/* ======================================== * Galactic2 - Galactic2.h * Copyright (c) airwindows, Airwindows uses the MIT license * ======================================== */ #ifndef __Galactic2_H #include "Galactic2.h" #endif void Galactic2::processReplacing(float **inputs, float **outputs, VstInt32 sampleFrames) { float* in1 = inputs[0]; float* in2 = inputs[1]; float* out1 = outputs[0]; float* out2 = outputs[1]; VstInt32 inFramesToProcess = sampleFrames; //vst doesn't give us this as a separate variable so we'll make it 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 inTrimA = inTrimB; inTrimB = pow(A,4); double regen = 1.0-(pow(1.0-B,4)); regen *= 0.063; double stages = C; wetA = wetB; wetB = 1.0-(pow(1.0-D,4)); 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 temp = (double)sampleFrames/inFramesToProcess; double inputGain = (inTrimA*temp)+(inTrimB*(1.0-temp)); double wet = (wetA*temp)+(wetB*(1.0-temp)); double outSample; cycle++; if (cycle == cycleEnd) { //hit the end point and we do a reverb sample if (inputGain < 1.0) { inputSampleL *= inputGain; inputSampleR *= inputGain; } if (stages > 0.858) { outSample = (inputSampleL + prevInAL)*0.5; prevInAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInAR)*0.5; prevInAR = inputSampleR; inputSampleR = outSample; } else {prevInAL = inputSampleL; prevInAR = inputSampleR;} if (stages > 0.660) { outSample = (inputSampleL + prevInBL)*0.5; prevInBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInBR)*0.5; prevInBR = inputSampleR; inputSampleR = outSample; } else {prevInBL = inputSampleL; prevInBR = inputSampleR;} if (stages > 0.462) { outSample = (inputSampleL + prevInCL)*0.5; prevInCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInCR)*0.5; prevInCR = inputSampleR; inputSampleR = outSample; } else {prevInCL = inputSampleL; prevInCR = inputSampleR;} if (stages > 0.264) { outSample = (inputSampleL + prevInDL)*0.5; prevInDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInDR)*0.5; prevInDR = inputSampleR; inputSampleR = outSample; } else {prevInDL = inputSampleL; prevInDR = inputSampleR;} if (stages > 0.066) { outSample = (inputSampleL + prevInEL)*0.5; prevInEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInER)*0.5; prevInER = inputSampleR; inputSampleR = outSample; } else {prevInEL = inputSampleL; prevInER = inputSampleR;} feedbackCL *= 0.0625; feedbackLR *= 0.0625; if (feedbackA < 0.0078125) feedbackA = 0.0078125; if (feedbackA > 1.0) feedbackA = 1.0; if (feedbackB < 0.0078125) feedbackB = 0.0078125; if (feedbackB > 1.0) feedbackB = 1.0; feedbackCL *= feedbackA; feedbackLR *= feedbackB; feedbackA += sin((fabs(feedbackCL*4)>1)?4:fabs(feedbackCL*4))*pow(feedbackCL,4); feedbackB += sin((fabs(feedbackLR*4)>1)?4:fabs(feedbackLR*4))*pow(feedbackLR,4); feedbackCL *= 16.0; feedbackLR *= 16.0; feedbackDL *= 0.0625; feedbackPR *= 0.0625; if (feedbackC < 0.0078125) feedbackC = 0.0078125; if (feedbackC > 1.0) feedbackC = 1.0; if (feedbackD < 0.0078125) feedbackD = 0.0078125; if (feedbackD > 1.0) feedbackD = 1.0; feedbackDL *= feedbackC; feedbackPR *= feedbackD; feedbackC += sin((fabs(feedbackDL*4)>1)?4:fabs(feedbackDL*4))*pow(feedbackDL,4); feedbackD += sin((fabs(feedbackPR*4)>1)?4:fabs(feedbackPR*4))*pow(feedbackPR,4); feedbackDL *= 16.0; feedbackPR *= 16.0; double iirAmount = ((feedbackA-1.0) * -0.00007) + 0.00001; //kick in highpass iirA = (iirA*(1.0-iirAmount)) + (feedbackCL*iirAmount); feedbackCL -= iirA; iirE = (iirE*(1.0-iirAmount)) + (feedbackAL*iirAmount); feedbackAL -= iirE; iirAmount = ((feedbackB-1.0) * -0.00007) + 0.00001; //kick in highpass iirB = (iirB*(1.0-iirAmount)) + (feedbackLR*iirAmount); feedbackLR -= iirB; iirF = (iirF*(1.0-iirAmount)) + (feedbackDR*iirAmount); feedbackDR -= iirF; iirAmount = ((feedbackC-1.0) * -0.00007) + 