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airwindows/plugins/WinVST/FireAmp/FireAmpProc.cpp
Christopher Johnson f06250c082 Clarifying Licensing in boilerplate code generation
2022-11-21 09:20:21 -05:00

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/* ========================================
* FireAmp - FireAmp.h
* Copyright (c) 2016 airwindows, Airwindows uses the MIT license
* ======================================== */
#ifndef __Gain_H
#include "FireAmp.h"
#endif
void FireAmp::processReplacing(float **inputs, float **outputs, VstInt32 sampleFrames)
{
float* in1 = inputs[0];
float* in2 = inputs[1];
float* out1 = outputs[0];
float* out2 = outputs[1];
double bassfill = A;
double outputlevel = C;
double wet = D;
double overallscale = 1.0;
overallscale /= 44100.0;
overallscale *= getSampleRate();
int cycleEnd = floor(overallscale);
if (cycleEnd < 1) cycleEnd = 1;
if (cycleEnd > 4) cycleEnd = 4;
//this is going to be 2 for 88.1 or 96k, 3 for silly people, 4 for 176 or 192k
if (cycle > cycleEnd-1) cycle = cycleEnd-1; //sanity check
double startlevel = bassfill;
double samplerate = getSampleRate();
double basstrim = bassfill / 16.0;
double toneEQ = (B / samplerate)*22050.0;
double EQ = (basstrim / samplerate)*22050.0;
double bleed = outputlevel/16.0;
double bassfactor = 1.0-(basstrim*basstrim);
double BEQ = (bleed / samplerate)*22050.0;
int diagonal = (int)(0.000861678*samplerate);
if (diagonal > 127) diagonal = 127;
int side = (int)(diagonal/1.4142135623730951);
int down = (side + diagonal)/2;
//now we've got down, side and diagonal as offsets and we also use three successive samples upfront
double cutoff = (15000.0+(B*10000.0)) / getSampleRate();
if (cutoff > 0.49) cutoff = 0.49; //don't crash if run at 44.1k
if (cutoff < 0.001) cutoff = 0.001; //or if cutoff's too low
fixF[fix_freq] = fixE[fix_freq] = fixD[fix_freq] = fixC[fix_freq] = fixB[fix_freq] = fixA[fix_freq] = cutoff;
fixA[fix_reso] = 4.46570214;
fixB[fix_reso] = 1.51387132;
fixC[fix_reso] = 0.93979296;
fixD[fix_reso] = 0.70710678;
fixE[fix_reso] = 0.52972649;
fixF[fix_reso] = 0.50316379;
double K = tan(M_PI * fixA[fix_freq]); //lowpass
double norm = 1.0 / (1.0 + K / fixA[fix_reso] + K * K);
fixA[fix_a0] = K * K * norm;
fixA[fix_a1] = 2.0 * fixA[fix_a0];
fixA[fix_a2] = fixA[fix_a0];
fixA[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixA[fix_b2] = (1.0 - K / fixA[fix_reso] + K * K) * norm;
K = tan(M_PI * fixB[fix_freq]);
norm = 1.0 / (1.0 + K / fixB[fix_reso] + K * K);
fixB[fix_a0] = K * K * norm;
fixB[fix_a1] = 2.0 * fixB[fix_a0];
fixB[fix_a2] = fixB[fix_a0];
fixB[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixB[fix_b2] = (1.0 - K / fixB[fix_reso] + K * K) * norm;
K = tan(M_PI * fixC[fix_freq]);
norm = 1.0 / (1.0 + K / fixC[fix_reso] + K * K);
fixC[fix_a0] = K * K * norm;
fixC[fix_a1] = 2.0 * fixC[fix_a0];
fixC[fix_a2] = fixC[fix_a0];
fixC[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixC[fix_b2] = (1.0 - K / fixC[fix_reso] + K * K) * norm;
K = tan(M_PI * fixD[fix_freq]);
norm = 1.0 / (1.0 + K / fixD[fix_reso] + K * K);
fixD[fix_a0] = K * K * norm;
fixD[fix_a1] = 2.0 * fixD[fix_a0];
fixD[fix_a2] = fixD[fix_a0];
fixD[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixD[fix_b2] = (1.0 - K / fixD[fix_reso] + K * K) * norm;
K = tan(M_PI * fixE[fix_freq]);
norm = 1.0 / (1.0 + K / fixE[fix_reso] + K * K);
fixE[fix_a0] = K * K * norm;
fixE[fix_a1] = 2.0 * fixE[fix_a0];
fixE[fix_a2] = fixE[fix_a0];
fixE[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixE[fix_b2] = (1.0 - K / fixE[fix_reso] + K * K) * norm;
K = tan(M_PI * fixF[fix_freq]);
norm = 1.0 / (1.0 + K / fixF[fix_reso] + K * K);
fixF[fix_a0] = K * K * norm;
fixF[fix_a1] = 2.0 * fixF[fix_a0];
fixF[fix_a2] = fixF[fix_a0];
fixF[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixF[fix_b2] = (1.0 - K / fixF[fix_reso] + K * K) * norm;
while (--sampleFrames >= 0)
{
double inputSampleL = *in1;
double inputSampleR = *in2;
if (fabs(inputSampleL)<1.18e-23) inputSampleL = fpdL * 1.18e-17;
if (fabs(inputSampleR)<1.18e-23) inputSampleR = fpdR * 1.18e-17;
double drySampleL = inputSampleL;
double drySampleR = inputSampleR;
double outSample = (inputSampleL * fixA[fix_a0]) + fixA[fix_sL1];
fixA[fix_sL1] = (inputSampleL * fixA[fix_a1]) - (outSample * fixA[fix_b1]) + fixA[fix_sL2];
fixA[fix_sL2] = (inputSampleL * fixA[fix_a2]) - (outSample * fixA[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixA[fix_a0]) + fixA[fix_sR1];
fixA[fix_sR1] = (inputSampleR * fixA[fix_a1]) - (outSample * fixA[fix_b1]) + fixA[fix_sR2];
fixA[fix_sR2] = (inputSampleR * fixA[fix_a2]) - (outSample * fixA[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
if (inputSampleL > 1.0) inputSampleL = 1.0;
if (inputSampleL < -1.0) inputSampleL = -1.0;
double basscutL = 0.98;
//we're going to be shifting this as the stages progress
double inputlevelL = startlevel;
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleAL = (iirSampleAL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleAL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
double bridgerectifier = (smoothAL + inputSampleL);
smoothAL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleBL = (iirSampleBL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleBL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothBL + inputSampleL);
smoothBL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
if (inputSampleR > 1.0) inputSampleR = 1.0;
if (inputSampleR < -1.0) inputSampleR = -1.0;
double basscutR = 0.98;
//we're going to be shifting this as the stages progress
double inputlevelR = startlevel;
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleAR = (iirSampleAR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleAR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothAR + inputSampleR);
smoothAR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleBR = (iirSampleBR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleBR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothBR + inputSampleR);
smoothBR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixB[fix_a0]) + fixB[fix_sL1];
fixB[fix_sL1] = (inputSampleL * fixB[fix_a1]) - (outSample * fixB[fix_b1]) + fixB[fix_sL2];
fixB[fix_sL2] = (inputSampleL * fixB[fix_a2]) - (outSample * fixB[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixB[fix_a0]) + fixB[fix_sR1];
fixB[fix_sR1] = (inputSampleR * fixB[fix_a1]) - (outSample * fixB[fix_b1]) + fixB[fix_sR2];
fixB[fix_sR2] = (inputSampleR * fixB[fix_a2]) - (outSample * fixB[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleCL = (iirSampleCL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleCL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothCL + inputSampleL);
smoothCL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleDL = (iirSampleDL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleDL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654) );
//overdrive
bridgerectifier = (smoothDL + inputSampleL);
smoothDL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleCR = (iirSampleCR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleCR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothCR + inputSampleR);
smoothCR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleDR = (iirSampleDR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleDR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothDR + inputSampleR);
smoothDR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixC[fix_a0]) + fixC[fix_sL1];
fixC[fix_sL1] = (inputSampleL * fixC[fix_a1]) - (outSample * fixC[fix_b1]) + fixC[fix_sL2];
fixC[fix_sL2] = (inputSampleL * fixC[fix_a2]) - (outSample * fixC[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixC[fix_a0]) + fixC[fix_sR1];
fixC[fix_sR1] = (inputSampleR * fixC[fix_a1]) - (outSample * fixC[fix_b1]) + fixC[fix_sR2];
fixC[fix_sR2] = (inputSampleR * fixC[fix_a2]) - (outSample * fixC[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleEL = (iirSampleEL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleEL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothEL + inputSampleL);
smoothEL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleFL = (iirSampleFL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleFL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothFL + inputSampleL);
smoothFL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleER = (iirSampleER * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleER*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothER + inputSampleR);
smoothER = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleFR = (iirSampleFR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleFR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothFR + inputSampleR);
smoothFR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixD[fix_a0]) + fixD[fix_sL1];
fixD[fix_sL1] = (inputSampleL * fixD[fix_a1]) - (outSample * fixD[fix_b1]) + fixD[fix_sL2];
fixD[fix_sL2] = (inputSampleL * fixD[fix_a2]) - (outSample * fixD[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixD[fix_a0]) + fixD[fix_sR1];
fixD[fix_sR1] = (inputSampleR * fixD[fix_a1]) - (outSample * fixD[fix_b1]) + fixD[fix_sR2];
fixD[fix_sR2] = (inputSampleR * fixD[fix_a2]) - (outSample * fixD[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleGL = (iirSampleGL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleGL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothGL + inputSampleL);
smoothGL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleHL = (iirSampleHL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleHL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothHL + inputSampleL);
smoothHL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleGR = (iirSampleGR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleGR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothGR + inputSampleR);
smoothGR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleHR = (iirSampleHR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleHR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothHR + inputSampleR);
smoothHR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixE[fix_a0]) + fixE[fix_sL1];
fixE[fix_sL1] = (inputSampleL * fixE[fix_a1]) - (outSample * fixE[fix_b1]) + fixE[fix_sL2];
fixE[fix_sL2] = (inputSampleL * fixE[fix_a2]) - (outSample * fixE[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixE[fix_a0]) + fixE[fix_sR1];
fixE[fix_sR1] = (inputSampleR * fixE[fix_a1]) - (outSample * fixE[fix_b1]) + fixE[fix_sR2];
fixE[fix_sR2] = (inputSampleR * fixE[fix_a2]) - (outSample * fixE[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleIL = (iirSampleIL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleIL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothIL + inputSampleL);
smoothIL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleJL = (iirSampleJL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleJL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothJL + inputSampleL);
smoothJL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleIR = (iirSampleIR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleIR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothIR + inputSampleR);
smoothIR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleJR = (iirSampleJR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleJR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothJR + inputSampleR);
smoothJR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixF[fix_a0]) + fixF[fix_sL1];
fixF[fix_sL1] = (inputSampleL * fixF[fix_a1]) - (outSample * fixF[fix_b1]) + fixF[fix_sL2];
fixF[fix_sL2] = (inputSampleL * fixF[fix_a2]) - (outSample * fixF[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixF[fix_a0]) + fixF[fix_sR1];
fixF[fix_sR1] = (inputSampleR * fixF[fix_a1]) - (outSample * fixF[fix_b1]) + fixF[fix_sR2];
fixF[fix_sR2] = (inputSampleR * fixF[fix_a2]) - (outSample * fixF[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleKL = (iirSampleKL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleKL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothKL + inputSampleL);
smoothKL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleLL = (iirSampleLL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleLL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothLL + inputSampleL);
smoothLL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleKR = (iirSampleKR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleKR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothKR + inputSampleR);
smoothKR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleLR = (iirSampleLR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleLR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothLR + inputSampleR);
smoothLR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
iirLowpassL = (iirLowpassL * (1.0 - toneEQ)) + (inputSampleL * toneEQ);
inputSampleL = iirLowpassL;
//lowpass. The only one of this type.
