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718 lines
27 KiB
C++
Executable file
718 lines
27 KiB
C++
Executable file
/* ========================================
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* VerbThic - VerbThic.h
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* Copyright (c) airwindows, Airwindows uses the MIT license
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* ======================================== */
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#ifndef __VerbThic_H
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#include "VerbThic.h"
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#endif
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void VerbThic::processReplacing(float **inputs, float **outputs, VstInt32 sampleFrames)
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{
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float* in1 = inputs[0];
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float* in2 = inputs[1];
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float* out1 = outputs[0];
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float* out2 = outputs[1];
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double overallscale = 1.0;
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overallscale /= 44100.0;
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overallscale *= getSampleRate();
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double reg4n = 0.03125+((1.0-pow(1.0-A,2.0))*0.03125);
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double attenuate = 1.0 - (1.0-pow(1.0-A,2.0));
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double derez = pow(B,2.0);
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derez = fmin(fmax(derez/overallscale,0.0001),1.0);
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int bezFraction = (int)(1.0/derez);
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double bezTrim = (double)bezFraction/(bezFraction+1.0);
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derez = 1.0 / bezFraction;
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bezTrim = 1.0-(derez*bezTrim);
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//the revision more accurately connects the bezier curves
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double derezFreq = pow(C,2.0);
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derezFreq = fmin(fmax(derezFreq/overallscale,0.0001),1.0);
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int bezFreqFraction = (int)(1.0/derezFreq);
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double bezFreqTrim = (double)bezFreqFraction/(bezFreqFraction+1.0);
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derezFreq = 1.0 / bezFreqFraction;
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bezFreqTrim = 1.0-(derezFreq*bezFreqTrim);
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//the revision more accurately connects the bezier curves
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double wider = D*2.0;
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double wet = E;
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while (--sampleFrames >= 0)
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{
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double inputSampleL = *in1;
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double inputSampleR = *in2;
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if (fabs(inputSampleL)<1.18e-23) inputSampleL = fpdL * 1.18e-17;
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if (fabs(inputSampleR)<1.18e-23) inputSampleR = fpdR * 1.18e-17;
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double drySampleL = inputSampleL;
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double drySampleR = inputSampleR;
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bez[bez_cycle] += derez;
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bez[bez_SampL] += (inputSampleL*attenuate*derez);
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bez[bez_SampR] += (inputSampleR*attenuate*derez);
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if (bez[bez_cycle] > 1.0) { //hit the end point and we do a reverb sample
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bez[bez_cycle] = 0.0;
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double mainSampleL = bez[bez_SampL];
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double dualmonoSampleL = bez[bez_SampR];
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//workaround involves keeping the cross-matrix system,
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//but for initial layering, each side gets each version
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//making blends never quite line up as exactly the same.
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//left verbs
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a4AL[c4AL] = mainSampleL + (f4DR * reg4n);
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a4BL[c4BL] = mainSampleL + (f4HR * reg4n);
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a4CL[c4CL] = mainSampleL + (f4LR * reg4n);
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a4DL[c4DL] = mainSampleL + (f4PR * reg4n);
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b4AL[c4AL] = dualmonoSampleL + (g4AL * reg4n);
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b4BL[c4BL] = dualmonoSampleL + (g4BL * reg4n);
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b4CL[c4CL] = dualmonoSampleL + (g4CL * reg4n);
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b4DL[c4DL] = dualmonoSampleL + (g4DL * reg4n);
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c4AL++; if (c4AL < 0 || c4AL > d4A) c4AL = 0;
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c4BL++; if (c4BL < 0 || c4BL > d4B) c4BL = 0;
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c4CL++; if (c4CL < 0 || c4CL > d4C) c4CL = 0;
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c4DL++; if (c4DL < 0 || c4DL > d4D) c4DL = 0;
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double hA = a4AL[c4AL-((c4AL > d4A)?d4A+1:0)];
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double hB = a4BL[c4BL-((c4BL > d4B)?d4B+1:0)];
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double hC = a4CL[c4CL-((c4CL > d4C)?d4C+1:0)];
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double hD = a4DL[c4DL-((c4DL > d4D)?d4D+1:0)];
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a4EL[c4EL] = hA - (hB + hC + hD);
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a4FL[c4FL] = hB - (hA + hC + hD);
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a4GL[c4GL] = hC - (hA + hB + hD);
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a4HL[c4HL] = hD - (hA + hB + hC);
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hA = b4AL[c4AL-((c4AL > d4A)?d4A+1:0)];
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hB = b4BL[c4BL-((c4BL > d4B)?d4B+1:0)];
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hC = b4CL[c4CL-((c4CL > d4C)?d4C+1:0)];
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hD = b4DL[c4DL-((c4DL > d4D)?d4D+1:0)];
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b4EL[c4EL] = hA - (hB + hC + hD);
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b4FL[c4FL] = hB - (hA + hC + hD);
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b4GL[c4GL] = hC - (hA + hB + hD);