0.00001; //kick in highpass iirC = (iirC*(1.0-iirAmount)) + (feedbackDL*iirAmount); feedbackDL -= iirC; iirG = (iirG*(1.0-iirAmount)) + (feedbackBL*iirAmount); feedbackBL -= iirG; iirAmount = ((feedbackD-1.0) * -0.00007) + 0.00001; //kick in highpass iirD = (iirD*(1.0-iirAmount)) + (feedbackPR*iirAmount); feedbackPR -= iirD; iirH = (iirH*(1.0-iirAmount)) + (feedbackHR*iirAmount); feedbackHR -= iirH; aAL[countAL] = inputSampleL + (feedbackAL * regen); aBL[countBL] = inputSampleL + (feedbackBL * regen); aCL[countCL] = inputSampleL + (feedbackCL * regen); aDL[countDL] = inputSampleL + (feedbackDL * regen); aDR[countDR] = inputSampleR + (feedbackDR * regen); aHR[countHR] = inputSampleR + (feedbackHR * regen); aLR[countLR] = inputSampleR + (feedbackLR * regen); aPR[countPR] = inputSampleR + (feedbackPR * regen); countAL++; if (countAL < 0 || countAL > shortA) countAL = 0; countBL++; if (countBL < 0 || countBL > shortB) countBL = 0; countCL++; if (countCL < 0 || countCL > shortC) countCL = 0; countDL++; if (countDL < 0 || countDL > shortD) countDL = 0; countDR++; if (countDR < 0 || countDR > shortD) countDR = 0; countHR++; if (countHR < 0 || countHR > shortH) countHR = 0; countLR++; if (countLR < 0 || countLR > shortL) countLR = 0; countPR++; if (countPR < 0 || countPR > shortP) countPR = 0; double outAL = aAL[countAL-((countAL > shortA)?shortA+1:0)]; double outBL = aBL[countBL-((countBL > shortB)?shortB+1:0)]; double outCL = aCL[countCL-((countCL > shortC)?shortC+1:0)]; double outDL = aDL[countDL-((countDL > shortD)?shortD+1:0)]; double outDR = aDR[countDR-((countDR > shortD)?shortD+1:0)]; double outHR = aHR[countHR-((countHR > shortH)?shortH+1:0)]; double outLR = aLR[countLR-((countLR > shortL)?shortL+1:0)]; double outPR = aPR[countPR-((countPR > shortP)?shortP+1:0)]; if (stages > 0.792) { outSample = (outBL + prevMulchAL)*0.5; prevMulchAL = outBL; outBL = outSample; outSample = (outHR + prevMulchAR)*0.5; prevMulchAR = outHR; outHR = outSample; } else {prevMulchAL = outBL; prevMulchAR = outHR;} if (stages > 0.990) { outSample = (outCL + prevMulchEL)*0.5; prevMulchEL = outCL; outCL = outSample; outSample = (outLR + prevMulchER)*0.5; prevMulchER = outLR; outLR = outSample; } else {prevMulchEL = outCL; prevMulchER = outLR;} aEL[countEL] = outAL - (outBL + outCL + outDL); aFL[countFL] = outBL - (outAL + outCL + outDL); aGL[countGL] = outCL - (outAL + outBL + outDL); aHL[countHL] = outDL - (outAL + outBL + outCL); aCR[countCR] = outDR - (outHR + outLR + outPR); aGR[countGR] = outHR - (outDR + outLR + outPR); aKR[countKR] = outLR - (outDR + outHR + outPR); aOR[countOR] = outPR - (outDR + outHR + outLR); countEL++; if (countEL < 0 || countEL > shortE) countEL = 0; countFL++; if (countFL < 0 || countFL > shortF) countFL = 0; countGL++; if (countGL < 0 || countGL > shortG) countGL = 0; countHL++; if (countHL < 0 || countHL > shortH) countHL = 0; countCR++; if (countCR < 0 || countCR > shortC) countCR = 0; countGR++; if (countGR < 0 || countGR > shortG) countGR = 0; countKR++; if (countKR < 0 || countKR > shortK) countKR = 0; countOR++; if (countOR < 0 || countOR > shortO) countOR = 0; double outEL = aEL[countEL-((countEL > shortE)?shortE+1:0)]; double outFL = aFL[countFL-((countFL > shortF)?shortF+1:0)]; double outGL = aGL[countGL-((countGL > shortG)?shortG+1:0)]; double outHL = aHL[countHL-((countHL > shortH)?shortH+1:0)]; double outCR = aCR[countCR-((countCR > shortC)?shortC+1:0)]; double outGR = aGR[countGR-((countGR > shortG)?shortG+1:0)]; double outKR = aKR[countKR-((countKR > shortK)?shortK+1:0)]; double outOR = aOR[countOR-((countOR > shortO)?shortO+1:0)]; if (stages > 0.594) { outSample = (outFL + prevMulchBL)*0.5; prevMulchBL = outFL; outFL = outSample; outSample = (outGR + prevMulchBR)*0.5; prevMulchBR = outGR; outGR = outSample; } else {prevMulchBL = outFL; prevMulchBR = outGR;} aIL[countIL] = outEL - (outFL + outGL + outHL); aJL[countJL] = outFL - (outEL + outGL + outHL); aKL[countKL] = outGL - (outEL + outFL + outHL); aLL[countLL] = outHL - (outEL + outFL + outGL); aBR[countBR] = outCR - (outGR + outKR + outOR); aFR[countFR] = outGR - (outCR + outKR + outOR); aJR[countJR] = outKR - (outCR + outGR + outOR); aNR[countNR] = outOR - (outCR + outGR + outKR); countIL++; if (countIL < 0 || countIL > shortI) countIL = 0; countJL++; if (countJL < 0 || countJL > shortJ) countJL = 0; countKL++; if (countKL < 0 || countKL > shortK) countKL = 0; countLL++; if (countLL < 0 || countLL > shortL) countLL = 0; countBR++; if (countBR < 0 || countBR > shortB) countBR = 0; countFR++; if (countFR < 0 || countFR > shortF) countFR = 0; countJR++; if (countJR < 0 || countJR > shortJ) countJR = 0; countNR++; if (countNR < 0 || countNR > shortN) countNR = 0; double outIL = aIL[countIL-((countIL > shortI)?shortI+1:0)]; double outJL = aJL[countJL-((countJL > shortJ)?shortJ+1:0)]; double outKL = aKL[countKL-((countKL > shortK)?shortK+1:0)]; double outLL = aLL[countLL-((countLL > shortL)?shortL+1:0)]; double outBR = aBR[countBR-((countBR > shortB)?shortB+1:0)]; double outFR = aFR[countFR-((countFR > shortF)?shortF+1:0)]; double outJR = aJR[countJR-((countJR > shortJ)?shortJ+1:0)]; double outNR = aNR[countNR-((countNR > shortN)?shortN+1:0)]; if (stages > 0.396) { outSample = (outJL + prevMulchCL)*0.5; prevMulchCL = outJL; outJL = outSample; outSample = (outFR + prevMulchCR)*0.5; prevMulchCR = outFR; outFR = outSample; } else {prevMulchCL = outJL; prevMulchCR = outFR;} aML[countML] = outIL - (outJL + outKL + outLL); aNL[countNL] = outJL - (outIL + outKL + outLL); aOL[countOL] = outKL - (outIL + outJL + outLL); aPL[countPL] = outLL - (outIL + outJL + outKL); aAR[countAR] = outBR - (outFR + outJR + outNR); aER[countER] = outFR - (outBR + outJR + outNR); aIR[countIR] = outJR - (outBR + outFR + outNR); aMR[countMR] = outNR - (outBR + outFR + outJR); countML++; if (countML < 0 || countML > shortM) countML = 0; countNL++; if (countNL < 0 || countNL > shortN) countNL = 0; countOL++; if (countOL < 0 || countOL > shortO) countOL = 0; countPL++; if (countPL < 0 || countPL > shortP) countPL = 0; countAR++; if (countAR < 0 || countAR > shortA) countAR = 0; countER++; if (countER < 0 || countER > shortE) countER = 0; countIR++; if (countIR < 0 || countIR > shortI) countIR = 0; countMR++; if (countMR < 0 || countMR > shortM) countMR = 0; double outML = aML[countML-((countML > shortM)?shortM+1:0)]; double outNL = aNL[countNL-((countNL > shortN)?shortN+1:0)]; double outOL = aOL[countOL-((countOL > shortO)?shortO+1:0)]; double outPL = aPL[countPL-((countPL > shortP)?shortP+1:0)]; double outAR = aAR[countAR-((countAR > shortA)?shortA+1:0)]; double outER = aER[countER-((countER > shortE)?shortE+1:0)]; double outIR = aIR[countIR-((countIR > shortI)?shortI+1:0)]; double outMR = aMR[countMR-((countMR > shortM)?shortM+1:0)]; if (stages > 0.198) { outSample = (outNL + prevMulchDL)*0.5; prevMulchDL = outNL; outNL = outSample; outSample = (outER + prevMulchDR)*0.5; prevMulchDR = outER; outER = outSample; } else {prevMulchDL = outNL; prevMulchDR = outER;} feedbackDR = outML - (outNL + outOL + outPL); feedbackAL = outAR - (outER + outIR + outMR); outSample = (feedbackDR + feedbackAL) * 0.5; feedbackDR = feedbackAL = outSample; feedbackBL = outNL - (outML + outOL + outPL); feedbackHR = outER - (outAR + outIR + outMR); feedbackCL = outOL - (outML + outNL + outPL); feedbackLR = outIR - (outAR + outER + outMR); feedbackDL = outPL - (outML + outNL + outOL); feedbackPR = outMR - (outAR + outER + outIR); //which we need to feed back into the