iirLowpassR = (iirLowpassR * (1.0 - toneEQ)) + (inputSampleR * toneEQ);
inputSampleR = iirLowpassR;
//lowpass. The only one of this type.
iirSpkAL = (iirSpkAL * (1.0 - BEQ)) + (inputSampleL * BEQ);
//extra lowpass for 4*12" speakers
iirSpkAR = (iirSpkAR * (1.0 - BEQ)) + (inputSampleR * BEQ);
//extra lowpass for 4*12" speakers
if (count < 0 || count > 128) {count = 128;}
double resultBL = 0.0;
double resultBR = 0.0;
if (flip)
{
OddL[count+128] = OddL[count] = iirSpkAL;
resultBL = (OddL[count+down] + OddL[count+side] + OddL[count+diagonal]);
OddR[count+128] = OddR[count] = iirSpkAR;
resultBR = (OddR[count+down] + OddR[count+side] + OddR[count+diagonal]);
}
else
{
EvenL[count+128] = EvenL[count] = iirSpkAL;
resultBL = (EvenL[count+down] + EvenL[count+side] + EvenL[count+diagonal]);
EvenR[count+128] = EvenR[count] = iirSpkAR;
resultBR = (EvenR[count+down] + EvenR[count+side] + EvenR[count+diagonal]);
}
count--;
iirSpkBL = (iirSpkBL * (1.0 - BEQ)) + (resultBL * BEQ);
inputSampleL += (iirSpkBL * bleed);
//extra lowpass for 4*12" speakers
iirSpkBR = (iirSpkBR * (1.0 - BEQ)) + (resultBR * BEQ);
inputSampleR += (iirSpkBR * bleed);
//extra lowpass for 4*12" speakers
bridgerectifier = fabs(inputSampleL*outputlevel);
if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
bridgerectifier = sin(bridgerectifier);
if (inputSampleL > 0) inputSampleL = bridgerectifier;
else inputSampleL = -bridgerectifier;
bridgerectifier = fabs(inputSampleR*outputlevel);
if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
bridgerectifier = sin(bridgerectifier);
if (inputSampleR > 0) inputSampleR = bridgerectifier;
else inputSampleR = -bridgerectifier;
iirSubL = (iirSubL * (1.0 - BEQ)) + (inputSampleL * BEQ);
inputSampleL += (iirSubL * bassfill * outputlevel);
iirSubR = (iirSubR * (1.0 - BEQ)) + (inputSampleR * BEQ);
inputSampleR += (iirSubR * bassfill * outputlevel);
double randy = ((double(fpdL)/UINT32_MAX)*0.053);
inputSampleL = ((inputSampleL*(1.0-randy))+(storeSampleL*randy))*outputlevel;
storeSampleL = inputSampleL;
randy = ((double(fpdR)/UINT32_MAX)*0.053);
inputSampleR = ((inputSampleR*(1.0-randy))+(storeSampleR*randy))*outputlevel;
storeSampleR = inputSampleR;
flip = !flip;
if (wet !=1.0) {
inputSampleL = (inputSampleL * wet) + (drySampleL * (1.0-wet));
inputSampleR = (inputSampleR * wet) + (drySampleR * (1.0-wet));
}
//Dry/Wet control, defaults to the last slider
//amp
cycle++;
if (cycle == cycleEnd) {
double temp = (inputSampleL + smoothCabAL)/3.0;
smoothCabAL = inputSampleL;
inputSampleL = temp;
bL[84] = bL[83]; bL[83] = bL[82]; bL[82] = bL[81]; bL[81] = bL[80]; bL[80] = bL[79];
bL[79] = bL[78]; bL[78] = bL[77]; bL[77] = bL[76]; bL[76] = bL[75]; bL[75] = bL[74]; bL[74] = bL[73]; bL[73] = bL[72]; bL[72] = bL[71];
bL[71] = bL[70]; bL[70] = bL[69]; bL[69] = bL[68]; bL[68] = bL[67]; bL[67] = bL[66]; bL[66] = bL[65]; bL[65] = bL[64]; bL[64] = bL[63];
bL[63] = bL[62]; bL[62] = bL[61]; bL[61] = bL[60]; bL[60] = bL[59]; bL[59] = bL[58]; bL[58] = bL[57]; bL[57] = bL[56]; bL[56] = bL[55];
bL[55] = bL[54]; bL[54] = bL[53]; bL[53] = bL[52]; bL[52] = bL[51]; bL[51] = bL[50]; bL[50] = bL[49]; bL[49] = bL[48]; bL[48] = bL[47];
bL[47] = bL[46]; bL[46] = bL[45]; bL[45] = bL[44]; bL[44] = bL[43]; bL[43] = bL[42]; bL[42] = bL[41]; bL[41] = bL[40]; bL[40] = bL[39];
bL[39] = bL[38]; bL[38] = bL[37]; bL[37] = bL[36]; bL[36] = bL[35]; bL[35] = bL[34]; bL[34] = bL[33]; bL[33] = bL[32]; bL[32] = bL[31];
bL[31] = bL[30]; bL[30] = bL[29]; bL[29] = bL[28]; bL[28] = bL[27]; bL[27] = bL[26]; bL[26] = bL[25]; bL[25] = bL[24]; bL[24] = bL[23];
bL[23] = bL[22]; bL[22] = bL[21]; bL[21] = bL[20]; bL[20] = bL[19]; bL[19] = bL[18]; bL[18] = bL[17]; bL[17] = bL[16]; bL[16] = bL[15];
bL[15] = bL[14]; bL[14] = bL[13]; bL[13] = bL[12]; bL[12] = bL[11]; bL[11] = bL[10]; bL[10] = bL[9]; bL[9] = bL[8]; bL[8] = bL[7];
bL[7] = bL[6]; bL[6] = bL[5]; bL[5] = bL[4]; bL[4] = bL[3]; bL[3] = bL[2]; bL[2] = bL[1]; bL[1] = bL[0]; bL[0] = inputSampleL;
inputSampleL += (bL[1] * (1.31698250313308396 - (0.08140616497621633*fabs(bL[1]))));
inputSampleL += (bL[2] * (1.47229016949915326 - (0.27680278993637253*fabs(bL[2]))));
inputSampleL += (bL[3] * (1.30410109086044956 - (0.35629113432046489*fabs(bL[3]))));
inputSampleL += (bL[4] * (0.81766210474551260 - (0.26808782337659753*fabs(bL[4]))));
inputSampleL += (bL[5] * (0.19868872545506663 - (0.11105517193919669*fabs(bL[5]))));
inputSampleL -= (bL[6] * (0.39115909132567039 - (0.12630622002682679*fabs(bL[6]))));
inputSampleL -= (bL[7] * (0.76881891559343574 - (0.40879849500403143*fabs(bL[7]))));
inputSampleL -= (bL[8] * (0.87146861782680340 - (0.59529560488000599*fabs(bL[8]))));
inputSampleL -= (bL[9] * (0.79504575932563670 - (0.60877047551611796*fabs(bL[9]))));
inputSampleL -= (bL[10] * (0.61653017622406314 - (0.47662851438557335*fabs(bL[10]))));
inputSampleL -= (bL[11] * (0.40718195794382067 - (0.24955839378539713*fabs(bL[11]))));
inputSampleL -= (bL[12] * (0.31794900040616203 - (0.04169792259600613*fabs(bL[12]))));
inputSampleL -= (bL[13] * (0.41075032540217843 + (0.00368483996076280*fabs(bL[13]))));
inputSampleL -= (bL[14] * (0.56901352922170667 - (0.11027360805893105*fabs(bL[14]))));
inputSampleL -= (bL[15] * (0.62443222391889264 - (0.22198075154245228*fabs(bL[15]))));
inputSampleL -= (bL[16] * (0.53462856723129204 - (0.22933544545324852*fabs(bL[16]))));
inputSampleL -= (bL[17] * (0.34441703361995046 - (0.12956809502269492*fabs(bL[17]))));
inputSampleL -= (bL[18] * (0.13947052337867882 + (0.00339775055962799*fabs(bL[18]))));
inputSampleL += (bL[19] * (0.03771252648928484 - (0.10863931549251718*fabs(bL[19]))));
inputSampleL += (bL[20] * (0.18280210770271693 - (0.17413646599296417*fabs(bL[20]))));
inputSampleL += (bL[21] * (0.24621986701761467 - (0.14547053270435095*fabs(bL[21]))));
inputSampleL += (bL[22] * (0.22347075142737360 - (0.02493869490104031*fabs(bL[22]))));
inputSampleL += (bL[23] * (0.14346348482123716 + (0.11284054747963246*fabs(bL[23]))));
inputSampleL += (bL[24] * (0.00834364862916028 + (0.24284684053733926*fabs(bL[24]))));
inputSampleL -= (bL[25] * (0.11559740296078347 - (0.32623054435304538*fabs(bL[25]))));
inputSampleL -= (bL[26] * (0.18067604561283060 - (0.32311481551122478*fabs(bL[26]))));
inputSampleL -= (bL[27] * (0.22927997789035612 - (0.26991539052832925*fabs(bL[27]))));
inputSampleL -= (bL[28] * (0.28487666578669446 - (0.22437227250279349*fabs(bL[28]))));
inputSampleL -= (bL[29] * (0.31992973037153838 - (0.15289876100963865*fabs(bL[29]))));
inputSampleL -= (bL[30] * (0.35174606303520733 - (0.05656293023086628*fabs(bL[30]))));
inputSampleL -= (bL[31] * (0.36894898011375254 + (0.04333925421463558*fabs(bL[31]))));
inputSampleL -= (bL[32] * (0.32567576055307507 + (0.14594589410921388*fabs(bL[32]))));
inputSampleL -= (bL[33] * (0.27440135050585784 + (0.15529667398122521*fabs(bL[33]))));
inputSampleL -= (bL[34] * (0.21998973785078091 + (0.05083553737157104*fabs(bL[34]))));
inputSampleL -= (bL[35] * (0.10323624876862457 - (0.04651829594199963*fabs(bL[35]))));
inputSampleL += (bL[36] * (0.02091603687851074 + (0.12000046818439322*fabs(bL[36]))));
inputSampleL += (bL[37] * (0.11344930914138468 + (0.17697142512225839*fabs(bL[37]))));
inputSampleL += (bL[38] * (0.22766779627643968 + (0.13645102964003858*fabs(bL[38]))));
inputSampleL += (bL[39] * (0.38378309953638229 - (0.01997653307333791*fabs(bL[39]))));
inputSampleL += (bL[40] * (0.52789400804568076 - (0.21409137428422448*fabs(bL[40]))));
inputSampleL += (bL[41] * (0.55444630296938280 - (0.32331980931576626*fabs(bL[41]))));
inputSampleL += (bL[42] * (0.42333237669264601 - (0.26855847463044280*fabs(bL[42]))));
inputSampleL += (bL[43] * (0.21942831522035078 - (0.12051365248820624*fabs(bL[43]))));
inputSampleL -= (bL[44] * (0.00584169427830633 - (0.03706970171280329*fabs(bL[44]))));
inputSampleL -= (bL[45] * (0.24279799124660351 - (0.17296440491477982*fabs(bL[45]))));
inputSampleL -= (bL[46] * (0.40173760787507085 - (0.21717989835163351*fabs(bL[46]))));
inputSampleL -= (bL[47] * (0.43930035724188155 - (0.16425928481378199*fabs(bL[47]))));
inputSampleL -= (bL[48] * (0.41067765934041811 - (0.10390115786636855*fabs(bL[48]))));
inputSampleL -= (bL[49] * (0.34409235547165967 - (0.07268159377411920*fabs(bL[49]))));
inputSampleL -= (bL[50] * (0.26542883122568151 - (0.05483457497365785*fabs(bL[50]))));
inputSampleL -= (bL[51] * (0.22024754776138800 - (0.06484897950087598*fabs(bL[51]))));
inputSampleL -= (bL[52] * (0.20394367993632415 - (0.08746309731952180*fabs(bL[52]))));
inputSampleL -= (bL[53] * (0.17565242431124092 - (0.07611309538078760*fabs(bL[53]))));
inputSampleL -= (bL[54] * (0.10116623231246825 - (0.00642818706295112*fabs(bL[54]))));
inputSampleL -= (bL[55] * (0.00782648272053632 + (0.08004141267685004*fabs(bL[55]))));
inputSampleL += (bL[56] * (0.05059046006747323 - (0.12436676387548490*fabs(bL[56]))));
inputSampleL += (bL[57] * (0.06241531553254467 - (0.11530779547021434*fabs(bL[57]))));
inputSampleL += (bL[58] * (0.04952694587101836 - (0.08340945324333944*fabs(bL[58]))));
inputSampleL += (bL[59] * (0.00843873294401687 - (0.03279659052562903*fabs(bL[59]))));
inputSampleL -= (bL[60] * (0.05161338949440241 - (0.03428181149163798*fabs(bL[60]))));