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b4HL[c4HL] = hD - (hA + hB + hC);
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c4EL++; if (c4EL < 0 || c4EL > d4E) c4EL = 0;
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c4FL++; if (c4FL < 0 || c4FL > d4F) c4FL = 0;
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c4GL++; if (c4GL < 0 || c4GL > d4G) c4GL = 0;
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c4HL++; if (c4HL < 0 || c4HL > d4H) c4HL = 0;
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hA = a4EL[c4EL-((c4EL > d4E)?d4E+1:0)];
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hB = a4FL[c4FL-((c4FL > d4F)?d4F+1:0)];
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hC = a4GL[c4GL-((c4GL > d4G)?d4G+1:0)];
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hD = a4HL[c4HL-((c4HL > d4H)?d4H+1:0)];
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a4IL[c4IL] = hA - (hB + hC + hD);
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a4JL[c4JL] = hB - (hA + hC + hD);
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a4KL[c4KL] = hC - (hA + hB + hD);
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a4LL[c4LL] = hD - (hA + hB + hC);
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hA = b4EL[c4EL-((c4EL > d4E)?d4E+1:0)];
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hB = b4FL[c4FL-((c4FL > d4F)?d4F+1:0)];
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hC = b4GL[c4GL-((c4GL > d4G)?d4G+1:0)];
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hD = b4HL[c4HL-((c4HL > d4H)?d4H+1:0)];
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b4IL[c4IL] = hA - (hB + hC + hD);
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b4JL[c4JL] = hB - (hA + hC + hD);
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b4KL[c4KL] = hC - (hA + hB + hD);
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b4LL[c4LL] = hD - (hA + hB + hC);
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c4IL++; if (c4IL < 0 || c4IL > d4I) c4IL = 0;
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c4JL++; if (c4JL < 0 || c4JL > d4J) c4JL = 0;
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c4KL++; if (c4KL < 0 || c4KL > d4K) c4KL = 0;
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c4LL++; if (c4LL < 0 || c4LL > d4L) c4LL = 0;
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hA = a4IL[c4IL-((c4IL > d4I)?d4I+1:0)];
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hB = a4JL[c4JL-((c4JL > d4J)?d4J+1:0)];
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hC = a4KL[c4KL-((c4KL > d4K)?d4K+1:0)];
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hD = a4LL[c4LL-((c4LL > d4L)?d4L+1:0)];
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a4ML[c4ML] = hA - (hB + hC + hD);
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a4NL[c4NL] = hB - (hA + hC + hD);
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a4OL[c4OL] = hC - (hA + hB + hD);
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a4PL[c4PL] = hD - (hA + hB + hC);
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hA = b4IL[c4IL-((c4IL > d4I)?d4I+1:0)];
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hB = b4JL[c4JL-((c4JL > d4J)?d4J+1:0)];
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hC = b4KL[c4KL-((c4KL > d4K)?d4K+1:0)];
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hD = b4LL[c4LL-((c4LL > d4L)?d4L+1:0)];
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b4ML[c4ML] = hA - (hB + hC + hD);
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b4NL[c4NL] = hB - (hA + hC + hD);
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b4OL[c4OL] = hC - (hA + hB + hD);
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b4PL[c4PL] = hD - (hA + hB + hC);
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c4ML++; if (c4ML < 0 || c4ML > d4M) c4ML = 0;
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c4NL++; if (c4NL < 0 || c4NL > d4N) c4NL = 0;
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c4OL++; if (c4OL < 0 || c4OL > d4O) c4OL = 0;
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c4PL++; if (c4PL < 0 || c4PL > d4P) c4PL = 0;
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hA = a4ML[c4ML-((c4ML > d4M)?d4M+1:0)];
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hB = a4NL[c4NL-((c4NL > d4N)?d4N+1:0)];
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hC = a4OL[c4OL-((c4OL > d4O)?d4O+1:0)];
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hD = a4PL[c4PL-((c4PL > d4P)?d4P+1:0)];
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f4AL = hA - (hB + hC + hD);
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f4BL = hB - (hA + hC + hD);
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f4CL = hC - (hA + hB + hD);
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f4DL = hD - (hA + hB + hC);//not actually crosschannel yet
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mainSampleL = (hA + hB + hC + hD)*0.125;
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hA = b4ML[c4ML-((c4ML > d4M)?d4M+1:0)];
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hB = b4NL[c4NL-((c4NL > d4N)?d4N+1:0)];
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hC = b4OL[c4OL-((c4OL > d4O)?d4O+1:0)];
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hD = b4PL[c4PL-((c4PL > d4P)?d4P+1:0)];
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g4AL = hA - (hB + hC + hD);
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g4BL = hB - (hA + hC + hD);
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g4CL = hC - (hA + hB + hD);
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g4DL = hD - (hA + hB + hC);
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dualmonoSampleL = (hA + hB + hC + hD)*0.125;
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double mainSampleR = bez[bez_SampR]; //begin primary reverb
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double dualmonoSampleR = bez[bez_SampL];
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//right verbs
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a4DR[c4DR] = mainSampleR + (f4AL * reg4n);
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a4HR[c4HR] = mainSampleR + (f4BL * reg4n);
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a4LR[c4LR] = mainSampleR + (f4CL * reg4n);
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a4PR[c4PR] = mainSampleR + (f4DL * reg4n);
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b4DR[c4DR] = dualmonoSampleR + (g4DR * reg4n);
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b4HR[c4HR] = dualmonoSampleR + (g4HR * reg4n);
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b4LR[c4LR] = dualmonoSampleR + (g4LR * reg4n);
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b4PR[c4PR] = dualmonoSampleR + (g4PR * reg4n);
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c4DR++; if (c4DR < 0 || c4DR > d4D) c4DR = 0;
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c4HR++; if (c4HR < 0 || c4HR > d4H) c4HR = 0;
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c4LR++; if (c4LR < 0 || c4LR > d4L) c4LR = 0;
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c4PR++; if (c4PR < 0 || c4PR > d4P) c4PR = 0;
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hA = a4DR[c4DR-((c4DR > d4D)?d4D+1:0)];
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hB = a4HR[c4HR-((c4HR > d4H)?d4H+1:0)];
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hC = a4LR[c4LR-((c4LR > d4L)?d4L+1:0)];