input again, a bit inputSampleL = (outML + outNL + outOL + outPL)/8.0; inputSampleR = (outAR + outER + outIR + outMR)/8.0; //and take the final combined sum of outputs, corrected for Householder gain if (stages > 0.924) { outSample = (inputSampleL + prevOutAL)*0.5; prevOutAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutAR)*0.5; prevOutAR = inputSampleR; inputSampleR = outSample; } else {prevOutAL = inputSampleL; prevOutAR = inputSampleR;} if (stages > 0.726) { outSample = (inputSampleL + prevOutBL)*0.5; prevOutBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutBR)*0.5; prevOutBR = inputSampleR; inputSampleR = outSample; } else {prevOutBL = inputSampleL; prevOutBR = inputSampleR;} if (stages > 0.528) { outSample = (inputSampleL + prevOutCL)*0.5; prevOutCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutCR)*0.5; prevOutCR = inputSampleR; inputSampleR = outSample; } else {prevOutCL = inputSampleL; prevOutCR = inputSampleR;} if (stages > 0.330) { outSample = (inputSampleL + prevOutDL)*0.5; prevOutDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutDR)*0.5; prevOutDR = inputSampleR; inputSampleR = outSample; } else {prevOutDL = inputSampleL; prevOutDR = inputSampleR;} if (stages > 0.132) { outSample = (inputSampleL + prevOutEL)*0.5; prevOutEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutER)*0.5; prevOutER = inputSampleR; inputSampleR = outSample; } else {prevOutEL = inputSampleL; prevOutER = inputSampleR;} 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 } inputSampleL *= 0.5; inputSampleR *= 0.5; if (inputSampleL > 2.0) inputSampleL = 2.0; if (inputSampleL < -2.0) inputSampleL = -2.0; if (inputSampleR > 2.0) inputSampleR = 2.0; if (inputSampleR < -2.0) inputSampleR = -2.0;//clip BigFastArcSin harder if (inputSampleL > 0.0) inputSampleL = (inputSampleL*2.0)/(2.8274333882308-inputSampleL); else inputSampleL = -(inputSampleL*-2.0)/(2.8274333882308+inputSampleL); if (inputSampleR > 0.0) inputSampleR = (inputSampleR*2.0)/(2.8274333882308-inputSampleR); else inputSampleR = -(inputSampleR*-2.0)/(2.8274333882308+inputSampleR); //BigFastArcSin output stage if (stages > 0.924) { outSample = (inputSampleL + finalOutAL)*0.5; finalOutAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutAR)*0.5; finalOutAR = inputSampleR; inputSampleR = outSample; } else {finalOutAL = inputSampleL; finalOutAR = inputSampleR;} if (stages > 0.726) { outSample = (inputSampleL + finalOutBL)*0.5; finalOutBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutBR)*0.5; finalOutBR = inputSampleR; inputSampleR = outSample; } else {finalOutBL = inputSampleL; finalOutBR = inputSampleR;} if (stages > 0.528) { outSample = (inputSampleL + finalOutCL)*0.5; finalOutCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutCR)*0.5; finalOutCR = inputSampleR; inputSampleR = outSample; } else {finalOutCL = inputSampleL; finalOutCR = inputSampleR;} if (stages > 0.330) { outSample = (inputSampleL + finalOutDL)*0.5; finalOutDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutDR)*0.5; finalOutDR = inputSampleR; inputSampleR = outSample; } else {finalOutDL = inputSampleL; finalOutDR = inputSampleR;} if (stages > 0.132) { outSample = (inputSampleL + finalOutEL)*0.5; finalOutEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutER)*0.5; finalOutER = inputSampleR; inputSampleR = outSample; } else {finalOutEL = inputSampleL; finalOutER = inputSampleR;} inputSampleL = (inputSampleL * wet) + (drySampleL * (1.0-wet)); inputSampleR = (inputSampleR * wet) + (drySampleR * (1.0-wet)); //Galactic2 does a proper crossfade so you can perform with it more actively if (inputSampleL > 2.0) inputSampleL = 2.0; if (inputSampleL < -2.0) inputSampleL = -2.0; if (inputSampleR > 2.0) inputSampleR = 2.0; if (inputSampleR < -2.0) inputSampleR = -2.0;//catch meltdowns //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 Galactic2::processDoubleReplacing(double **inputs, double **outputs, VstInt32 sampleFrames) { double* in1 = inputs[0]; double* in2 = inputs[1]; double* out1 = outputs[0]; double* out2 = outputs[1]; VstInt32 inFramesToProcess = sampleFrames; //vst doesn't give us this as a separate variable so we'll make it 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 inTrimA = inTrimB; inTrimB = pow(A,4); double regen = 1.0-(pow(1.0-B,4)); regen *= 0.063; double stages = C; wetA = wetB; wetB = 1.0-(pow(1.0-D,4)); 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 temp = (double)sampleFrames/inFramesToProcess; double inputGain = (inTrimA*temp)+(inTrimB*(1.0-temp)); double wet = (wetA*temp)+(wetB*(1.0-temp)); double outSample; cycle++; if (cycle == cycleEnd) { //hit the end point and we do a reverb sample if (inputGain < 1.0) { inputSampleL *= inputGain; inputSampleR *= inputGain; } if (stages > 0.858) { outSample = (inputSampleL + prevInAL)*0.5; prevInAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInAR)*0.5; prevInAR = inputSampleR; inputSampleR = outSample; } else {prevInAL = inputSampleL; prevInAR = inputSampleR;} if (stages > 0.660) { outSample = (inputSampleL + prevInBL)*0.5; prevInBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInBR)*0.5; prevInBR = inputSampleR; inputSampleR = outSample; } else {prevInBL = inputSampleL; prevInBR = inputSampleR;} if (stages > 0.462) { outSample = (inputSampleL + prevInCL)*0.5; prevInCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInCR)*0.5; prevInCR = inputSampleR; inputSampleR = outSample; } else {prevInCL = inputSampleL; prevInCR = inputSampleR;} if (stages > 0.264) { outSample = (inputSampleL + prevInDL)*0.5; prevInDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInDR)*0.5; prevInDR = inputSampleR; inputSampleR = outSample; } else {prevInDL = inputSampleL; prevInDR = inputSampleR;} if (stages > 0.066) { outSample = (inputSampleL + prevInEL)*0.5; prevInEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevInER)*0.5; prevInER = inputSampleR; inputSampleR = outSample; } else {prevInEL = inputSampleL; prevInER = inputSampleR;} feedbackCL *= 0.0625; feedbackLR *= 0.0625; if (feedbackA < 0.0078125) feedbackA = 0.0078125; if (feedbackA > 1.0) feedbackA = 1.0; if (feedbackB < 0.0078125) feedbackB = 0.0078125; if (feedbackB > 1.0) feedbackB = 1.0; feedbackCL *= feedbackA; feedbackLR *= feedbackB; feedbackA += sin((fabs(feedbackCL*4)>1)?4:fabs(feedbackCL*4))*pow(feedbackCL,4); feedbackB += sin((fabs(feedbackLR*4)>1)?4:fabs(feedbackLR*4))*pow(feedbackLR,4); feedbackCL *= 16.0; feedbackLR *= 16.0; feedbackDL *= 0.0625; feedbackPR *= 0.0625; if (feedbackC < 0.0078125) feedbackC = 0.0078125; if (feedbackC > 1.0) feedbackC = 1.0; if (feedbackD < 0.0078125) feedbackD = 0.0078125; if (feedbackD > 1.0) feedbackD = 1.0; feedbackDL *= feedbackC; feedbackPR *= feedbackD; feedbackC += sin((fabs(feedbackDL*4)>1)?4:fabs(feedbackDL*4))*pow(feedbackDL,4); feedbackD += sin((fabs(feedbackPR*4)>1)?4:fabs(feedbackPR*4))*pow(feedbackPR,4); feedbackDL *= 16.0; feedbackPR *= 16.0; double iirAmount = ((feedbackA-1.0) * -0.00007) + 0.00001; //kick in highpass iirA = (iirA*(1.0-iirAmount)) + (feedbackCL*iirAmount); feedbackCL -= iirA; iirE = (iirE*(1.0-iirAmount)) + (feedbackAL*iirAmount); feedbackAL -= iirE; iirAmount = ((feedbackB-1.0) * -0.00007) + 0.00001; //kick in highpass iirB = (iirB*(1.0-iirAmount)) + (feedbackLR*iirAmount); feedbackLR -= iirB; iirF = (iirF*(1.0-iirAmount)) + (feedbackDR*iirAmount); feedbackDR -= iirF; iirAmount = ((feedbackC-1.0) * -0.00007) + 0.00001; //kick in highpass iirC = (iirC*(1.0-iirAmount)) + (feedbackDL*iirAmount); feedbackDL -= iirC; iirG = (iirG*(1.0-iirAmount)) + (feedbackBL*iirAmount); feedbackBL -= iirG; iirAmount = ((feedbackD-1.0) * -0.00007) + 0.00001; //kick in highpass iirD = (iirD*(1.0-iirAmount)) + (feedbackPR*iirAmount); feedbackPR -= iirD; iirH = (iirH*(1.0-iirAmount)) + (feedbackHR*iirAmount); feedbackHR -= iirH; aAL[countAL] = inputSampleL + (feedbackAL * regen); aBL[countBL] = inputSampleL + (feedbackBL * regen); aCL[countCL] = inputSampleL + (feedbackCL * regen); aDL[countDL] = inputSampleL + (feedbackDL * regen); aDR[countDR] = inputSampleR + (feedbackDR * regen); aHR[countHR] = inputSampleR + (feedbackHR * regen); aLR[countLR] = inputSampleR + (feedbackLR * regen); aPR[countPR] = inputSampleR + (feedbackPR * regen); countAL++; if (countAL < 0 || countAL > shortA) countAL = 0; countBL++; if (countBL < 0 || countBL > shortB) countBL = 0; countCL++; if (countCL < 0 || countCL > shortC) countCL = 0; countDL++; if (countDL < 0 || countDL > shortD) countDL = 0; countDR++; if (countDR < 0 || countDR > shortD) countDR = 0; countHR++; if (countHR < 0 || countHR > shortH) countHR = 0; countLR++; if (countLR < 0 || countLR > shortL) countLR = 0; countPR++; if (countPR < 0 || countPR > shortP) countPR = 0; double outAL = aAL[countAL-((countAL > shortA)?shortA+1:0)]; double outBL = aBL[countBL-((countBL > shortB)?shortB+1:0)]; double outCL = aCL[countCL-((countCL > shortC)?shortC+1:0)]; double outDL = aDL[countDL-((countDL > shortD)?shortD+1:0)]; double outDR = aDR[countDR-((countDR > shortD)?shortD+1:0)]; double outHR = aHR[countHR-((countHR > shortH)?shortH+1:0)]; double outLR = aLR[countLR-((countLR > shortL)?shortL+1:0)]; double outPR = aPR[countPR-((countPR > shortP)?shortP+1:0)]; if (stages > 0.792) { outSample = (outBL + prevMulchAL)*0.5; prevMulchAL = outBL; outBL = outSample; outSample = (outHR + prevMulchAR)*0.5; prevMulchAR = outHR; outHR = outSample; } else {prevMulchAL = outBL; prevMulchAR = outHR;} if (stages > 0.990) { outSample = (outCL + prevMulchEL)*0.5; prevMulchEL = outCL; outCL = outSample; outSample = (outLR + prevMulchER)*0.5; prevMulchER = outLR; outLR = outSample; } else {prevMulchEL = outCL; prevMulchER = outLR;} aEL[countEL] = outAL - (outBL + outCL + outDL); aFL[countFL] = outBL - (outAL + outCL + outDL); aGL[countGL] = outCL - (outAL + outBL + outDL); aHL[countHL] = outDL - (outAL + outBL + outCL); aCR[countCR] = outDR - (outHR + outLR + outPR); aGR[countGR] = outHR - (outDR + outLR + outPR); aKR[countKR] = outLR - (outDR + outHR + outPR); aOR[countOR] = outPR - (outDR + outHR + outLR); countEL++; if (countEL < 0 || countEL > shortE) countEL = 0; countFL++; if (countFL < 0 || countFL > shortF) countFL = 0; countGL++; if (countGL < 0 || countGL > shortG) countGL = 0; countHL++; if (countHL < 0 || countHL > shortH) countHL = 0; countCR++; if (countCR < 0 || countCR > shortC) countCR = 0; countGR++; if (countGR < 0 || countGR > shortG) countGR = 0; countKR++; if (countKR < 0 || countKR > shortK) countKR = 0; countOR++; if (countOR < 0 || countOR > shortO) countOR = 0; double outEL = aEL[countEL-((countEL > shortE)?shortE+1:0)]; double outFL = aFL[countFL-((countFL > shortF)?shortF+1:0)]; double outGL = aGL[countGL-((countGL > shortG)?shortG+1:0)]; double outHL = aHL[countHL-((countHL > shortH)?shortH+1:0)]; double outCR = aCR[countCR-((countCR > shortC)?shortC+1:0)]; double outGR = aGR[countGR-((countGR > shortG)?shortG+1:0)]; double outKR = aKR[countKR-((countKR > shortK)?shortK+1:0)]; double outOR = aOR[countOR-((countOR > shortO)?shortO+1:0)]; if (stages > 0.594) { outSample = (outFL + prevMulchBL)*0.5; prevMulchBL = outFL; outFL = outSample; outSample = (outGR + prevMulchBR)*0.5; prevMulchBR = outGR; outGR = outSample; } else {prevMulchBL = outFL; prevMulchBR = outGR;} aIL[countIL] = outEL - (outFL + outGL + outHL); aJL[countJL] = outFL - (outEL + outGL + outHL); aKL[countKL] = outGL - (outEL + outFL + outHL); aLL[countLL] = outHL - (outEL + outFL + outGL); aBR[countBR] = outCR - (outGR + outKR + outOR); aFR[countFR] = outGR - (outCR + outKR + outOR); aJR[countJR] = outKR - (outCR + outGR + outOR); aNR[countNR] = outOR - (outCR + outGR + outKR); countIL++; if (countIL < 0 || countIL > shortI) countIL = 0; countJL++; if (countJL < 0 || countJL > shortJ) countJL = 0; countKL++; if (countKL < 0 || countKL > shortK) countKL = 0; countLL++; if (countLL < 0 || countLL > shortL) countLL = 0; countBR++; if (countBR < 0 || countBR > shortB) countBR = 0; countFR++; if (countFR < 0 || countFR > shortF) countFR = 0; countJR++; if (countJR < 0 || countJR > shortJ) countJR = 0; countNR++; if (countNR < 0 || countNR > shortN) countNR = 0; double outIL = aIL[countIL-((countIL > shortI)?shortI+1:0)]; double outJL = aJL[countJL-((countJL > shortJ)?shortJ+1:0)]; double outKL = aKL[countKL-((countKL > shortK)?shortK+1:0)]; double outLL = aLL[countLL-((countLL > shortL)?shortL+1:0)]; double outBR = aBR[countBR-((countBR > shortB)?shortB+1:0)]; double outFR = aFR[countFR-((countFR > shortF)?shortF+1:0)]; double outJR = aJR[countJR-((countJR > shortJ)?shortJ+1:0)]; double outNR = aNR[countNR-((countNR > shortN)?shortN+1:0)]; if (stages > 0.396) { outSample = (outJL + prevMulchCL)*0.5; prevMulchCL = outJL; outJL = outSample; outSample = (outFR + prevMulchCR)*0.5; prevMulchCR = outFR; outFR = outSample; } else {prevMulchCL = outJL; prevMulchCR = outFR;} aML[countML] = outIL - (outJL + outKL + outLL); aNL[countNL] = outJL - (outIL + outKL + outLL); aOL[countOL] = outKL - (outIL + outJL + outLL); aPL[countPL] = outLL - (outIL + outJL + outKL); aAR[countAR] = outBR - (outFR + outJR + outNR); aER[countER] = outFR - (outBR + outJR + outNR); aIR[countIR] = outJR - (outBR + outFR + outNR); aMR[countMR] = outNR - (outBR + outFR + outJR); countML++; if (countML < 0 || countML > shortM) countML = 0; countNL++; if (countNL < 0 || countNL > shortN) countNL = 0; countOL++; if (countOL < 0 || countOL > shortO) countOL = 0; countPL++; if (countPL < 0 || countPL > shortP) countPL = 0; countAR++; if (countAR < 0 || countAR > shortA) countAR = 0; countER++; if (countER < 0 || countER > shortE) countER = 0; countIR++; if (countIR < 0 || countIR > shortI) countIR = 0; countMR++; if (countMR < 0 || countMR > shortM) countMR = 0; double outML = aML[countML-((countML > shortM)?shortM+1:0)]; double outNL = aNL[countNL-((countNL > shortN)?shortN+1:0)]; double outOL = aOL[countOL-((countOL > shortO)?shortO+1:0)]; double outPL = aPL[countPL-((countPL > shortP)?shortP+1:0)]; double outAR = aAR[countAR-((countAR > shortA)?shortA+1:0)]; double outER = aER[countER-((countER > shortE)?shortE+1:0)]; double outIR = aIR[countIR-((countIR > shortI)?shortI+1:0)]; double outMR = aMR[countMR-((countMR > shortM)?shortM+1:0)]; if (stages > 0.198) { outSample = (outNL + prevMulchDL)*0.5; prevMulchDL = outNL; outNL = outSample; outSample = (outER + prevMulchDR)*0.5; prevMulchDR = outER; outER = outSample; } else {prevMulchDL = outNL; prevMulchDR = outER;} feedbackDR = outML - (outNL + outOL + outPL); feedbackAL = outAR - (outER + outIR + outMR); outSample = (feedbackDR + feedbackAL) * 0.5; feedbackDR = feedbackAL = outSample; feedbackBL = outNL - (outML + outOL + outPL); feedbackHR = outER - (outAR + outIR + outMR); feedbackCL = outOL - (outML + outNL + outPL); feedbackLR = outIR - (outAR + outER + outMR); feedbackDL = outPL - (outML + outNL + outOL); feedbackPR = outMR - (outAR + outER + outIR); //which we need to feed back into the input again, a bit inputSampleL = (outML + outNL + outOL + outPL)/8.0; inputSampleR = (outAR + outER + outIR + outMR)/8.0; //and