inputSampleL -= (bL[61] * (0.08165520146902012 - (0.08196746092283110*fabs(bL[61]))));
inputSampleL -= (bL[62] * (0.06639532849935320 - (0.09797462781896329*fabs(bL[62]))));
inputSampleL -= (bL[63] * (0.02953430910661621 - (0.09175612938515763*fabs(bL[63]))));
inputSampleL += (bL[64] * (0.00741058547442938 + (0.05442091048731967*fabs(bL[64]))));
inputSampleL += (bL[65] * (0.01832866125391727 + (0.00306243693643687*fabs(bL[65]))));
inputSampleL += (bL[66] * (0.00526964230373573 - (0.04364102661136410*fabs(bL[66]))));
inputSampleL -= (bL[67] * (0.00300984373848200 + (0.09742737841278880*fabs(bL[67]))));
inputSampleL -= (bL[68] * (0.00413616769576694 + (0.14380661694523073*fabs(bL[68]))));
inputSampleL -= (bL[69] * (0.00588769034931419 + (0.16012843578892538*fabs(bL[69]))));
inputSampleL -= (bL[70] * (0.00688588239450581 + (0.14074464279305798*fabs(bL[70]))));
inputSampleL -= (bL[71] * (0.02277307992926315 + (0.07914752191801366*fabs(bL[71]))));
inputSampleL -= (bL[72] * (0.04627166091180877 - (0.00192787268067208*fabs(bL[72]))));
inputSampleL -= (bL[73] * (0.05562045897455786 - (0.05932868727665747*fabs(bL[73]))));
inputSampleL -= (bL[74] * (0.05134243784922165 - (0.08245334798868090*fabs(bL[74]))));
inputSampleL -= (bL[75] * (0.04719409472239919 - (0.07498680629253825*fabs(bL[75]))));
inputSampleL -= (bL[76] * (0.05889738914266415 - (0.06116127018043697*fabs(bL[76]))));
inputSampleL -= (bL[77] * (0.09428363535111127 - (0.06535868867863834*fabs(bL[77]))));
inputSampleL -= (bL[78] * (0.15181756953225126 - (0.08982979655234427*fabs(bL[78]))));
inputSampleL -= (bL[79] * (0.20878969456036670 - (0.10761070891499538*fabs(bL[79]))));
inputSampleL -= (bL[80] * (0.22647885581813790 - (0.08462542510349125*fabs(bL[80]))));
inputSampleL -= (bL[81] * (0.19723482443646323 - (0.02665160920736287*fabs(bL[81]))));
inputSampleL -= (bL[82] * (0.16441643451155163 + (0.02314691954338197*fabs(bL[82]))));
inputSampleL -= (bL[83] * (0.15201914054931515 + (0.04424903493886839*fabs(bL[83]))));
inputSampleL -= (bL[84] * (0.15454370641307855 + (0.04223203797913008*fabs(bL[84]))));
temp = (inputSampleL + smoothCabBL)/3.0;
smoothCabBL = inputSampleL;
inputSampleL = temp/4.0;
randy = ((double(fpdL)/UINT32_MAX)*0.057);
drySampleL = ((((inputSampleL*(1-randy))+(lastCabSampleL*randy))*wet)+(drySampleL*(1.0-wet)))*outputlevel;
lastCabSampleL = inputSampleL;
inputSampleL = drySampleL; //cab L
temp = (inputSampleR + smoothCabAR)/3.0;
smoothCabAR = inputSampleR;
inputSampleR = temp;
bR[84] = bR[83]; bR[83] = bR[82]; bR[82] = bR[81]; bR[81] = bR[80]; bR[80] = bR[79];
bR[79] = bR[78]; bR[78] = bR[77]; bR[77] = bR[76]; bR[76] = bR[75]; bR[75] = bR[74]; bR[74] = bR[73]; bR[73] = bR[72]; bR[72] = bR[71];
bR[71] = bR[70]; bR[70] = bR[69]; bR[69] = bR[68]; bR[68] = bR[67]; bR[67] = bR[66]; bR[66] = bR[65]; bR[65] = bR[64]; bR[64] = bR[63];
bR[63] = bR[62]; bR[62] = bR[61]; bR[61] = bR[60]; bR[60] = bR[59]; bR[59] = bR[58]; bR[58] = bR[57]; bR[57] = bR[56]; bR[56] = bR[55];
bR[55] = bR[54]; bR[54] = bR[53]; bR[53] = bR[52]; bR[52] = bR[51]; bR[51] = bR[50]; bR[50] = bR[49]; bR[49] = bR[48]; bR[48] = bR[47];
bR[47] = bR[46]; bR[46] = bR[45]; bR[45] = bR[44]; bR[44] = bR[43]; bR[43] = bR[42]; bR[42] = bR[41]; bR[41] = bR[40]; bR[40] = bR[39];
bR[39] = bR[38]; bR[38] = bR[37]; bR[37] = bR[36]; bR[36] = bR[35]; bR[35] = bR[34]; bR[34] = bR[33]; bR[33] = bR[32]; bR[32] = bR[31];
bR[31] = bR[30]; bR[30] = bR[29]; bR[29] = bR[28]; bR[28] = bR[27]; bR[27] = bR[26]; bR[26] = bR[25]; bR[25] = bR[24]; bR[24] = bR[23];
bR[23] = bR[22]; bR[22] = bR[21]; bR[21] = bR[20]; bR[20] = bR[19]; bR[19] = bR[18]; bR[18] = bR[17]; bR[17] = bR[16]; bR[16] = bR[15];
bR[15] = bR[14]; bR[14] = bR[13]; bR[13] = bR[12]; bR[12] = bR[11]; bR[11] = bR[10]; bR[10] = bR[9]; bR[9] = bR[8]; bR[8] = bR[7];
bR[7] = bR[6]; bR[6] = bR[5]; bR[5] = bR[4]; bR[4] = bR[3]; bR[3] = bR[2]; bR[2] = bR[1]; bR[1] = bR[0]; bR[0] = inputSampleR;
inputSampleR += (bR[1] * (1.31698250313308396 - (0.08140616497621633*fabs(bR[1]))));
inputSampleR += (bR[2] * (1.47229016949915326 - (0.27680278993637253*fabs(bR[2]))));
inputSampleR += (bR[3] * (1.30410109086044956 - (0.35629113432046489*fabs(bR[3]))));
inputSampleR += (bR[4] * (0.81766210474551260 - (0.26808782337659753*fabs(bR[4]))));
inputSampleR += (bR[5] * (0.19868872545506663 - (0.11105517193919669*fabs(bR[5]))));
inputSampleR -= (bR[6] * (0.39115909132567039 - (0.12630622002682679*fabs(bR[6]))));
inputSampleR -= (bR[7] * (0.76881891559343574 - (0.40879849500403143*fabs(bR[7]))));
inputSampleR -= (bR[8] * (0.87146861782680340 - (0.59529560488000599*fabs(bR[8]))));
inputSampleR -= (bR[9] * (0.79504575932563670 - (0.60877047551611796*fabs(bR[9]))));
inputSampleR -= (bR[10] * (0.61653017622406314 - (0.47662851438557335*fabs(bR[10]))));
inputSampleR -= (bR[11] * (0.40718195794382067 - (0.24955839378539713*fabs(bR[11]))));
inputSampleR -= (bR[12] * (0.31794900040616203 - (0.04169792259600613*fabs(bR[12]))));
inputSampleR -= (bR[13] * (0.41075032540217843 + (0.00368483996076280*fabs(bR[13]))));
inputSampleR -= (bR[14] * (0.56901352922170667 - (0.11027360805893105*fabs(bR[14]))));
inputSampleR -= (bR[15] * (0.62443222391889264 - (0.22198075154245228*fabs(bR[15]))));
inputSampleR -= (bR[16] * (0.53462856723129204 - (0.22933544545324852*fabs(bR[16]))));
inputSampleR -= (bR[17] * (0.34441703361995046 - (0.12956809502269492*fabs(bR[17]))));
inputSampleR -= (bR[18] * (0.13947052337867882 + (0.00339775055962799*fabs(bR[18]))));
inputSampleR += (bR[19] * (0.03771252648928484 - (0.10863931549251718*fabs(bR[19]))));
inputSampleR += (bR[20] * (0.18280210770271693 - (0.17413646599296417*fabs(bR[20]))));
inputSampleR += (bR[21] * (0.24621986701761467 - (0.14547053270435095*fabs(bR[21]))));
inputSampleR += (bR[22] * (0.22347075142737360 - (0.02493869490104031*fabs(bR[22]))));
inputSampleR += (bR[23] * (0.14346348482123716 + (0.11284054747963246*fabs(bR[23]))));
inputSampleR += (bR[24] * (0.00834364862916028 + (0.24284684053733926*fabs(bR[24]))));
inputSampleR -= (bR[25] * (0.11559740296078347 - (0.32623054435304538*fabs(bR[25]))));
inputSampleR -= (bR[26] * (0.18067604561283060 - (0.32311481551122478*fabs(bR[26]))));
inputSampleR -= (bR[27] * (0.22927997789035612 - (0.26991539052832925*fabs(bR[27]))));
inputSampleR -= (bR[28] * (0.28487666578669446 - (0.22437227250279349*fabs(bR[28]))));
inputSampleR -= (bR[29] * (0.31992973037153838 - (0.15289876100963865*fabs(bR[29]))));
inputSampleR -= (bR[30] * (0.35174606303520733 - (0.05656293023086628*fabs(bR[30]))));
inputSampleR -= (bR[31] * (0.36894898011375254 + (0.04333925421463558*fabs(bR[31]))));
inputSampleR -= (bR[32] * (0.32567576055307507 + (0.14594589410921388*fabs(bR[32]))));
inputSampleR -= (bR[33] * (0.27440135050585784 + (0.15529667398122521*fabs(bR[33]))));
inputSampleR -= (bR[34] * (0.21998973785078091 + (0.05083553737157104*fabs(bR[34]))));
inputSampleR -= (bR[35] * (0.10323624876862457 - (0.04651829594199963*fabs(bR[35]))));
inputSampleR += (bR[36] * (0.02091603687851074 + (0.12000046818439322*fabs(bR[36]))));
inputSampleR += (bR[37] * (0.11344930914138468 + (0.17697142512225839*fabs(bR[37]))));
inputSampleR += (bR[38] * (0.22766779627643968 + (0.13645102964003858*fabs(bR[38]))));
inputSampleR += (bR[39] * (0.38378309953638229 - (0.01997653307333791*fabs(bR[39]))));
inputSampleR += (bR[40] * (0.52789400804568076 - (0.21409137428422448*fabs(bR[40]))));
inputSampleR += (bR[41] * (0.55444630296938280 - (0.32331980931576626*fabs(bR[41]))));
inputSampleR += (bR[42] * (0.42333237669264601 - (0.26855847463044280*fabs(bR[42]))));
inputSampleR += (bR[43] * (0.21942831522035078 - (0.12051365248820624*fabs(bR[43]))));
inputSampleR -= (bR[44] * (0.00584169427830633 - (0.03706970171280329*fabs(bR[44]))));
inputSampleR -= (bR[45] * (0.24279799124660351 - (0.17296440491477982*fabs(bR[45]))));
inputSampleR -= (bR[46] * (0.40173760787507085 - (0.21717989835163351*fabs(bR[46]))));
inputSampleR -= (bR[47] * (0.43930035724188155 - (0.16425928481378199*fabs(bR[47]))));
inputSampleR -= (bR[48] * (0.41067765934041811 - (0.10390115786636855*fabs(bR[48]))));
inputSampleR -= (bR[49] * (0.34409235547165967 - (0.07268159377411920*fabs(bR[49]))));
inputSampleR -= (bR[50] * (0.26542883122568151 - (0.05483457497365785*fabs(bR[50]))));
inputSampleR -= (bR[51] * (0.22024754776138800 - (0.06484897950087598*fabs(bR[51]))));
inputSampleR -= (bR[52] * (0.20394367993632415 - (0.08746309731952180*fabs(bR[52]))));
inputSampleR -= (bR[53] * (0.17565242431124092 - (0.07611309538078760*fabs(bR[53]))));
inputSampleR -= (bR[54] * (0.10116623231246825 - (0.00642818706295112*fabs(bR[54]))));
inputSampleR -= (bR[55] * (0.00782648272053632 + (0.08004141267685004*fabs(bR[55]))));
inputSampleR += (bR[56] * (0.05059046006747323 - (0.12436676387548490*fabs(bR[56]))));
inputSampleR += (bR[57] * (0.06241531553254467 - (0.11530779547021434*fabs(bR[57]))));
inputSampleR += (bR[58] * (0.04952694587101836 - (0.08340945324333944*fabs(bR[58]))));
inputSampleR += (bR[59] * (0.00843873294401687 - (0.03279659052562903*fabs(bR[59]))));
inputSampleR -= (bR[60] * (0.05161338949440241 - (0.03428181149163798*fabs(bR[60]))));