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hD = a4PR[c4PR-((c4PR > d4P)?d4P+1:0)];
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a4CR[c4CR] = hA - (hB + hC + hD);
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a4GR[c4GR] = hB - (hA + hC + hD);
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a4KR[c4KR] = hC - (hA + hB + hD);
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a4OR[c4OR] = hD - (hA + hB + hC);
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hA = b4DR[c4DR-((c4DR > d4D)?d4D+1:0)];
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hB = b4HR[c4HR-((c4HR > d4H)?d4H+1:0)];
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hC = b4LR[c4LR-((c4LR > d4L)?d4L+1:0)];
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hD = b4PR[c4PR-((c4PR > d4P)?d4P+1:0)];
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b4CR[c4CR] = hA - (hB + hC + hD);
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b4GR[c4GR] = hB - (hA + hC + hD);
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b4KR[c4KR] = hC - (hA + hB + hD);
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b4OR[c4OR] = hD - (hA + hB + hC);
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c4CR++; if (c4CR < 0 || c4CR > d4C) c4CR = 0;
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c4GR++; if (c4GR < 0 || c4GR > d4G) c4GR = 0;
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c4KR++; if (c4KR < 0 || c4KR > d4K) c4KR = 0;
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c4OR++; if (c4OR < 0 || c4OR > d4O) c4OR = 0;
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hA = a4CR[c4CR-((c4CR > d4C)?d4C+1:0)];
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hB = a4GR[c4GR-((c4GR > d4G)?d4G+1:0)];
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hC = a4KR[c4KR-((c4KR > d4K)?d4K+1:0)];
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hD = a4OR[c4OR-((c4OR > d4O)?d4O+1:0)];
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a4BR[c4BR] = hA - (hB + hC + hD);
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a4FR[c4FR] = hB - (hA + hC + hD);
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a4JR[c4JR] = hC - (hA + hB + hD);
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a4NR[c4NR] = hD - (hA + hB + hC);
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hA = b4CR[c4CR-((c4CR > d4C)?d4C+1:0)];
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hB = b4GR[c4GR-((c4GR > d4G)?d4G+1:0)];
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hC = b4KR[c4KR-((c4KR > d4K)?d4K+1:0)];
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hD = b4OR[c4OR-((c4OR > d4O)?d4O+1:0)];
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b4BR[c4BR] = hA - (hB + hC + hD);
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b4FR[c4FR] = hB - (hA + hC + hD);
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b4JR[c4JR] = hC - (hA + hB + hD);
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b4NR[c4NR] = hD - (hA + hB + hC);
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c4BR++; if (c4BR < 0 || c4BR > d4B) c4BR = 0;
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c4FR++; if (c4FR < 0 || c4FR > d4F) c4FR = 0;
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c4JR++; if (c4JR < 0 || c4JR > d4J) c4JR = 0;
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c4NR++; if (c4NR < 0 || c4NR > d4N) c4NR = 0;
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hA = a4BR[c4BR-((c4BR > d4B)?d4B+1:0)];
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hB = a4FR[c4FR-((c4FR > d4F)?d4F+1:0)];
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hC = a4JR[c4JR-((c4JR > d4J)?d4J+1:0)];
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hD = a4NR[c4NR-((c4NR > d4N)?d4N+1:0)];
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a4AR[c4AR] = hA - (hB + hC + hD);
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a4ER[c4ER] = hB - (hA + hC + hD);
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a4IR[c4IR] = hC - (hA + hB + hD);
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a4MR[c4MR] = hD - (hA + hB + hC);
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hA = b4BR[c4BR-((c4BR > d4B)?d4B+1:0)];
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hB = b4FR[c4FR-((c4FR > d4F)?d4F+1:0)];
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hC = b4JR[c4JR-((c4JR > d4J)?d4J+1:0)];
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hD = b4NR[c4NR-((c4NR > d4N)?d4N+1:0)];
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b4AR[c4AR] = hA - (hB + hC + hD);
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b4ER[c4ER] = hB - (hA + hC + hD);
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b4IR[c4IR] = hC - (hA + hB + hD);
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b4MR[c4MR] = hD - (hA + hB + hC);
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c4AR++; if (c4AR < 0 || c4AR > d4A) c4AR = 0;
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c4ER++; if (c4ER < 0 || c4ER > d4E) c4ER = 0;
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c4IR++; if (c4IR < 0 || c4IR > d4I) c4IR = 0;
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c4MR++; if (c4MR < 0 || c4MR > d4M) c4MR = 0;
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hA = a4AR[c4AR-((c4AR > d4A)?d4A+1:0)];
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hB = a4ER[c4ER-((c4ER > d4E)?d4E+1:0)];
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hC = a4IR[c4IR-((c4IR > d4I)?d4I+1:0)];
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hD = a4MR[c4MR-((c4MR > d4M)?d4M+1:0)];
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f4DR = hA - (hB + hC + hD);
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f4HR = hB - (hA + hC + hD);
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f4LR = hC - (hA + hB + hD);
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f4PR = hD - (hA + hB + hC);
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mainSampleR = (hA + hB + hC + hD)*0.125;
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hA = b4AR[c4AR-((c4AR > d4A)?d4A+1:0)];
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hB = b4ER[c4ER-((c4ER > d4E)?d4E+1:0)];
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hC = b4IR[c4IR-((c4IR > d4I)?d4I+1:0)];
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hD = b4MR[c4MR-((c4MR > d4M)?d4M+1:0)];
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g4DR = hA - (hB + hC + hD);
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g4HR = hB - (hA + hC + hD);
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g4LR = hC - (hA + hB + hD);
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g4PR = hD - (hA + hB + hC);
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dualmonoSampleR = (hA + hB + hC + hD)*0.125;
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//dual mono version is wider = 1.0 at the center
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//with mainsample 0.0 and 2.0 (only at the edges)
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//with mainsample out of phase when over 1.0
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//couldn't re-do the arrays perfectly, so instead
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//we keep exactly the same cross-matrix,
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//but we flip the sides we're using for initial reverb.