take the final combined sum of outputs, corrected for Householder gain if (stages > 0.924) { outSample = (inputSampleL + prevOutAL)*0.5; prevOutAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutAR)*0.5; prevOutAR = inputSampleR; inputSampleR = outSample; } else {prevOutAL = inputSampleL; prevOutAR = inputSampleR;} if (stages > 0.726) { outSample = (inputSampleL + prevOutBL)*0.5; prevOutBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutBR)*0.5; prevOutBR = inputSampleR; inputSampleR = outSample; } else {prevOutBL = inputSampleL; prevOutBR = inputSampleR;} if (stages > 0.528) { outSample = (inputSampleL + prevOutCL)*0.5; prevOutCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutCR)*0.5; prevOutCR = inputSampleR; inputSampleR = outSample; } else {prevOutCL = inputSampleL; prevOutCR = inputSampleR;} if (stages > 0.330) { outSample = (inputSampleL + prevOutDL)*0.5; prevOutDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutDR)*0.5; prevOutDR = inputSampleR; inputSampleR = outSample; } else {prevOutDL = inputSampleL; prevOutDR = inputSampleR;} if (stages > 0.132) { outSample = (inputSampleL + prevOutEL)*0.5; prevOutEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + prevOutER)*0.5; prevOutER = inputSampleR; inputSampleR = outSample; } else {prevOutEL = inputSampleL; prevOutER = inputSampleR;} 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 } inputSampleL *= 0.5; inputSampleR *= 0.5; if (inputSampleL > 2.0) inputSampleL = 2.0; if (inputSampleL < -2.0) inputSampleL = -2.0; if (inputSampleR > 2.0) inputSampleR = 2.0; if (inputSampleR < -2.0) inputSampleR = -2.0;//clip BigFastArcSin harder if (inputSampleL > 0.0) inputSampleL = (inputSampleL*2.0)/(2.8274333882308-inputSampleL); else inputSampleL = -(inputSampleL*-2.0)/(2.8274333882308+inputSampleL); if (inputSampleR > 0.0) inputSampleR = (inputSampleR*2.0)/(2.8274333882308-inputSampleR); else inputSampleR = -(inputSampleR*-2.0)/(2.8274333882308+inputSampleR); //BigFastArcSin output stage if (stages > 0.924) { outSample = (inputSampleL + finalOutAL)*0.5; finalOutAL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutAR)*0.5; finalOutAR = inputSampleR; inputSampleR = outSample; } else {finalOutAL = inputSampleL; finalOutAR = inputSampleR;} if (stages > 0.726) { outSample = (inputSampleL + finalOutBL)*0.5; finalOutBL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutBR)*0.5; finalOutBR = inputSampleR; inputSampleR = outSample; } else {finalOutBL = inputSampleL; finalOutBR = inputSampleR;} if (stages > 0.528) { outSample = (inputSampleL + finalOutCL)*0.5; finalOutCL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutCR)*0.5; finalOutCR = inputSampleR; inputSampleR = outSample; } else {finalOutCL = inputSampleL; finalOutCR = inputSampleR;} if (stages > 0.330) { outSample = (inputSampleL + finalOutDL)*0.5; finalOutDL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutDR)*0.5; finalOutDR = inputSampleR; inputSampleR = outSample; } else {finalOutDL = inputSampleL; finalOutDR = inputSampleR;} if (stages > 0.132) { outSample = (inputSampleL + finalOutEL)*0.5; finalOutEL = inputSampleL; inputSampleL = outSample; outSample = (inputSampleR + finalOutER)*0.5; finalOutER = inputSampleR; inputSampleR = outSample; } else {finalOutEL = inputSampleL; finalOutER = inputSampleR;} inputSampleL = (inputSampleL * wet) + (drySampleL * (1.0-wet)); inputSampleR = (inputSampleR * wet) + (drySampleR * (1.0-wet)); //Galactic2 does a proper crossfade so you can perform with it more actively if (inputSampleL > 2.0) inputSampleL = 2.0; if (inputSampleL < -2.0) inputSampleL = -2.0; if (inputSampleR > 2.0) inputSampleR = 2.0; if (inputSampleR < -2.0) inputSampleR = -2.0;//catch meltdowns //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++; } }