inputSampleR -= (bR[61] * (0.08165520146902012 - (0.08196746092283110*fabs(bR[61]))));
inputSampleR -= (bR[62] * (0.06639532849935320 - (0.09797462781896329*fabs(bR[62]))));
inputSampleR -= (bR[63] * (0.02953430910661621 - (0.09175612938515763*fabs(bR[63]))));
inputSampleR += (bR[64] * (0.00741058547442938 + (0.05442091048731967*fabs(bR[64]))));
inputSampleR += (bR[65] * (0.01832866125391727 + (0.00306243693643687*fabs(bR[65]))));
inputSampleR += (bR[66] * (0.00526964230373573 - (0.04364102661136410*fabs(bR[66]))));
inputSampleR -= (bR[67] * (0.00300984373848200 + (0.09742737841278880*fabs(bR[67]))));
inputSampleR -= (bR[68] * (0.00413616769576694 + (0.14380661694523073*fabs(bR[68]))));
inputSampleR -= (bR[69] * (0.00588769034931419 + (0.16012843578892538*fabs(bR[69]))));
inputSampleR -= (bR[70] * (0.00688588239450581 + (0.14074464279305798*fabs(bR[70]))));
inputSampleR -= (bR[71] * (0.02277307992926315 + (0.07914752191801366*fabs(bR[71]))));
inputSampleR -= (bR[72] * (0.04627166091180877 - (0.00192787268067208*fabs(bR[72]))));
inputSampleR -= (bR[73] * (0.05562045897455786 - (0.05932868727665747*fabs(bR[73]))));
inputSampleR -= (bR[74] * (0.05134243784922165 - (0.08245334798868090*fabs(bR[74]))));
inputSampleR -= (bR[75] * (0.04719409472239919 - (0.07498680629253825*fabs(bR[75]))));
inputSampleR -= (bR[76] * (0.05889738914266415 - (0.06116127018043697*fabs(bR[76]))));
inputSampleR -= (bR[77] * (0.09428363535111127 - (0.06535868867863834*fabs(bR[77]))));
inputSampleR -= (bR[78] * (0.15181756953225126 - (0.08982979655234427*fabs(bR[78]))));
inputSampleR -= (bR[79] * (0.20878969456036670 - (0.10761070891499538*fabs(bR[79]))));
inputSampleR -= (bR[80] * (0.22647885581813790 - (0.08462542510349125*fabs(bR[80]))));
inputSampleR -= (bR[81] * (0.19723482443646323 - (0.02665160920736287*fabs(bR[81]))));
inputSampleR -= (bR[82] * (0.16441643451155163 + (0.02314691954338197*fabs(bR[82]))));
inputSampleR -= (bR[83] * (0.15201914054931515 + (0.04424903493886839*fabs(bR[83]))));
inputSampleR -= (bR[84] * (0.15454370641307855 + (0.04223203797913008*fabs(bR[84]))));
temp = (inputSampleR + smoothCabBR)/3.0;
smoothCabBR = inputSampleR;
inputSampleR = temp/4.0;
randy = ((double(fpdR)/UINT32_MAX)*0.057);
drySampleR = ((((inputSampleR*(1.0-randy))+(lastCabSampleR*randy))*wet)+(drySampleR*(1.0-wet)))*outputlevel;
lastCabSampleR = inputSampleR;
inputSampleR = drySampleR; //cab
if (cycleEnd == 4) {
lastRefL[0] = lastRefL[4]; //start from previous last
lastRefL[2] = (lastRefL[0] + inputSampleL)/2; //half
lastRefL[1] = (lastRefL[0] + lastRefL[2])/2; //one quarter
lastRefL[3] = (lastRefL[2] + inputSampleL)/2; //three quarters
lastRefL[4] = inputSampleL; //full
lastRefR[0] = lastRefR[4]; //start from previous last
lastRefR[2] = (lastRefR[0] + inputSampleR)/2; //half
lastRefR[1] = (lastRefR[0] + lastRefR[2])/2; //one quarter
lastRefR[3] = (lastRefR[2] + inputSampleR)/2; //three quarters
lastRefR[4] = inputSampleR; //full
}
if (cycleEnd == 3) {
lastRefL[0] = lastRefL[3]; //start from previous last
lastRefL[2] = (lastRefL[0]+lastRefL[0]+inputSampleL)/3; //third
lastRefL[1] = (lastRefL[0]+inputSampleL+inputSampleL)/3; //two thirds
lastRefL[3] = inputSampleL; //full
lastRefR[0] = lastRefR[3]; //start from previous last
lastRefR[2] = (lastRefR[0]+lastRefR[0]+inputSampleR)/3; //third
lastRefR[1] = (lastRefR[0]+inputSampleR+inputSampleR)/3; //two thirds
lastRefR[3] = inputSampleR; //full
}
if (cycleEnd == 2) {
lastRefL[0] = lastRefL[2]; //start from previous last
lastRefL[1] = (lastRefL[0] + inputSampleL)/2; //half
lastRefL[2] = inputSampleL; //full
lastRefR[0] = lastRefR[2]; //start from previous last
lastRefR[1] = (lastRefR[0] + inputSampleR)/2; //half
lastRefR[2] = inputSampleR; //full
}
if (cycleEnd == 1) {
lastRefL[0] = inputSampleL;
lastRefR[0] = inputSampleR;
}
cycle = 0; //reset
inputSampleL = lastRefL[cycle];
inputSampleR = lastRefR[cycle];
} else {
inputSampleL = lastRefL[cycle];
inputSampleR = lastRefR[cycle];
//we are going through our references now
}
switch (cycleEnd) //multi-pole average using lastRef[] variables
{
case 4:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[7])*0.5;
lastRefL[7] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[7])*0.5;
lastRefR[7] = lastRefR[8]; //continue, do not break
case 3:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[6])*0.5;
lastRefL[6] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[6])*0.5;
lastRefR[6] = lastRefR[8]; //continue, do not break
case 2:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[5])*0.5;
lastRefL[5] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[5])*0.5;
lastRefR[5] = lastRefR[8]; //continue, do not break
case 1:
break; //no further averaging
}
//begin 32 bit stereo floating point dither
int expon; frexpf((float)inputSampleL, &expon);
fpdL ^= fpdL << 13; fpdL ^= fpdL >> 17; fpdL ^= fpdL << 5;
inputSampleL += ((double(fpdL)-uint32_t(0x7fffffff)) * 5.5e-36l * pow(2,expon+62));
frexpf((float)inputSampleR, &expon);
fpdR ^= fpdR << 13; fpdR ^= fpdR >> 17; fpdR ^= fpdR << 5;
inputSampleR += ((double(fpdR)-uint32_t(0x7fffffff)) * 5.5e-36l * pow(2,expon+62));
//end 32 bit stereo floating point dither
*out1 = inputSampleL;
*out2 = inputSampleR;
in1++;
in2++;
out1++;
out2++;
}
}
void FireAmp::processDoubleReplacing(double **inputs, double **outputs, VstInt32 sampleFrames)
{
double* in1 = inputs[0];
double* in2 = inputs[1];
double* out1 = outputs[0];
double* out2 = outputs[1];
double bassfill = A;
double outputlevel = C;
double wet = D;
double overallscale = 1.0;
overallscale /= 44100.0;
overallscale *= getSampleRate();
int cycleEnd = floor(overallscale);
if (cycleEnd < 1) cycleEnd = 1;
if (cycleEnd > 4) cycleEnd = 4;
//this is going to be 2 for 88.1 or 96k, 3 for silly people, 4 for 176 or 192k
if (cycle > cycleEnd-1) cycle = cycleEnd-1; //sanity check
double startlevel = bassfill;
double samplerate = getSampleRate();
double basstrim = bassfill / 16.0;
double toneEQ = (B / samplerate)*22050.0;
double EQ = (basstrim / samplerate)*22050.0;
double bleed = outputlevel/16.0;
double bassfactor = 1.0-(basstrim*basstrim);
double BEQ = (bleed / samplerate)*22050.0;
int diagonal = (int)(0.000861678*samplerate);
if (diagonal > 127) diagonal = 127;
int side = (int)(diagonal/1.4142135623730951);
int down = (side + diagonal)/2;
//now we've got down, side and diagonal as offsets and we also use three successive samples upfront
double cutoff = (15000.0+(B*10000.0)) / getSampleRate();
if (cutoff > 0.49) cutoff = 0.49; //don't crash if run at 44.1k
if (cutoff < 0.001) cutoff = 0.001; //or if cutoff's too low
fixF[fix_freq] = fixE[fix_freq] = fixD[fix_freq] = fixC[fix_freq] = fixB[fix_freq] = fixA[fix_freq] = cutoff;
fixA[fix_reso] = 4.46570214;
fixB[fix_reso] = 1.51387132;
fixC[fix_reso] = 0.93979296;
fixD[fix_reso] = 0.70710678;
fixE[fix_reso] = 0.52972649;
fixF[fix_reso] = 0.50316379;
double K = tan(M_PI * fixA[fix_freq]); //lowpass
double norm = 1.0 / (1.0 + K / fixA[fix_reso] + K * K);
fixA[fix_a0] = K * K * norm;
fixA[fix_a1] = 2.0 * fixA[fix_a0];
fixA[fix_a2] = fixA[fix_a0];
fixA[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixA[fix_b2] = (1.0 - K / fixA[fix_reso] + K * K) * norm;
K = tan(M_PI * fixB[fix_freq]);
norm = 1.0 / (1.0 + K / fixB[fix_reso] + K * K);
fixB[fix_a0] = K * K * norm;
fixB[fix_a1] = 2.0 * fixB[fix_a0];
fixB[fix_a2] = fixB[fix_a0];
fixB[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixB[fix_b2] = (1.0 - K / fixB[fix_reso] + K * K) * norm;
K = tan(M_PI * fixC[fix_freq]);
norm = 1.0 / (1.0 + K / fixC[fix_reso] + K * K);
fixC[fix_a0] = K * K * norm;
fixC[fix_a1] = 2.0 * fixC[fix_a0];
fixC[fix_a2] = fixC[fix_a0];
fixC[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixC[fix_b2] = (1.0 - K / fixC[fix_reso] + K * K) * norm;
K = tan(M_PI * fixD[fix_freq]);
norm = 1.0 / (1.0 + K / fixD[fix_reso] + K * K);
fixD[fix_a0] = K * K * norm;
fixD[fix_a1] = 2.0 * fixD[fix_a0];
fixD[fix_a2] = fixD[fix_a0];
fixD[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixD[fix_b2] = (1.0 - K / fixD[fix_reso] + K * K) * norm;
K = tan(M_PI * fixE[fix_freq]);
norm = 1.0 / (1.0 + K / fixE[fix_reso] + K * K);
fixE[fix_a0] = K * K * norm;
fixE[fix_a1] = 2.0 * fixE[fix_a0];
fixE[fix_a2] = fixE[fix_a0];
fixE[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixE[fix_b2] = (1.0 - K / fixE[fix_reso] + K * K) * norm;
K = tan(M_PI * fixF[fix_freq]);
norm = 1.0 / (1.0 + K / fixF[fix_reso] + K * K);
fixF[fix_a0] = K * K * norm;
fixF[fix_a1] = 2.0 * fixF[fix_a0];
fixF[fix_a2] = fixF[fix_a0];
fixF[fix_b1] = 2.0 * (K * K - 1.0) * norm;
fixF[fix_b2] = (1.0 - K / fixF[fix_reso] + K * K) * norm;
while (--sampleFrames >= 0)
{
double inputSampleL = *in1;
double inputSampleR = *in2;
if (fabs(inputSampleL)<1.18e-23) inputSampleL = fpdL * 1.18e-17;
if (fabs(inputSampleR)<1.18e-23) inputSampleR = fpdR * 1.18e-17;
double drySampleL = inputSampleL;
double drySampleR = inputSampleR;
double outSample = (inputSampleL * fixA[fix_a0]) + fixA[fix_sL1];
fixA[fix_sL1] = (inputSampleL * fixA[fix_a1]) - (outSample * fixA[fix_b1]) + fixA[fix_sL2];
fixA[fix_sL2] = (inputSampleL * fixA[fix_a2]) - (outSample * fixA[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixA[fix_a0]) + fixA[fix_sR1];