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//then, dualmono remains totally dualmono, and blend a bit in for wideness.
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if (wider < 1.0) {
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inputSampleL = (dualmonoSampleR*wider) + (mainSampleL*(1.0-wider));
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inputSampleR = (dualmonoSampleL*wider) + (mainSampleR*(1.0-wider));
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} else {
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inputSampleL = (dualmonoSampleR*(2.0-wider)) + (mainSampleL*(wider-1.0));
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inputSampleR = (dualmonoSampleL*(2.0-wider)) + (-mainSampleR*(wider-1.0));
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}
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inputSampleL = fmin(fmax(inputSampleL,-2.032610446872596),2.032610446872596);
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long double X = inputSampleL * inputSampleL;
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long double temp = inputSampleL * X;
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inputSampleL -= (temp*0.125); temp *= X;
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inputSampleL += (temp*0.0078125); temp *= X;
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inputSampleL -= (temp*0.000244140625); temp *= X;
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inputSampleL += (temp*0.000003814697265625); temp *= X;
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inputSampleL -= (temp*0.0000000298023223876953125); temp *= X;
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//purestsaturation: sine, except all the corrections
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//retain mantissa of a long double increasing power function
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inputSampleR = fmin(fmax(inputSampleR,-2.032610446872596),2.032610446872596);
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X = inputSampleR * inputSampleR;
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temp = inputSampleR * X;
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inputSampleR -= (temp*0.125); temp *= X;
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inputSampleR += (temp*0.0078125); temp *= X;
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inputSampleR -= (temp*0.000244140625); temp *= X;
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inputSampleR += (temp*0.000003814697265625); temp *= X;
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inputSampleR -= (temp*0.0000000298023223876953125); temp *= X;
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//purestsaturation: sine, except all the corrections
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//retain mantissa of a long double increasing power function
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bez[bez_CL] = bez[bez_BL];
|
|
bez[bez_BL] = bez[bez_AL];
|
|
bez[bez_AL] = inputSampleL;
|
|
bez[bez_SampL] = 0.0;
|
|
|
|
bez[bez_CR] = bez[bez_BR];
|
|
bez[bez_BR] = bez[bez_AR];
|
|
bez[bez_AR] = inputSampleR;
|
|
bez[bez_SampR] = 0.0;
|
|
}
|
|
double X = bez[bez_cycle]*bezTrim;
|
|
double CBL = (bez[bez_CL]*(1.0-X))+(bez[bez_BL]*X);
|
|
double CBR = (bez[bez_CR]*(1.0-X))+(bez[bez_BR]*X);
|
|
double BAL = (bez[bez_BL]*(1.0-X))+(bez[bez_AL]*X);
|
|
double BAR = (bez[bez_BR]*(1.0-X))+(bez[bez_AR]*X);
|
|
inputSampleL = (bez[bez_BL]+(CBL*(1.0-X))+(BAL*X))*-0.25;
|
|
inputSampleR = (bez[bez_BR]+(CBR*(1.0-X))+(BAR*X))*-0.25;
|
|
|
|
bezF[bez_cycle] += derezFreq;
|
|
bezF[bez_SampL] += (inputSampleL * derezFreq);
|
|
bezF[bez_SampR] += (inputSampleR * derezFreq);
|
|
if (bezF[bez_cycle] > 1.0) { //hit the end point and we do a filter sample
|
|
bezF[bez_cycle] = 0.0;
|
|
bezF[bez_CL] = bezF[bez_BL];
|
|
bezF[bez_BL] = bezF[bez_AL];
|
|
bezF[bez_AL] = bezF[bez_SampL];
|
|
bezF[bez_SampL] = 0.0;
|
|
bezF[bez_CR] = bezF[bez_BR];
|
|
bezF[bez_BR] = bezF[bez_AR];
|
|
bezF[bez_AR] = bezF[bez_SampR];
|
|
bezF[bez_SampR] = 0.0;
|
|
}
|
|
X = bezF[bez_cycle]*bezFreqTrim;
|
|
double CBLfreq = (bezF[bez_CL]*(1.0-X))+(bezF[bez_BL]*X);
|
|
double BALfreq = (bezF[bez_BL]*(1.0-X))+(bezF[bez_AL]*X);
|
|
inputSampleL = (bezF[bez_BL]+(CBLfreq*(1.0-X))+(BALfreq*X))*0.5;
|
|
double CBRfreq = (bezF[bez_CR]*(1.0-X))+(bezF[bez_BR]*X);
|
|
double BARfreq = (bezF[bez_BR]*(1.0-X))+(bezF[bez_AR]*X);
|
|
inputSampleR = (bezF[bez_BR]+(CBRfreq*(1.0-X))+(BARfreq*X))*0.5;
|
|
//filtering the reverb separately, after making it
|
|
|
|
inputSampleL = (inputSampleL * wet)+(drySampleL * (1.0-wet));
|
|
inputSampleR = (inputSampleR * wet)+(drySampleR * (1.0-wet));
|
|
|
|
//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 VerbThic::processDoubleReplacing(double **inputs, double **outputs, VstInt32 sampleFrames)
|
|
{
|
|
double* in1 = inputs[0];
|
|
double* in2 = inputs[1];
|
|
double* out1 = outputs[0];
|
|
double* out2 = outputs[1];
|
|
|
|
double overallscale = 1.0;
|
|
overallscale /= 44100.0;
|
|
overallscale *= getSampleRate();
|
|
|
|
double reg4n = 0.03125+((1.0-pow(1.0-A,2.0))*0.03125);
|
|
double attenuate = 1.0 - (1.0-pow(1.0-A,2.0));
|
|
double derez = pow(B,2.0);
|
|
derez = fmin(fmax(derez/overallscale,0.0001),1.0);
|
|
int bezFraction = (int)(1.0/derez);
|
|
double bezTrim = (double)bezFraction/(bezFraction+1.0);
|
|
derez = 1.0 / bezFraction;
|
|
bezTrim = 1.0-(derez*bezTrim);
|
|
//the revision more accurately connects the bezier curves
|
|
double derezFreq = pow(C,2.0);
|
|
derezFreq = fmin(fmax(derezFreq/overallscale,0.0001),1.0);
|
|
int bezFreqFraction = (int)(1.0/derezFreq);
|
|
double bezFreqTrim = (double)bezFreqFraction/(bezFreqFraction+1.0);
|
|
derezFreq = 1.0 / bezFreqFraction;
|
|
bezFreqTrim = 1.0-(derezFreq*bezFreqTrim);
|
|
//the revision more accurately connects the bezier curves
|
|
double wider = D*2.0;
|
|
double wet = E;
|
|
|
|
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;
|
|
|
|
bez[bez_cycle] += derez;
|
|
bez[bez_SampL] += (inputSampleL*attenuate*derez);
|
|
bez[bez_SampR] += (inputSampleR*attenuate*derez);
|
|
if (bez[bez_cycle] > 1.0) { //hit the end point and we do a reverb sample
|
|
bez[bez_cycle] = 0.0;
|
|
double mainSampleL = bez[bez_SampL];
|
|
double dualmonoSampleL = bez[bez_SampR];
|
|
//workaround involves keeping the cross-matrix system,
|
|
//but for initial layering, each side gets each version
|
|
//making blends never quite line up as exactly the same.
