialized=false;
return;
}
_attenuation=_targetAttenuation;
_step=(double)fs/(double)newFs;
_configuredStep=_step;
_stepAdapted=_step;
_sum=0.;
_oldDiffs[0]=0.;
_oldDiffs[1]=0.;
for (uint8_t i =0; i< MAX_NO_CHANNELS; i++){
memset(_buffer[i], 0, sizeof(float)*_maxHalfFilterLength*2);
}
double kaiserBeta, cutOffFrequ;
_overSamplingFactor=1024;
if (fs <= newFs){
_attenuation=0;
cutOffFrequ=1.;
kaiserBeta=10.;
_halfFilterLength=_minHalfFilterLength;
}
else{
cutOffFrequ=newFs/fs;
double b=(2.*(0.5*(double)newFs-20000.)/(double)fs); //this transition band width causes aliasing. However the generated frequencies are above 20kHz
#ifdef DEBUG_RESAMPLER
Serial.print("b: ");
Serial.println(b);
#endif
int32_t hfl=(int32_t)((_attenuation-8.)/(2.*2.285*TWO_PI*b)+0.5);
if (hfl >= _minHalfFilterLength && hfl <= _maxHalfFilterLength){
_halfFilterLength=hfl;
}
else if (hfl < _minHalfFilterLength){
_halfFilterLength=_minHalfFilterLength;
_attenuation=((2.*(double)_halfFilterLength+1.)-1.)*(2.285*TWO_PI*b)+8.;
}
else{
_halfFilterLength=_maxHalfFilterLength;
_attenuation=((2.*(double)_halfFilterLength+1.)-1.)*(2.285*TWO_PI*b)+8.;
}
if (_attenuation>50.){
kaiserBeta=0.1102*(_attenuation-8.7);
}
else if (21.<=_attenuation && _attenuation<=50.){
kaiserBeta=0.5842*pow(_attenuation-21.,0.4)+0.07886*(_attenuation-21.);
}
else{
kaiserBeta=0.;
}
int32_t noSamples=_halfFilterLength*_overSamplingFactor+1;
if (noSamples > MAX_FILTER_SAMPLES){
int32_t f = (noSamples-1)/(MAX_FILTER_SAMPLES-1)+1;
_overSamplingFactor/=f;
}
}
#ifdef DEBUG_RESAMPLER
Serial.print("fs: ");
Serial.println(fs);
Serial.print("cutOffFrequ: ");
Serial.println(cutOffFrequ);
Serial.print("filter length: ");
Serial.println(2*_halfFilterLength+1);
Serial.print("overSampling: ");
Serial.println(_overSamplingFactor);
Serial.print("kaiserBeta: ");
Serial.println(kaiserBeta, 12);
Serial.print("_step: ");
Serial.println(_step, 12);
#endif
setFilter(_halfFilterLength, _overSamplingFactor, cutOffFrequ, kaiserBeta);
_filterLength=_halfFilterLength*2;
for (uint8_t i =0; i< MAX_NO_CHANNELS; i++){
_endOfBuffer[i]=&_buffer[i][_filterLength];
}
_cPos=-_halfFilterLength; //marks the current center position of the filter
_initialized=true;
}
bool Resampler::initialized() const {
return _initialized;
}
void Resampler::resample(float* input0, float* input1, uint16_t inputLength, uint16_t& processedLength, float* output0, float* output1,uint16_t outputLength, uint16_t& outputCount) {
outputCount=0;
int32_t successorIndex=(int32_t)(ceil(_cPos)); //negative number -> currently the _buffer0 of the last iteration is used
float* ip0, *ip1, *fPtr;
float filterC;
float si0[2];
float si1[2];
while (floor(_cPos + _halfFilterLength) < inputLength && outputCount < outputLength){
float dist=successorIndex-_cPos;
const float distScaled=dist*_overSamplingFactor;
int32_t rightIndex=abs((int32_t)(ceilf(distScaled))-_overSamplingFactor*_halfFilterLength);
const int32_t indexData=successorIndex-_halfFilterLength;
if (indexData>=0){
ip0=input0+indexData;