fixA[fix_sR1] = (inputSampleR * fixA[fix_a1]) - (outSample * fixA[fix_b1]) + fixA[fix_sR2];
fixA[fix_sR2] = (inputSampleR * fixA[fix_a2]) - (outSample * fixA[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
if (inputSampleL > 1.0) inputSampleL = 1.0;
if (inputSampleL < -1.0) inputSampleL = -1.0;
double basscutL = 0.98;
//we're going to be shifting this as the stages progress
double inputlevelL = startlevel;
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleAL = (iirSampleAL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleAL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
double bridgerectifier = (smoothAL + inputSampleL);
smoothAL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleBL = (iirSampleBL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleBL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothBL + inputSampleL);
smoothBL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
if (inputSampleR > 1.0) inputSampleR = 1.0;
if (inputSampleR < -1.0) inputSampleR = -1.0;
double basscutR = 0.98;
//we're going to be shifting this as the stages progress
double inputlevelR = startlevel;
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleAR = (iirSampleAR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleAR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothAR + inputSampleR);
smoothAR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleBR = (iirSampleBR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleBR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothBR + inputSampleR);
smoothBR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixB[fix_a0]) + fixB[fix_sL1];
fixB[fix_sL1] = (inputSampleL * fixB[fix_a1]) - (outSample * fixB[fix_b1]) + fixB[fix_sL2];
fixB[fix_sL2] = (inputSampleL * fixB[fix_a2]) - (outSample * fixB[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixB[fix_a0]) + fixB[fix_sR1];
fixB[fix_sR1] = (inputSampleR * fixB[fix_a1]) - (outSample * fixB[fix_b1]) + fixB[fix_sR2];
fixB[fix_sR2] = (inputSampleR * fixB[fix_a2]) - (outSample * fixB[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleCL = (iirSampleCL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleCL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothCL + inputSampleL);
smoothCL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleDL = (iirSampleDL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleDL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654) );
//overdrive
bridgerectifier = (smoothDL + inputSampleL);
smoothDL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleCR = (iirSampleCR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleCR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothCR + inputSampleR);
smoothCR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleDR = (iirSampleDR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleDR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654) );
//overdrive
bridgerectifier = (smoothDR + inputSampleR);
smoothDR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixC[fix_a0]) + fixC[fix_sL1];
fixC[fix_sL1] = (inputSampleL * fixC[fix_a1]) - (outSample * fixC[fix_b1]) + fixC[fix_sL2];
fixC[fix_sL2] = (inputSampleL * fixC[fix_a2]) - (outSample * fixC[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixC[fix_a0]) + fixC[fix_sR1];
fixC[fix_sR1] = (inputSampleR * fixC[fix_a1]) - (outSample * fixC[fix_b1]) + fixC[fix_sR2];
fixC[fix_sR2] = (inputSampleR * fixC[fix_a2]) - (outSample * fixC[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleEL = (iirSampleEL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleEL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothEL + inputSampleL);
smoothEL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleFL = (iirSampleFL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleFL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothFL + inputSampleL);
smoothFL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleER = (iirSampleER * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleER*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothER + inputSampleR);
smoothER = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleFR = (iirSampleFR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleFR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothFR + inputSampleR);
smoothFR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixD[fix_a0]) + fixD[fix_sL1];
fixD[fix_sL1] = (inputSampleL * fixD[fix_a1]) - (outSample * fixD[fix_b1]) + fixD[fix_sL2];
fixD[fix_sL2] = (inputSampleL * fixD[fix_a2]) - (outSample * fixD[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixD[fix_a0]) + fixD[fix_sR1];
fixD[fix_sR1] = (inputSampleR * fixD[fix_a1]) - (outSample * fixD[fix_b1]) + fixD[fix_sR2];
fixD[fix_sR2] = (inputSampleR * fixD[fix_a2]) - (outSample * fixD[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleGL = (iirSampleGL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleGL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothGL + inputSampleL);
smoothGL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleHL = (iirSampleHL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleHL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothHL + inputSampleL);
smoothHL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleGR = (iirSampleGR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleGR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothGR + inputSampleR);
smoothGR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleHR = (iirSampleHR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleHR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothHR + inputSampleR);
smoothHR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixE[fix_a0]) + fixE[fix_sL1];
fixE[fix_sL1] = (inputSampleL * fixE[fix_a1]) - (outSample * fixE[fix_b1]) + fixE[fix_sL2];
fixE[fix_sL2] = (inputSampleL * fixE[fix_a2]) - (outSample * fixE[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixE[fix_a0]) + fixE[fix_sR1];
fixE[fix_sR1] = (inputSampleR * fixE[fix_a1]) - (outSample * fixE[fix_b1]) + fixE[fix_sR2];
fixE[fix_sR2] = (inputSampleR * fixE[fix_a2]) - (outSample * fixE[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleIL = (iirSampleIL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleIL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothIL + inputSampleL);
smoothIL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleJL = (iirSampleJL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleJL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothJL + inputSampleL);
smoothJL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleIR = (iirSampleIR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleIR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothIR + inputSampleR);
smoothIR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleJR = (iirSampleJR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleJR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothJR + inputSampleR);
smoothJR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
outSample = (inputSampleL * fixF[fix_a0]) + fixF[fix_sL1];
fixF[fix_sL1] = (inputSampleL * fixF[fix_a1]) - (outSample * fixF[fix_b1]) + fixF[fix_sL2];
fixF[fix_sL2] = (inputSampleL * fixF[fix_a2]) - (outSample * fixF[fix_b2]);
inputSampleL = outSample; //fixed biquad filtering ultrasonics
outSample = (inputSampleR * fixF[fix_a0]) + fixF[fix_sR1];
fixF[fix_sR1] = (inputSampleR * fixF[fix_a1]) - (outSample * fixF[fix_b1]) + fixF[fix_sR2];
fixF[fix_sR2] = (inputSampleR * fixF[fix_a2]) - (outSample * fixF[fix_b2]);
inputSampleR = outSample; //fixed biquad filtering ultrasonics
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleKL = (iirSampleKL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleKL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothKL + inputSampleL);
smoothKL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleL *= inputlevelL;
inputlevelL = ((inputlevelL * 7.0)+1.0)/8.0;
iirSampleLL = (iirSampleLL * (1.0 - EQ)) + (inputSampleL * EQ);
basscutL *= bassfactor;
inputSampleL = inputSampleL - (iirSampleLL*basscutL);
//highpass
inputSampleL -= (inputSampleL * (fabs(inputSampleL) * 0.654) * (fabs(inputSampleL) * 0.654));
//overdrive
bridgerectifier = (smoothLL + inputSampleL);
smoothLL = inputSampleL;
inputSampleL = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleKR = (iirSampleKR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleKR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothKR + inputSampleR);
smoothKR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
inputSampleR *= inputlevelR;
inputlevelR = ((inputlevelR * 7.0)+1.0)/8.0;
iirSampleLR = (iirSampleLR * (1.0 - EQ)) + (inputSampleR * EQ);
basscutR *= bassfactor;
inputSampleR = inputSampleR - (iirSampleLR*basscutR);
//highpass
inputSampleR -= (inputSampleR * (fabs(inputSampleR) * 0.654) * (fabs(inputSampleR) * 0.654));
//overdrive
bridgerectifier = (smoothLR + inputSampleR);
smoothLR = inputSampleR;
inputSampleR = bridgerectifier;
//two-sample averaging lowpass
iirLowpassL = (iirLowpassL * (1.0 - toneEQ)) + (inputSampleL * toneEQ);
inputSampleL = iirLowpassL;
//lowpass. The only one of this type.