|
|
|
|
//left verbs
|
|
a4AL[c4AL] = mainSampleL + (f4DR * reg4n);
|
|
a4BL[c4BL] = mainSampleL + (f4HR * reg4n);
|
|
a4CL[c4CL] = mainSampleL + (f4LR * reg4n);
|
|
a4DL[c4DL] = mainSampleL + (f4PR * reg4n);
|
|
b4AL[c4AL] = dualmonoSampleL + (g4AL * reg4n);
|
|
b4BL[c4BL] = dualmonoSampleL + (g4BL * reg4n);
|
|
b4CL[c4CL] = dualmonoSampleL + (g4CL * reg4n);
|
|
b4DL[c4DL] = dualmonoSampleL + (g4DL * reg4n);
|
|
|
|
c4AL++; if (c4AL < 0 || c4AL > d4A) c4AL = 0;
|
|
c4BL++; if (c4BL < 0 || c4BL > d4B) c4BL = 0;
|
|
c4CL++; if (c4CL < 0 || c4CL > d4C) c4CL = 0;
|
|
c4DL++; if (c4DL < 0 || c4DL > d4D) c4DL = 0;
|
|
|
|
double hA = a4AL[c4AL-((c4AL > d4A)?d4A+1:0)];
|
|
double hB = a4BL[c4BL-((c4BL > d4B)?d4B+1:0)];
|
|
double hC = a4CL[c4CL-((c4CL > d4C)?d4C+1:0)];
|
|
double hD = a4DL[c4DL-((c4DL > d4D)?d4D+1:0)];
|
|
a4EL[c4EL] = hA - (hB + hC + hD);
|
|
a4FL[c4FL] = hB - (hA + hC + hD);
|
|
a4GL[c4GL] = hC - (hA + hB + hD);
|
|
a4HL[c4HL] = hD - (hA + hB + hC);
|
|
hA = b4AL[c4AL-((c4AL > d4A)?d4A+1:0)];
|
|
hB = b4BL[c4BL-((c4BL > d4B)?d4B+1:0)];
|
|
hC = b4CL[c4CL-((c4CL > d4C)?d4C+1:0)];
|
|
hD = b4DL[c4DL-((c4DL > d4D)?d4D+1:0)];
|
|
b4EL[c4EL] = hA - (hB + hC + hD);
|
|
b4FL[c4FL] = hB - (hA + hC + hD);
|
|
b4GL[c4GL] = hC - (hA + hB + hD);
|
|
b4HL[c4HL] = hD - (hA + hB + hC);
|
|
|
|
c4EL++; if (c4EL < 0 || c4EL > d4E) c4EL = 0;
|
|
c4FL++; if (c4FL < 0 || c4FL > d4F) c4FL = 0;
|
|
c4GL++; if (c4GL < 0 || c4GL > d4G) c4GL = 0;
|
|
c4HL++; if (c4HL < 0 || c4HL > d4H) c4HL = 0;
|
|
|
|
hA = a4EL[c4EL-((c4EL > d4E)?d4E+1:0)];
|
|
hB = a4FL[c4FL-((c4FL > d4F)?d4F+1:0)];
|
|
hC = a4GL[c4GL-((c4GL > d4G)?d4G+1:0)];
|
|
hD = a4HL[c4HL-((c4HL > d4H)?d4H+1:0)];
|
|
a4IL[c4IL] = hA - (hB + hC + hD);
|
|
a4JL[c4JL] = hB - (hA + hC + hD);
|
|
a4KL[c4KL] = hC - (hA + hB + hD);
|
|
a4LL[c4LL] = hD - (hA + hB + hC);
|
|
hA = b4EL[c4EL-((c4EL > d4E)?d4E+1:0)];
|
|
hB = b4FL[c4FL-((c4FL > d4F)?d4F+1:0)];
|
|
hC = b4GL[c4GL-((c4GL > d4G)?d4G+1:0)];
|
|
hD = b4HL[c4HL-((c4HL > d4H)?d4H+1:0)];
|
|
b4IL[c4IL] = hA - (hB + hC + hD);
|
|
b4JL[c4JL] = hB - (hA + hC + hD);
|
|
b4KL[c4KL] = hC - (hA + hB + hD);
|
|
b4LL[c4LL] = hD - (hA + hB + hC);
|
|
|
|
c4IL++; if (c4IL < 0 || c4IL > d4I) c4IL = 0;
|
|
c4JL++; if (c4JL < 0 || c4JL > d4J) c4JL = 0;
|
|
c4KL++; if (c4KL < 0 || c4KL > d4K) c4KL = 0;
|
|
c4LL++; if (c4LL < 0 || c4LL > d4L) c4LL = 0;
|
|
|
|
hA = a4IL[c4IL-((c4IL > d4I)?d4I+1:0)];
|
|
hB = a4JL[c4JL-((c4JL > d4J)?d4J+1:0)];
|
|
hC = a4KL[c4KL-((c4KL > d4K)?d4K+1:0)];
|
|
hD = a4LL[c4LL-((c4LL > d4L)?d4L+1:0)];
|
|
a4ML[c4ML] = hA - (hB + hC + hD);
|
|
a4NL[c4NL] = hB - (hA + hC + hD);
|
|
a4OL[c4OL] = hC - (hA + hB + hD);
|
|
a4PL[c4PL] = hD - (hA + hB + hC);
|
|
hA = b4IL[c4IL-((c4IL > d4I)?d4I+1:0)];
|
|
hB = b4JL[c4JL-((c4JL > d4J)?d4J+1:0)];
|
|
hC = b4KL[c4KL-((c4KL > d4K)?d4K+1:0)];
|
|
hD = b4LL[c4LL-((c4LL > d4L)?d4L+1:0)];
|
|
b4ML[c4ML] = hA - (hB + hC + hD);
|
|
b4NL[c4NL] = hB - (hA + hC + hD);
|
|
b4OL[c4OL] = hC - (hA + hB + hD);
|
|
b4PL[c4PL] = hD - (hA + hB + hC);
|
|
|
|
c4ML++; if (c4ML < 0 || c4ML > d4M) c4ML = 0;
|
|
c4NL++; if (c4NL < 0 || c4NL > d4N) c4NL = 0;
|
|