ip1=input1+indexData;
}
else {
ip0=_buffer[0]+indexData+_filterLength;
ip1=_buffer[1]+indexData+_filterLength;
}
fPtr=filter+rightIndex;
if (rightIndex==_overSamplingFactor*_halfFilterLength){
si1[0]=*ip0++**fPtr;
si1[1]=*ip1++**fPtr;
memset(si0, 0, 2*sizeof(float));
fPtr-=_overSamplingFactor;
rightIndex=(int32_t)(ceilf(distScaled))+_overSamplingFactor; //needed below
}
else {
memset(si0, 0, 2*sizeof(float));
memset(si1, 0, 2*sizeof(float));
rightIndex=(int32_t)(ceilf(distScaled)); //needed below
}
for (uint16_t i =0 ; i<_halfFilterLength; i++){
if(ip0==_endOfBuffer[0]){
ip0=input0;
ip1=input1;
}
si1[0]+=*ip0**fPtr;
si1[1]+=*ip1**fPtr;
filterC=*(fPtr+1);
si0[0]+=*ip0*filterC;
si0[1]+=*ip1*filterC;
fPtr-=_overSamplingFactor;
++ip0;
++ip1;
}
fPtr=filter+rightIndex-1;
for (uint16_t i =0 ; i<_halfFilterLength; i++){
if(ip0==_endOfBuffer[0]){
ip0=input0;
ip1=input1;
}
si0[0]+=*ip0**fPtr;
si0[1]+=*ip1**fPtr;
filterC=*(fPtr+1);
si1[0]+=*ip0*filterC;
si1[1]+=*ip1*filterC;
fPtr+=_overSamplingFactor;
++ip0;
++ip1;
}
const float w0=ceilf(distScaled)-distScaled;
const float w1=1.f-w0;
*output0++=si0[0]*w0 + si1[0]*w1;
*output1++=si0[1]*w0 + si1[1]*w1;
outputCount++;
_cPos+=_stepAdapted;
while (_cPos >successorIndex){
successorIndex++;
}
}
if(outputCount < outputLength){
//ouput vector not full -> we ran out of input samples
processedLength=inputLength;
}
else{
processedLength=min(inputLength, (int16_t)floor(_cPos + _halfFilterLength));
}
//fill _buffer
const int32_t indexData=processedLength-_filterLength;
if (indexData>=0){
ip0=input0+indexData;
ip1=input1+indexData;
const unsigned long long bytesToCopy= _filterLength*sizeof(float);
memcpy((void *)_buffer[0], (void *)ip0, bytesToCopy);
memcpy((void *)_buffer[1], (void *)ip1, bytesToCopy);
}
else {
float* b0=_buffer[0];
float* b1=_buffer[1];
ip0=_buffer[0]+indexData+_filterLength;
ip1=_buffer[1]+indexData+_filterLength;
for (uint16_t i =0; i< _filterLength; i++){
if(ip0==_endOfBuffer[0]){
ip0=input0;
ip1=input1;
}
*b0++ = *ip0++;
*b1++ = *ip1++;
}
}
_cPos-=processedLength;
if (_cPos < -_halfFilterLength){
_cPos=-_halfFilterLength;
}
}
void Resampler::fixStep(){
if (!_initialized){
return;
}
_step=_stepAdapted;
_sum=0.;
_oldDiffs[0]=0.;
_oldDiffs[1]=0.;
}
void Resampler::addToPos(double val){
if(val < 0){
return;
}
_cPos+=val;
}
bool Resampler::addToSampleDiff(double diff){
_oldDiffs[0]=_oldDiffs[1];
_oldDiffs[1]=(1.-_settings.alpha)*_oldDiffs[1]+_settings.alpha*diff;
const double slope=_oldDiffs[1]-_oldDiffs[0];
_sum+=diff;
double correction=_settings.kp*diff+_settings.kd*slope+_settings.ki*_sum;
const double oldStepAdapted=_stepAdapted;
_stepAdapted=_step+correction;
if (abs(_stepAdapted/_configuredStep-1.) > _settings.maxAdaption){
_initialized=false;
return false;
}
bool settled=false;
if ((abs(oldStepAdapted- _stepAdapted)/_stepAdapted < _settledThrs*abs(diff) && abs(diff) > 1.5*1e-6)) {
settled=true;
}
return settled;
}
double Resampler::getXPos() const{
return _cPos+(double)_halfFilterLength;
}