iirLowpassR = (iirLowpassR * (1.0 - toneEQ)) + (inputSampleR * toneEQ);
inputSampleR = iirLowpassR;
//lowpass. The only one of this type.
iirSpkAL = (iirSpkAL * (1.0 - BEQ)) + (inputSampleL * BEQ);
//extra lowpass for 4*12" speakers
iirSpkAR = (iirSpkAR * (1.0 - BEQ)) + (inputSampleR * BEQ);
//extra lowpass for 4*12" speakers
if (count < 0 || count > 128) {count = 128;}
double resultBL = 0.0;
double resultBR = 0.0;
if (flip)
{
OddL[count+128] = OddL[count] = iirSpkAL;
resultBL = (OddL[count+down] + OddL[count+side] + OddL[count+diagonal]);
OddR[count+128] = OddR[count] = iirSpkAR;
resultBR = (OddR[count+down] + OddR[count+side] + OddR[count+diagonal]);
}
else
{
EvenL[count+128] = EvenL[count] = iirSpkAL;
resultBL = (EvenL[count+down] + EvenL[count+side] + EvenL[count+diagonal]);
EvenR[count+128] = EvenR[count] = iirSpkAR;
resultBR = (EvenR[count+down] + EvenR[count+side] + EvenR[count+diagonal]);
}
count--;
iirSpkBL = (iirSpkBL * (1.0 - BEQ)) + (resultBL * BEQ);
inputSampleL += (iirSpkBL * bleed);
//extra lowpass for 4*12" speakers
iirSpkBR = (iirSpkBR * (1.0 - BEQ)) + (resultBR * BEQ);
inputSampleR += (iirSpkBR * bleed);
//extra lowpass for 4*12" speakers
bridgerectifier = fabs(inputSampleL*outputlevel);
if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
bridgerectifier = sin(bridgerectifier);
if (inputSampleL > 0) inputSampleL = bridgerectifier;
else inputSampleL = -bridgerectifier;
bridgerectifier = fabs(inputSampleR*outputlevel);
if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
bridgerectifier = sin(bridgerectifier);
if (inputSampleR > 0) inputSampleR = bridgerectifier;
else inputSampleR = -bridgerectifier;
iirSubL = (iirSubL * (1.0 - BEQ)) + (inputSampleL * BEQ);
inputSampleL += (iirSubL * bassfill * outputlevel);
iirSubR = (iirSubR * (1.0 - BEQ)) + (inputSampleR * BEQ);
inputSampleR += (iirSubR * bassfill * outputlevel);
double randy = ((double(fpdL)/UINT32_MAX)*0.053);
inputSampleL = ((inputSampleL*(1.0-randy))+(storeSampleL*randy))*outputlevel;
storeSampleL = inputSampleL;
randy = ((double(fpdR)/UINT32_MAX)*0.053);
inputSampleR = ((inputSampleR*(1.0-randy))+(storeSampleR*randy))*outputlevel;
storeSampleR = inputSampleR;
flip = !flip;
if (wet !=1.0) {
inputSampleL = (inputSampleL * wet) + (drySampleL * (1.0-wet));
inputSampleR = (inputSampleR * wet) + (drySampleR * (1.0-wet));
}
//Dry/Wet control, defaults to the last slider
//amp
cycle++;
if (cycle == cycleEnd) {
double temp = (inputSampleL + smoothCabAL)/3.0;
smoothCabAL = inputSampleL;
inputSampleL = temp;
bL[84] = bL[83]; bL[83] = bL[82]; bL[82] = bL[81]; bL[81] = bL[80]; bL[80] = bL[79];
bL[79] = bL[78]; bL[78] = bL[77]; bL[77] = bL[76]; bL[76] = bL[75]; bL[75] = bL[74]; bL[74] = bL[73]; bL[73] = bL[72]; bL[72] = bL[71];
bL[71] = bL[70]; bL[70] = bL[69]; bL[69] = bL[68]; bL[68] = bL[67]; bL[67] = bL[66]; bL[66] = bL[65]; bL[65] = bL[64]; bL[64] = bL[63];
bL[63] = bL[62]; bL[62] = bL[61]; bL[61] = bL[60]; bL[60] = bL[59]; bL[59] = bL[58]; bL[58] = bL[57]; bL[57] = bL[56]; bL[56] = bL[55];
bL[55] = bL[54]; bL[54] = bL[53]; bL[53] = bL[52]; bL[52] = bL[51]; bL[51] = bL[50]; bL[50] = bL[49]; bL[49] = bL[48]; bL[48] = bL[47];
bL[47] = bL[46]; bL[46] = bL[45]; bL[45] = bL[44]; bL[44] = bL[43]; bL[43] = bL[42]; bL[42] = bL[41]; bL[41] = bL[40]; bL[40] = bL[39];
bL[39] = bL[38]; bL[38] = bL[37]; bL[37] = bL[36]; bL[36] = bL[35]; bL[35] = bL[34]; bL[34] = bL[33]; bL[33] = bL[32]; bL[32] = bL[31];
bL[31] = bL[30]; bL[30] = bL[29]; bL[29] = bL[28]; bL[28] = bL[27]; bL[27] = bL[26]; bL[26] = bL[25]; bL[25] = bL[24]; bL[24] = bL[23];
bL[23] = bL[22]; bL[22] = bL[21]; bL[21] = bL[20]; bL[20] = bL[19]; bL[19] = bL[18]; bL[18] = bL[17]; bL[17] = bL[16]; bL[16] = bL[15];
bL[15] = bL[14]; bL[14] = bL[13]; bL[13] = bL[12]; bL[12] = bL[11]; bL[11] = bL[10]; bL[10] = bL[9]; bL[9] = bL[8]; bL[8] = bL[7];
bL[7] = bL[6]; bL[6] = bL[5]; bL[5] = bL[4]; bL[4] = bL[3]; bL[3] = bL[2]; bL[2] = bL[1]; bL[1] = bL[0]; bL[0] = inputSampleL;
inputSampleL += (bL[1] * (1.31698250313308396 - (0.08140616497621633*fabs(bL[1]))));
inputSampleL += (bL[2] * (1.47229016949915326 - (0.27680278993637253*fabs(bL[2]))));
inputSampleL += (bL[3] * (1.30410109086044956 - (0.35629113432046489*fabs(bL[3]))));
inputSampleL += (bL[4] * (0.81766210474551260 - (0.26808782337659753*fabs(bL[4]))));
inputSampleL += (bL[5] * (0.19868872545506663 - (0.11105517193919669*fabs(bL[5]))));
inputSampleL -= (bL[6] * (0.39115909132567039 - (0.12630622002682679*fabs(bL[6]))));
inputSampleL -= (bL[7] * (0.76881891559343574 - (0.40879849500403143*fabs(bL[7]))));
inputSampleL -= (bL[8] * (0.87146861782680340 - (0.59529560488000599*fabs(bL[8]))));
inputSampleL -= (bL[9] * (0.79504575932563670 - (0.60877047551611796*fabs(bL[9]))));
inputSampleL -= (bL[10] * (0.61653017622406314 - (0.47662851438557335*fabs(bL[10]))));
inputSampleL -= (bL[11] * (0.40718195794382067 - (0.24955839378539713*fabs(bL[11]))));
inputSampleL -= (bL[12] * (0.31794900040616203 - (0.04169792259600613*fabs(bL[12]))));
inputSampleL -= (bL[13] * (0.41075032540217843 + (0.00368483996076280*fabs(bL[13]))));
inputSampleL -= (bL[14] * (0.56901352922170667 - (0.11027360805893105*fabs(bL[14]))));
inputSampleL -= (bL[15] * (0.62443222391889264 - (0.22198075154245228*fabs(bL[15]))));
inputSampleL -= (bL[16] * (0.53462856723129204 - (0.22933544545324852*fabs(bL[16]))));
inputSampleL -= (bL[17] * (0.34441703361995046 - (0.12956809502269492*fabs(bL[17]))));
inputSampleL -= (bL[18] * (0.13947052337867882 + (0.00339775055962799*fabs(bL[18]))));
inputSampleL += (bL[19] * (0.03771252648928484 - (0.10863931549251718*fabs(bL[19]))));
inputSampleL += (bL[20] * (0.18280210770271693 - (0.17413646599296417*fabs(bL[20]))));
inputSampleL += (bL[21] * (0.24621986701761467 - (0.14547053270435095*fabs(bL[21]))));
inputSampleL += (bL[22] * (0.22347075142737360 - (0.02493869490104031*fabs(bL[22]))));
inputSampleL += (bL[23] * (0.14346348482123716 + (0.11284054747963246*fabs(bL[23]))));
inputSampleL += (bL[24] * (0.00834364862916028 + (0.24284684053733926*fabs(bL[24]))));
inputSampleL -= (bL[25] * (0.11559740296078347 - (0.32623054435304538*fabs(bL[25]))));
inputSampleL -= (bL[26] * (0.18067604561283060 - (0.32311481551122478*fabs(bL[26]))));
inputSampleL -= (bL[27] * (0.22927997789035612 - (0.26991539052832925*fabs(bL[27]))));
inputSampleL -= (bL[28] * (0.28487666578669446 - (0.22437227250279349*fabs(bL[28]))));
inputSampleL -= (bL[29] * (0.31992973037153838 - (0.15289876100963865*fabs(bL[29]))));
inputSampleL -= (bL[30] * (0.35174606303520733 - (0.05656293023086628*fabs(bL[30]))));
inputSampleL -= (bL[31] * (0.36894898011375254 + (0.04333925421463558*fabs(bL[31]))));
inputSampleL -= (bL[32] * (0.32567576055307507 + (0.14594589410921388*fabs(bL[32]))));
inputSampleL -= (bL[33] * (0.27440135050585784 + (0.15529667398122521*fabs(bL[33]))));
inputSampleL -= (bL[34] * (0.21998973785078091 + (0.05083553737157104*fabs(bL[34]))));
inputSampleL -= (bL[35] * (0.10323624876862457 - (0.04651829594199963*fabs(bL[35]))));
inputSampleL += (bL[36] * (0.02091603687851074 + (0.12000046818439322*fabs(bL[36]))));
inputSampleL += (bL[37] * (0.11344930914138468 + (0.17697142512225839*fabs(bL[37]))));
inputSampleL += (bL[38] * (0.22766779627643968 + (0.13645102964003858*fabs(bL[38]))));
inputSampleL += (bL[39] * (0.38378309953638229 - (0.01997653307333791*fabs(bL[39]))));
inputSampleL += (bL[40] * (0.52789400804568076 - (0.21409137428422448*fabs(bL[40]))));
inputSampleL += (bL[41] * (0.55444630296938280 - (0.32331980931576626*fabs(bL[41]))));
inputSampleL += (bL[42] * (0.42333237669264601 - (0.26855847463044280*fabs(bL[42]))));
inputSampleL += (bL[43] * (0.21942831522035078 - (0.12051365248820624*fabs(bL[43]))));
inputSampleL -= (bL[44] * (0.00584169427830633 - (0.03706970171280329*fabs(bL[44]))));
inputSampleL -= (bL[45] * (0.24279799124660351 - (0.17296440491477982*fabs(bL[45]))));