c4OL++; if (c4OL < 0 || c4OL > d4O) c4OL = 0;
|
|
c4PL++; if (c4PL < 0 || c4PL > d4P) c4PL = 0;
|
|
|
|
hA = a4ML[c4ML-((c4ML > d4M)?d4M+1:0)];
|
|
hB = a4NL[c4NL-((c4NL > d4N)?d4N+1:0)];
|
|
hC = a4OL[c4OL-((c4OL > d4O)?d4O+1:0)];
|
|
hD = a4PL[c4PL-((c4PL > d4P)?d4P+1:0)];
|
|
f4AL = hA - (hB + hC + hD);
|
|
f4BL = hB - (hA + hC + hD);
|
|
f4CL = hC - (hA + hB + hD);
|
|
f4DL = hD - (hA + hB + hC);//not actually crosschannel yet
|
|
mainSampleL = (hA + hB + hC + hD)*0.125;
|
|
|
|
hA = b4ML[c4ML-((c4ML > d4M)?d4M+1:0)];
|
|
hB = b4NL[c4NL-((c4NL > d4N)?d4N+1:0)];
|
|
hC = b4OL[c4OL-((c4OL > d4O)?d4O+1:0)];
|
|
hD = b4PL[c4PL-((c4PL > d4P)?d4P+1:0)];
|
|
g4AL = hA - (hB + hC + hD);
|
|
g4BL = hB - (hA + hC + hD);
|
|
g4CL = hC - (hA + hB + hD);
|
|
g4DL = hD - (hA + hB + hC);
|
|
dualmonoSampleL = (hA + hB + hC + hD)*0.125;
|
|
|
|
double mainSampleR = bez[bez_SampR]; //begin primary reverb
|
|
double dualmonoSampleR = bez[bez_SampL];
|
|
|
|
//right verbs
|
|
a4DR[c4DR] = mainSampleR + (f4AL * reg4n);
|
|
a4HR[c4HR] = mainSampleR + (f4BL * reg4n);
|
|
a4LR[c4LR] = mainSampleR + (f4CL * reg4n);
|
|
a4PR[c4PR] = mainSampleR + (f4DL * reg4n);
|
|
b4DR[c4DR] = dualmonoSampleR + (g4DR * reg4n);
|
|
b4HR[c4HR] = dualmonoSampleR + (g4HR * reg4n);
|
|
b4LR[c4LR] = dualmonoSampleR + (g4LR * reg4n);
|
|
b4PR[c4PR] = dualmonoSampleR + (g4PR * reg4n);
|
|
|
|
c4DR++; if (c4DR < 0 || c4DR > d4D) c4DR = 0;
|
|
c4HR++; if (c4HR < 0 || c4HR > d4H) c4HR = 0;
|
|
c4LR++; if (c4LR < 0 || c4LR > d4L) c4LR = 0;
|
|
c4PR++; if (c4PR < 0 || c4PR > d4P) c4PR = 0;
|
|
|
|
hA = a4DR[c4DR-((c4DR > d4D)?d4D+1:0)];
|
|
hB = a4HR[c4HR-((c4HR > d4H)?d4H+1:0)];
|
|
hC = a4LR[c4LR-((c4LR > d4L)?d4L+1:0)];
|
|
hD = a4PR[c4PR-((c4PR > d4P)?d4P+1:0)];
|
|
a4CR[c4CR] = hA - (hB + hC + hD);
|
|
a4GR[c4GR] = hB - (hA + hC + hD);
|
|
a4KR[c4KR] = hC - (hA + hB + hD);
|
|
a4OR[c4OR] = hD - (hA + hB + hC);
|
|
hA = b4DR[c4DR-((c4DR > d4D)?d4D+1:0)];
|
|
hB = b4HR[c4HR-((c4HR > d4H)?d4H+1:0)];
|
|
hC = b4LR[c4LR-((c4LR > d4L)?d4L+1:0)];
|
|
hD = b4PR[c4PR-((c4PR > d4P)?d4P+1:0)];
|
|
b4CR[c4CR] = hA - (hB + hC + hD);
|
|
b4GR[c4GR] = hB - (hA + hC + hD);
|
|
b4KR[c4KR] = hC - (hA + hB + hD);
|
|
b4OR[c4OR] = hD - (hA + hB + hC);
|
|
|
|
c4CR++; if (c4CR < 0 || c4CR > d4C) c4CR = 0;
|
|
c4GR++; if (c4GR < 0 || c4GR > d4G) c4GR = 0;
|
|
c4KR++; if (c4KR < 0 || c4KR > d4K) c4KR = 0;
|
|
c4OR++; if (c4OR < 0 || c4OR > d4O) c4OR = 0;
|
|
|
|
hA = a4CR[c4CR-((c4CR > d4C)?d4C+1:0)];
|
|
hB = a4GR[c4GR-((c4GR > d4G)?d4G+1:0)];
|
|
hC = a4KR[c4KR-((c4KR > d4K)?d4K+1:0)];
|
|
hD = a4OR[c4OR-((c4OR > d4O)?d4O+1:0)];
|
|
a4BR[c4BR] = hA - (hB + hC + hD);
|
|
a4FR[c4FR] = hB - (hA + hC + hD);
|
|
a4JR[c4JR] = hC - (hA + hB + hD);
|
|
a4NR[c4NR] = hD - (hA + hB + hC);
|
|
hA = b4CR[c4CR-((c4CR > d4C)?d4C+1:0)];
|
|
hB = b4GR[c4GR-((c4GR > d4G)?d4G+1:0)];
|
|
hC = b4KR[c4KR-((c4KR > d4K)?d4K+1:0)];
|
|
hD = b4OR[c4OR-((c4OR > d4O)?d4O+1:0)];
|
|
b4BR[c4BR] = hA - (hB + hC + hD);
|
|
b4FR[c4FR] = hB - (hA + hC + hD);
|
|
b4JR[c4JR] = hC - (hA + hB + hD);
|
|
b4NR[c4NR] = hD - (hA + hB + hC);
|
|
|
|
c4BR++; if (c4BR < 0 || c4BR > d4B) c4BR = 0;
|
|
c4FR++; if (c4FR < 0 || c4FR > d4F) c4FR = 0;
|
|
c4JR++; if (c4JR < 0 || c4JR > d4J) c4JR = 0;
|
|
c4NR++; if (c4NR < 0 || c4NR > d4N) c4NR = 0;
|
|
|
|
hA = a4BR[c4BR-((c4BR > d4B)?d4B+1:0)];
|
|
hB = a4FR[c4FR-((c4FR > d4F)?d4F+1:0)];
|
|
hC = a4JR[c4JR-((c4JR > d4J)?d4J+1:0)];
|
|
hD = a4NR[c4NR-((c4NR > d4N)?d4N+1:0)];
|
|
a4AR[c4AR] = hA - (hB + hC + hD);
|
|
a4ER[c4ER] = hB - (hA + hC + hD);
|
|
a4IR[c4IR] = hC - (hA + hB + hD);
|
|
a4MR[c4MR] = hD - (hA + hB + hC);
|
|
hA = b4BR[c4BR-((c4BR > d4B)?d4B+1:0)];
|
|
hB = b4FR[c4FR-((c4FR > d4F)?d4F+1:0)];
|
|
hC = b4JR[c4JR-((c4JR > d4J)?d4J+1:0)];
|
|
hD = b4NR[c4NR-((c4NR > d4N)?d4N+1:0)];
|
|
b4AR[c4AR] = hA - (hB + hC + hD);
|
|
b4ER[c4ER] = hB - (hA + hC + hD);
|
|
b4IR[c4IR] = hC - (hA + hB + hD);
|
|
b4MR[c4MR] = hD - (hA + hB + hC);
|
|
|
|
c4AR++; if (c4AR < 0 || c4AR > d4A) c4AR = 0;
|
|
c4ER++; if (c4ER < 0 || c4ER > d4E) c4ER = 0;
|
|
c4IR++; if (c4IR < 0 || c4IR > d4I) c4IR = 0;
|
|
c4MR++; if (c4MR < 0 || c4MR > d4M) c4MR = 0;
|
|
|
|
hA = a4AR[c4AR-((c4AR > d4A)?d4A+1:0)];
|
|
hB = a4ER[c4ER-((c4ER > d4E)?d4E+1:0)];
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hC = a4IR[c4IR-((c4IR > d4I)?d4I+1:0)];
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hD = a4MR[c4MR-((c4MR > d4M)?d4M+1:0)];
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f4DR = hA - (hB + hC + hD);
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f4HR = hB - (hA + hC + hD);
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f4LR = hC - (hA + hB + hD);
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f4PR = hD - (hA + hB + hC);
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mainSampleR = (hA + hB + hC + hD)*0.125;
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|
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hA = b4AR[c4AR-((c4AR > d4A)?d4A+1:0)];
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hB = b4ER[c4ER-((c4ER > d4E)?d4E+1:0)];
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hC = b4IR[c4IR-((c4IR > d4I)?d4I+1:0)];
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hD = b4MR[c4MR-((c4MR > d4M)?d4M+1:0)];
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g4DR = hA - (hB + hC + hD);
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g4HR = hB - (hA + hC + hD);
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g4LR = hC - (hA + hB + hD);
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g4PR = hD - (hA + hB + hC);
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dualmonoSampleR = (hA + hB + hC + hD)*0.125;
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//dual mono version is wider = 1.0 at the center
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//with mainsample 0.0 and 2.0 (only at the edges)
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//with mainsample out of phase when over 1.0
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//couldn't re-do the arrays perfectly, so instead
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//we keep exactly the same cross-matrix,
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//but we flip the sides we're using for initial reverb.