inputSampleL -= (bL[46] * (0.40173760787507085 - (0.21717989835163351*fabs(bL[46]))));
inputSampleL -= (bL[47] * (0.43930035724188155 - (0.16425928481378199*fabs(bL[47]))));
inputSampleL -= (bL[48] * (0.41067765934041811 - (0.10390115786636855*fabs(bL[48]))));
inputSampleL -= (bL[49] * (0.34409235547165967 - (0.07268159377411920*fabs(bL[49]))));
inputSampleL -= (bL[50] * (0.26542883122568151 - (0.05483457497365785*fabs(bL[50]))));
inputSampleL -= (bL[51] * (0.22024754776138800 - (0.06484897950087598*fabs(bL[51]))));
inputSampleL -= (bL[52] * (0.20394367993632415 - (0.08746309731952180*fabs(bL[52]))));
inputSampleL -= (bL[53] * (0.17565242431124092 - (0.07611309538078760*fabs(bL[53]))));
inputSampleL -= (bL[54] * (0.10116623231246825 - (0.00642818706295112*fabs(bL[54]))));
inputSampleL -= (bL[55] * (0.00782648272053632 + (0.08004141267685004*fabs(bL[55]))));
inputSampleL += (bL[56] * (0.05059046006747323 - (0.12436676387548490*fabs(bL[56]))));
inputSampleL += (bL[57] * (0.06241531553254467 - (0.11530779547021434*fabs(bL[57]))));
inputSampleL += (bL[58] * (0.04952694587101836 - (0.08340945324333944*fabs(bL[58]))));
inputSampleL += (bL[59] * (0.00843873294401687 - (0.03279659052562903*fabs(bL[59]))));
inputSampleL -= (bL[60] * (0.05161338949440241 - (0.03428181149163798*fabs(bL[60]))));
inputSampleL -= (bL[61] * (0.08165520146902012 - (0.08196746092283110*fabs(bL[61]))));
inputSampleL -= (bL[62] * (0.06639532849935320 - (0.09797462781896329*fabs(bL[62]))));
inputSampleL -= (bL[63] * (0.02953430910661621 - (0.09175612938515763*fabs(bL[63]))));
inputSampleL += (bL[64] * (0.00741058547442938 + (0.05442091048731967*fabs(bL[64]))));
inputSampleL += (bL[65] * (0.01832866125391727 + (0.00306243693643687*fabs(bL[65]))));
inputSampleL += (bL[66] * (0.00526964230373573 - (0.04364102661136410*fabs(bL[66]))));
inputSampleL -= (bL[67] * (0.00300984373848200 + (0.09742737841278880*fabs(bL[67]))));
inputSampleL -= (bL[68] * (0.00413616769576694 + (0.14380661694523073*fabs(bL[68]))));
inputSampleL -= (bL[69] * (0.00588769034931419 + (0.16012843578892538*fabs(bL[69]))));
inputSampleL -= (bL[70] * (0.00688588239450581 + (0.14074464279305798*fabs(bL[70]))));
inputSampleL -= (bL[71] * (0.02277307992926315 + (0.07914752191801366*fabs(bL[71]))));
inputSampleL -= (bL[72] * (0.04627166091180877 - (0.00192787268067208*fabs(bL[72]))));
inputSampleL -= (bL[73] * (0.05562045897455786 - (0.05932868727665747*fabs(bL[73]))));
inputSampleL -= (bL[74] * (0.05134243784922165 - (0.08245334798868090*fabs(bL[74]))));
inputSampleL -= (bL[75] * (0.04719409472239919 - (0.07498680629253825*fabs(bL[75]))));
inputSampleL -= (bL[76] * (0.05889738914266415 - (0.06116127018043697*fabs(bL[76]))));
inputSampleL -= (bL[77] * (0.09428363535111127 - (0.06535868867863834*fabs(bL[77]))));
inputSampleL -= (bL[78] * (0.15181756953225126 - (0.08982979655234427*fabs(bL[78]))));
inputSampleL -= (bL[79] * (0.20878969456036670 - (0.10761070891499538*fabs(bL[79]))));
inputSampleL -= (bL[80] * (0.22647885581813790 - (0.08462542510349125*fabs(bL[80]))));
inputSampleL -= (bL[81] * (0.19723482443646323 - (0.02665160920736287*fabs(bL[81]))));
inputSampleL -= (bL[82] * (0.16441643451155163 + (0.02314691954338197*fabs(bL[82]))));
inputSampleL -= (bL[83] * (0.15201914054931515 + (0.04424903493886839*fabs(bL[83]))));
inputSampleL -= (bL[84] * (0.15454370641307855 + (0.04223203797913008*fabs(bL[84]))));
temp = (inputSampleL + smoothCabBL)/3.0;
smoothCabBL = inputSampleL;
inputSampleL = temp/4.0;
randy = ((double(fpdL)/UINT32_MAX)*0.057);
drySampleL = ((((inputSampleL*(1-randy))+(lastCabSampleL*randy))*wet)+(drySampleL*(1.0-wet)))*outputlevel;
lastCabSampleL = inputSampleL;
inputSampleL = drySampleL; //cab L
temp = (inputSampleR + smoothCabAR)/3.0;
smoothCabAR = inputSampleR;
inputSampleR = temp;
bR[84] = bR[83]; bR[83] = bR[82]; bR[82] = bR[81]; bR[81] = bR[80]; bR[80] = bR[79];
bR[79] = bR[78]; bR[78] = bR[77]; bR[77] = bR[76]; bR[76] = bR[75]; bR[75] = bR[74]; bR[74] = bR[73]; bR[73] = bR[72]; bR[72] = bR[71];
bR[71] = bR[70]; bR[70] = bR[69]; bR[69] = bR[68]; bR[68] = bR[67]; bR[67] = bR[66]; bR[66] = bR[65]; bR[65] = bR[64]; bR[64] = bR[63];
bR[63] = bR[62]; bR[62] = bR[61]; bR[61] = bR[60]; bR[60] = bR[59]; bR[59] = bR[58]; bR[58] = bR[57]; bR[57] = bR[56]; bR[56] = bR[55];
bR[55] = bR[54]; bR[54] = bR[53]; bR[53] = bR[52]; bR[52] = bR[51]; bR[51] = bR[50]; bR[50] = bR[49]; bR[49] = bR[48]; bR[48] = bR[47];
bR[47] = bR[46]; bR[46] = bR[45]; bR[45] = bR[44]; bR[44] = bR[43]; bR[43] = bR[42]; bR[42] = bR[41]; bR[41] = bR[40]; bR[40] = bR[39];
bR[39] = bR[38]; bR[38] = bR[37]; bR[37] = bR[36]; bR[36] = bR[35]; bR[35] = bR[34]; bR[34] = bR[33]; bR[33] = bR[32]; bR[32] = bR[31];
bR[31] = bR[30]; bR[30] = bR[29]; bR[29] = bR[28]; bR[28] = bR[27]; bR[27] = bR[26]; bR[26] = bR[25]; bR[25] = bR[24]; bR[24] = bR[23];
bR[23] = bR[22]; bR[22] = bR[21]; bR[21] = bR[20]; bR[20] = bR[19]; bR[19] = bR[18]; bR[18] = bR[17]; bR[17] = bR[16]; bR[16] = bR[15];
bR[15] = bR[14]; bR[14] = bR[13]; bR[13] = bR[12]; bR[12] = bR[11]; bR[11] = bR[10]; bR[10] = bR[9]; bR[9] = bR[8]; bR[8] = bR[7];
bR[7] = bR[6]; bR[6] = bR[5]; bR[5] = bR[4]; bR[4] = bR[3]; bR[3] = bR[2]; bR[2] = bR[1]; bR[1] = bR[0]; bR[0] = inputSampleR;
inputSampleR += (bR[1] * (1.31698250313308396 - (0.08140616497621633*fabs(bR[1]))));
inputSampleR += (bR[2] * (1.47229016949915326 - (0.27680278993637253*fabs(bR[2]))));
inputSampleR += (bR[3] * (1.30410109086044956 - (0.35629113432046489*fabs(bR[3]))));
inputSampleR += (bR[4] * (0.81766210474551260 - (0.26808782337659753*fabs(bR[4]))));
inputSampleR += (bR[5] * (0.19868872545506663 - (0.11105517193919669*fabs(bR[5]))));
inputSampleR -= (bR[6] * (0.39115909132567039 - (0.12630622002682679*fabs(bR[6]))));
inputSampleR -= (bR[7] * (0.76881891559343574 - (0.40879849500403143*fabs(bR[7]))));
inputSampleR -= (bR[8] * (0.87146861782680340 - (0.59529560488000599*fabs(bR[8]))));
inputSampleR -= (bR[9] * (0.79504575932563670 - (0.60877047551611796*fabs(bR[9]))));
inputSampleR -= (bR[10] * (0.61653017622406314 - (0.47662851438557335*fabs(bR[10]))));
inputSampleR -= (bR[11] * (0.40718195794382067 - (0.24955839378539713*fabs(bR[11]))));
inputSampleR -= (bR[12] * (0.31794900040616203 - (0.04169792259600613*fabs(bR[12]))));
inputSampleR -= (bR[13] * (0.41075032540217843 + (0.00368483996076280*fabs(bR[13]))));
inputSampleR -= (bR[14] * (0.56901352922170667 - (0.11027360805893105*fabs(bR[14]))));
inputSampleR -= (bR[15] * (0.62443222391889264 - (0.22198075154245228*fabs(bR[15]))));
inputSampleR -= (bR[16] * (0.53462856723129204 - (0.22933544545324852*fabs(bR[16]))));
inputSampleR -= (bR[17] * (0.34441703361995046 - (0.12956809502269492*fabs(bR[17]))));
inputSampleR -= (bR[18] * (0.13947052337867882 + (0.00339775055962799*fabs(bR[18]))));
inputSampleR += (bR[19] * (0.03771252648928484 - (0.10863931549251718*fabs(bR[19]))));
inputSampleR += (bR[20] * (0.18280210770271693 - (0.17413646599296417*fabs(bR[20]))));
inputSampleR += (bR[21] * (0.24621986701761467 - (0.14547053270435095*fabs(bR[21]))));
inputSampleR += (bR[22] * (0.22347075142737360 - (0.02493869490104031*fabs(bR[22]))));
inputSampleR += (bR[23] * (0.14346348482123716 + (0.11284054747963246*fabs(bR[23]))));
inputSampleR += (bR[24] * (0.00834364862916028 + (0.24284684053733926*fabs(bR[24]))));
inputSampleR -= (bR[25] * (0.11559740296078347 - (0.32623054435304538*fabs(bR[25]))));
inputSampleR -= (bR[26] * (0.18067604561283060 - (0.32311481551122478*fabs(bR[26]))));
inputSampleR -= (bR[27] * (0.22927997789035612 - (0.26991539052832925*fabs(bR[27]))));
inputSampleR -= (bR[28] * (0.28487666578669446 - (0.22437227250279349*fabs(bR[28]))));
inputSampleR -= (bR[29] * (0.31992973037153838 - (0.15289876100963865*fabs(bR[29]))));
inputSampleR -= (bR[30] * (0.35174606303520733 - (0.05656293023086628*fabs(bR[30]))));
inputSampleR -= (bR[31] * (0.36894898011375254 + (0.04333925421463558*fabs(bR[31]))));