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//then, dualmono remains totally dualmono, and blend a bit in for wideness.
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|
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if (wider < 1.0) {
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inputSampleL = (dualmonoSampleR*wider) + (mainSampleL*(1.0-wider));
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inputSampleR = (dualmonoSampleL*wider) + (mainSampleR*(1.0-wider));
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} else {
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inputSampleL = (dualmonoSampleR*(2.0-wider)) + (mainSampleL*(wider-1.0));
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inputSampleR = (dualmonoSampleL*(2.0-wider)) + (-mainSampleR*(wider-1.0));
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}
|
|
|
|
|
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inputSampleL = fmin(fmax(inputSampleL,-2.032610446872596),2.032610446872596);
|
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long double X = inputSampleL * inputSampleL;
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long double temp = inputSampleL * X;
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inputSampleL -= (temp*0.125); temp *= X;
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inputSampleL += (temp*0.0078125); temp *= X;
|
|
inputSampleL -= (temp*0.000244140625); temp *= X;
|
|
inputSampleL += (temp*0.000003814697265625); temp *= X;
|
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inputSampleL -= (temp*0.0000000298023223876953125); temp *= X;
|
|
//purestsaturation: sine, except all the corrections
|
|
//retain mantissa of a long double increasing power function
|
|
inputSampleR = fmin(fmax(inputSampleR,-2.032610446872596),2.032610446872596);
|
|
X = inputSampleR * inputSampleR;
|
|
temp = inputSampleR * X;
|
|
inputSampleR -= (temp*0.125); temp *= X;
|
|
inputSampleR += (temp*0.0078125); temp *= X;
|
|
inputSampleR -= (temp*0.000244140625); temp *= X;
|
|
inputSampleR += (temp*0.000003814697265625); temp *= X;
|
|
inputSampleR -= (temp*0.0000000298023223876953125); temp *= X;
|
|
//purestsaturation: sine, except all the corrections
|
|
//retain mantissa of a long double increasing power function
|
|
|
|
bez[bez_CL] = bez[bez_BL];
|
|
bez[bez_BL] = bez[bez_AL];
|
|
bez[bez_AL] = inputSampleL;
|
|
bez[bez_SampL] = 0.0;
|
|
|
|
bez[bez_CR] = bez[bez_BR];
|
|
bez[bez_BR] = bez[bez_AR];
|
|
bez[bez_AR] = inputSampleR;
|
|
bez[bez_SampR] = 0.0;
|
|
}
|
|
double X = bez[bez_cycle]*bezTrim;
|
|
double CBL = (bez[bez_CL]*(1.0-X))+(bez[bez_BL]*X);
|
|
double CBR = (bez[bez_CR]*(1.0-X))+(bez[bez_BR]*X);
|
|
double BAL = (bez[bez_BL]*(1.0-X))+(bez[bez_AL]*X);
|
|
double BAR = (bez[bez_BR]*(1.0-X))+(bez[bez_AR]*X);
|
|
inputSampleL = (bez[bez_BL]+(CBL*(1.0-X))+(BAL*X))*-0.25;
|
|
inputSampleR = (bez[bez_BR]+(CBR*(1.0-X))+(BAR*X))*-0.25;
|
|
|
|
bezF[bez_cycle] += derezFreq;
|
|
bezF[bez_SampL] += (inputSampleL * derezFreq);
|
|
bezF[bez_SampR] += (inputSampleR * derezFreq);
|
|
if (bezF[bez_cycle] > 1.0) { //hit the end point and we do a filter sample
|
|
bezF[bez_cycle] = 0.0;
|
|
bezF[bez_CL] = bezF[bez_BL];
|
|
bezF[bez_BL] = bezF[bez_AL];
|
|
bezF[bez_AL] = bezF[bez_SampL];
|
|
bezF[bez_SampL] = 0.0;
|
|
bezF[bez_CR] = bezF[bez_BR];
|
|
bezF[bez_BR] = bezF[bez_AR];
|
|
bezF[bez_AR] = bezF[bez_SampR];
|
|
bezF[bez_SampR] = 0.0;
|
|
}
|
|
X = bezF[bez_cycle]*bezFreqTrim;
|
|
double CBLfreq = (bezF[bez_CL]*(1.0-X))+(bezF[bez_BL]*X);
|
|
double BALfreq = (bezF[bez_BL]*(1.0-X))+(bezF[bez_AL]*X);
|
|
inputSampleL = (bezF[bez_BL]+(CBLfreq*(1.0-X))+(BALfreq*X))*0.5;
|
|
double CBRfreq = (bezF[bez_CR]*(1.0-X))+(bezF[bez_BR]*X);
|
|
double BARfreq = (bezF[bez_BR]*(1.0-X))+(bezF[bez_AR]*X);
|
|
inputSampleR = (bezF[bez_BR]+(CBRfreq*(1.0-X))+(BARfreq*X))*0.5;
|
|
//filtering the reverb separately, after making it
|
|
|
|
inputSampleL = (inputSampleL * wet)+(drySampleL * (1.0-wet));
|
|
inputSampleR = (inputSampleR * wet)+(drySampleR * (1.0-wet));
|
|
|
|
//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++;
|
|
}
|
|
}
|