inputSampleR -= (bR[32] * (0.32567576055307507 + (0.14594589410921388*fabs(bR[32]))));
inputSampleR -= (bR[33] * (0.27440135050585784 + (0.15529667398122521*fabs(bR[33]))));
inputSampleR -= (bR[34] * (0.21998973785078091 + (0.05083553737157104*fabs(bR[34]))));
inputSampleR -= (bR[35] * (0.10323624876862457 - (0.04651829594199963*fabs(bR[35]))));
inputSampleR += (bR[36] * (0.02091603687851074 + (0.12000046818439322*fabs(bR[36]))));
inputSampleR += (bR[37] * (0.11344930914138468 + (0.17697142512225839*fabs(bR[37]))));
inputSampleR += (bR[38] * (0.22766779627643968 + (0.13645102964003858*fabs(bR[38]))));
inputSampleR += (bR[39] * (0.38378309953638229 - (0.01997653307333791*fabs(bR[39]))));
inputSampleR += (bR[40] * (0.52789400804568076 - (0.21409137428422448*fabs(bR[40]))));
inputSampleR += (bR[41] * (0.55444630296938280 - (0.32331980931576626*fabs(bR[41]))));
inputSampleR += (bR[42] * (0.42333237669264601 - (0.26855847463044280*fabs(bR[42]))));
inputSampleR += (bR[43] * (0.21942831522035078 - (0.12051365248820624*fabs(bR[43]))));
inputSampleR -= (bR[44] * (0.00584169427830633 - (0.03706970171280329*fabs(bR[44]))));
inputSampleR -= (bR[45] * (0.24279799124660351 - (0.17296440491477982*fabs(bR[45]))));
inputSampleR -= (bR[46] * (0.40173760787507085 - (0.21717989835163351*fabs(bR[46]))));
inputSampleR -= (bR[47] * (0.43930035724188155 - (0.16425928481378199*fabs(bR[47]))));
inputSampleR -= (bR[48] * (0.41067765934041811 - (0.10390115786636855*fabs(bR[48]))));
inputSampleR -= (bR[49] * (0.34409235547165967 - (0.07268159377411920*fabs(bR[49]))));
inputSampleR -= (bR[50] * (0.26542883122568151 - (0.05483457497365785*fabs(bR[50]))));
inputSampleR -= (bR[51] * (0.22024754776138800 - (0.06484897950087598*fabs(bR[51]))));
inputSampleR -= (bR[52] * (0.20394367993632415 - (0.08746309731952180*fabs(bR[52]))));
inputSampleR -= (bR[53] * (0.17565242431124092 - (0.07611309538078760*fabs(bR[53]))));
inputSampleR -= (bR[54] * (0.10116623231246825 - (0.00642818706295112*fabs(bR[54]))));
inputSampleR -= (bR[55] * (0.00782648272053632 + (0.08004141267685004*fabs(bR[55]))));
inputSampleR += (bR[56] * (0.05059046006747323 - (0.12436676387548490*fabs(bR[56]))));
inputSampleR += (bR[57] * (0.06241531553254467 - (0.11530779547021434*fabs(bR[57]))));
inputSampleR += (bR[58] * (0.04952694587101836 - (0.08340945324333944*fabs(bR[58]))));
inputSampleR += (bR[59] * (0.00843873294401687 - (0.03279659052562903*fabs(bR[59]))));
inputSampleR -= (bR[60] * (0.05161338949440241 - (0.03428181149163798*fabs(bR[60]))));
inputSampleR -= (bR[61] * (0.08165520146902012 - (0.08196746092283110*fabs(bR[61]))));
inputSampleR -= (bR[62] * (0.06639532849935320 - (0.09797462781896329*fabs(bR[62]))));
inputSampleR -= (bR[63] * (0.02953430910661621 - (0.09175612938515763*fabs(bR[63]))));
inputSampleR += (bR[64] * (0.00741058547442938 + (0.05442091048731967*fabs(bR[64]))));
inputSampleR += (bR[65] * (0.01832866125391727 + (0.00306243693643687*fabs(bR[65]))));
inputSampleR += (bR[66] * (0.00526964230373573 - (0.04364102661136410*fabs(bR[66]))));
inputSampleR -= (bR[67] * (0.00300984373848200 + (0.09742737841278880*fabs(bR[67]))));
inputSampleR -= (bR[68] * (0.00413616769576694 + (0.14380661694523073*fabs(bR[68]))));
inputSampleR -= (bR[69] * (0.00588769034931419 + (0.16012843578892538*fabs(bR[69]))));
inputSampleR -= (bR[70] * (0.00688588239450581 + (0.14074464279305798*fabs(bR[70]))));
inputSampleR -= (bR[71] * (0.02277307992926315 + (0.07914752191801366*fabs(bR[71]))));
inputSampleR -= (bR[72] * (0.04627166091180877 - (0.00192787268067208*fabs(bR[72]))));
inputSampleR -= (bR[73] * (0.05562045897455786 - (0.05932868727665747*fabs(bR[73]))));
inputSampleR -= (bR[74] * (0.05134243784922165 - (0.08245334798868090*fabs(bR[74]))));
inputSampleR -= (bR[75] * (0.04719409472239919 - (0.07498680629253825*fabs(bR[75]))));
inputSampleR -= (bR[76] * (0.05889738914266415 - (0.06116127018043697*fabs(bR[76]))));
inputSampleR -= (bR[77] * (0.09428363535111127 - (0.06535868867863834*fabs(bR[77]))));
inputSampleR -= (bR[78] * (0.15181756953225126 - (0.08982979655234427*fabs(bR[78]))));
inputSampleR -= (bR[79] * (0.20878969456036670 - (0.10761070891499538*fabs(bR[79]))));
inputSampleR -= (bR[80] * (0.22647885581813790 - (0.08462542510349125*fabs(bR[80]))));
inputSampleR -= (bR[81] * (0.19723482443646323 - (0.02665160920736287*fabs(bR[81]))));
inputSampleR -= (bR[82] * (0.16441643451155163 + (0.02314691954338197*fabs(bR[82]))));
inputSampleR -= (bR[83] * (0.15201914054931515 + (0.04424903493886839*fabs(bR[83]))));
inputSampleR -= (bR[84] * (0.15454370641307855 + (0.04223203797913008*fabs(bR[84]))));
temp = (inputSampleR + smoothCabBR)/3.0;
smoothCabBR = inputSampleR;
inputSampleR = temp/4.0;
randy = ((double(fpdR)/UINT32_MAX)*0.057);
drySampleR = ((((inputSampleR*(1.0-randy))+(lastCabSampleR*randy))*wet)+(drySampleR*(1.0-wet)))*outputlevel;
lastCabSampleR = inputSampleR;
inputSampleR = drySampleR; //cab
if (cycleEnd == 4) {
lastRefL[0] = lastRefL[4]; //start from previous last
lastRefL[2] = (lastRefL[0] + inputSampleL)/2; //half
lastRefL[1] = (lastRefL[0] + lastRefL[2])/2; //one quarter
lastRefL[3] = (lastRefL[2] + inputSampleL)/2; //three quarters
lastRefL[4] = inputSampleL; //full
lastRefR[0] = lastRefR[4]; //start from previous last
lastRefR[2] = (lastRefR[0] + inputSampleR)/2; //half
lastRefR[1] = (lastRefR[0] + lastRefR[2])/2; //one quarter
lastRefR[3] = (lastRefR[2] + inputSampleR)/2; //three quarters
lastRefR[4] = inputSampleR; //full
}
if (cycleEnd == 3) {
lastRefL[0] = lastRefL[3]; //start from previous last
lastRefL[2] = (lastRefL[0]+lastRefL[0]+inputSampleL)/3; //third
lastRefL[1] = (lastRefL[0]+inputSampleL+inputSampleL)/3; //two thirds
lastRefL[3] = inputSampleL; //full
lastRefR[0] = lastRefR[3]; //start from previous last
lastRefR[2] = (lastRefR[0]+lastRefR[0]+inputSampleR)/3; //third
lastRefR[1] = (lastRefR[0]+inputSampleR+inputSampleR)/3; //two thirds
lastRefR[3] = inputSampleR; //full
}
if (cycleEnd == 2) {
lastRefL[0] = lastRefL[2]; //start from previous last
lastRefL[1] = (lastRefL[0] + inputSampleL)/2; //half
lastRefL[2] = inputSampleL; //full
lastRefR[0] = lastRefR[2]; //start from previous last
lastRefR[1] = (lastRefR[0] + inputSampleR)/2; //half
lastRefR[2] = inputSampleR; //full
}
if (cycleEnd == 1) {
lastRefL[0] = inputSampleL;
lastRefR[0] = inputSampleR;
}
cycle = 0; //reset
inputSampleL = lastRefL[cycle];
inputSampleR = lastRefR[cycle];
} else {
inputSampleL = lastRefL[cycle];
inputSampleR = lastRefR[cycle];
//we are going through our references now
}
switch (cycleEnd) //multi-pole average using lastRef[] variables
{
case 4:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[7])*0.5;
lastRefL[7] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[7])*0.5;
lastRefR[7] = lastRefR[8]; //continue, do not break
case 3:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[6])*0.5;
lastRefL[6] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[6])*0.5;
lastRefR[6] = lastRefR[8]; //continue, do not break
case 2:
lastRefL[8] = inputSampleL; inputSampleL = (inputSampleL+lastRefL[5])*0.5;
lastRefL[5] = lastRefL[8]; //continue, do not break
lastRefR[8] = inputSampleR; inputSampleR = (inputSampleR+lastRefR[5])*0.5;
lastRefR[5] = lastRefR[8]; //continue, do not break
case 1:
break; //no further averaging
}
//begin 64 bit stereo floating point dither
//int expon; frexp((double)inputSampleL, &expon);
fpdL ^= fpdL << 13; fpdL ^= fpdL >> 17; fpdL ^= fpdL << 5;
//inputSampleL += ((double(fpdL)-uint32_t(0x7fffffff)) * 1.1e-44l * pow(2,expon+62));
//frexp((double)inputSampleR, &expon);
fpdR ^= fpdR << 13; fpdR ^= fpdR >> 17; fpdR ^= fpdR << 5;
//inputSampleR += ((double(fpdR)-uint32_t(0x7fffffff)) * 1.1e-44l * pow(2,expon+62));
//end 64 bit stereo floating point dither
*out1 = inputSampleL;
*out2 = inputSampleR;
in1++;
in2++;
out1++;
out2++;
}
}
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