/* ======================================== * ResEQ - ResEQ.h * Copyright (c) 2016 airwindows, All rights reserved * ======================================== */ #ifndef __ResEQ_H #include "ResEQ.h" #endif void ResEQ::processReplacing(float **inputs, float **outputs, VstInt32 sampleFrames) { float* in1 = inputs[0]; float* in2 = inputs[1]; float* out1 = outputs[0]; float* out2 = outputs[1]; double overallscale = 1.0; overallscale /= 44100.0; overallscale *= getSampleRate(); double v1 = A; double v2 = B; double v3 = C; double v4 = D; double v5 = E; double v6 = F; double v7 = G; double v8 = H; double f1 = pow(v1,2); double f2 = pow(v2,2); double f3 = pow(v3,2); double f4 = pow(v4,2); double f5 = pow(v5,2); double f6 = pow(v6,2); double f7 = pow(v7,2); double f8 = pow(v8,2); double wet = I; double falloff; v1 += 0.2; v2 += 0.2; v3 += 0.2; v4 += 0.2; v5 += 0.2; v6 += 0.2; v7 += 0.2; v8 += 0.2; v1 /= overallscale; v2 /= overallscale; v3 /= overallscale; v4 /= overallscale; v5 /= overallscale; v6 /= overallscale; v7 /= overallscale; v8 /= overallscale; //each process frame we'll update some of the kernel frames. That way we don't have to crunch the whole thing at once, //and we can load a LOT more resonant peaks into the kernel. framenumber += 1; if (framenumber > 59) framenumber = 1; falloff = sin(framenumber / 19.098992); fL[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fL[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fL[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fL[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fL[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fL[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fL[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fL[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fL[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fL[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fL[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fL[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fL[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fL[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fL[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fL[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fL[framenumber] += (cos(framenumber * f8) * falloff * v8); fR[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fR[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fR[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fR[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fR[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fR[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fR[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fR[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fR[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fR[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fR[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fR[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fR[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fR[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fR[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fR[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fR[framenumber] += (cos(framenumber * f8) * falloff * v8); framenumber += 1; if (framenumber > 59) framenumber = 1; falloff = sin(framenumber / 19.098992); fL[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fL[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fL[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fL[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fL[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fL[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fL[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fL[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fL[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fL[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fL[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fL[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fL[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fL[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fL[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fL[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fL[framenumber] += (cos(framenumber * f8) * falloff * v8); fR[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fR[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fR[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fR[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fR[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fR[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fR[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fR[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fR[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fR[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fR[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fR[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fR[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fR[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fR[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fR[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fR[framenumber] += (cos(framenumber * f8) * falloff * v8); //done updating the kernel for this go-round while (--sampleFrames >= 0) { long double inputSampleL = *in1; long double inputSampleR = *in2; if (fabs(inputSampleL)<1.18e-37) inputSampleL = fpd * 1.18e-37; if (fabs(inputSampleR)<1.18e-37) inputSampleR = fpd * 1.18e-37; long double drySampleL = inputSampleL; long double drySampleR = inputSampleR; 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] * fL[1]); inputSampleL += (bL[2] * fL[2]); inputSampleL += (bL[3] * fL[3]); inputSampleL += (bL[4] * fL[4]); inputSampleL += (bL[5] * fL[5]); inputSampleL += (bL[6] * fL[6]); inputSampleL += (bL[7] * fL[7]); inputSampleL += (bL[8] * fL[8]); inputSampleL += (bL[9] * fL[9]); inputSampleL += (bL[10] * fL[10]); inputSampleL += (bL[11] * fL[11]); inputSampleL += (bL[12] * fL[12]); inputSampleL += (bL[13] * fL[13]); inputSampleL += (bL[14] * fL[14]); inputSampleL += (bL[15] * fL[15]); inputSampleL += (bL[16] * fL[16]); inputSampleL += (bL[17] * fL[17]); inputSampleL += (bL[18] * fL[18]); inputSampleL += (bL[19] * fL[19]); inputSampleL += (bL[20] * fL[20]); inputSampleL += (bL[21] * fL[21]); inputSampleL += (bL[22] * fL[22]); inputSampleL += (bL[23] * fL[23]); inputSampleL += (bL[24] * fL[24]); inputSampleL += (bL[25] * fL[25]); inputSampleL += (bL[26] * fL[26]); inputSampleL += (bL[27] * fL[27]); inputSampleL += (bL[28] * fL[28]); inputSampleL += (bL[29] * fL[29]); inputSampleL += (bL[30] * fL[30]); inputSampleL += (bL[31] * fL[31]); inputSampleL += (bL[32] * fL[32]); inputSampleL += (bL[33] * fL[33]); inputSampleL += (bL[34] * fL[34]); inputSampleL += (bL[35] * fL[35]); inputSampleL += (bL[36] * fL[36]); inputSampleL += (bL[37] * fL[37]); inputSampleL += (bL[38] * fL[38]); inputSampleL += (bL[39] * fL[39]); inputSampleL += (bL[40] * fL[40]); inputSampleL += (bL[41] * fL[41]); inputSampleL += (bL[42] * fL[42]); inputSampleL += (bL[43] * fL[43]); inputSampleL += (bL[44] * fL[44]); inputSampleL += (bL[45] * fL[45]); inputSampleL += (bL[46] * fL[46]); inputSampleL += (bL[47] * fL[47]); inputSampleL += (bL[48] * fL[48]); inputSampleL += (bL[49] * fL[49]); inputSampleL += (bL[50] * fL[50]); inputSampleL += (bL[51] * fL[51]); inputSampleL += (bL[52] * fL[52]); inputSampleL += (bL[53] * fL[53]); inputSampleL += (bL[54] * fL[54]); inputSampleL += (bL[55] * fL[55]); inputSampleL += (bL[56] * fL[56]); inputSampleL += (bL[57] * fL[57]); inputSampleL += (bL[58] * fL[58]); inputSampleL += (bL[59] * fL[59]); inputSampleL /= 12.0; //inlined- this is our little EQ kernel. Longer will give better tightness on bass frequencies. //Note that normal programmers will make this a loop, which isn't much slower if at all, on modern CPUs. //It was unrolled more or less to show how much is done when you define a loop like that: it's easy to specify stuff where a lot of grinding is done. 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] * fR[1]); inputSampleR += (bR[2] * fR[2]); inputSampleR += (bR[3] * fR[3]); inputSampleR += (bR[4] * fR[4]); inputSampleR += (bR[5] * fR[5]); inputSampleR += (bR[6] * fR[6]); inputSampleR += (bR[7] * fR[7]); inputSampleR += (bR[8] * fR[8]); inputSampleR += (bR[9] * fR[9]); inputSampleR += (bR[10] * fR[10]); inputSampleR += (bR[11] * fR[11]); inputSampleR += (bR[12] * fR[12]); inputSampleR += (bR[13] * fR[13]); inputSampleR += (bR[14] * fR[14]); inputSampleR += (bR[15] * fR[15]); inputSampleR += (bR[16] * fR[16]); inputSampleR += (bR[17] * fR[17]); inputSampleR += (bR[18] * fR[18]); inputSampleR += (bR[19] * fR[19]); inputSampleR += (bR[20] * fR[20]); inputSampleR += (bR[21] * fR[21]); inputSampleR += (bR[22] * fR[22]); inputSampleR += (bR[23] * fR[23]); inputSampleR += (bR[24] * fR[24]); inputSampleR += (bR[25] * fR[25]); inputSampleR += (bR[26] * fR[26]); inputSampleR += (bR[27] * fR[27]); inputSampleR += (bR[28] * fR[28]); inputSampleR += (bR[29] * fR[29]); inputSampleR += (bR[30] * fR[30]); inputSampleR += (bR[31] * fR[31]); inputSampleR += (bR[32] * fR[32]); inputSampleR += (bR[33] * fR[33]); inputSampleR += (bR[34] * fR[34]); inputSampleR += (bR[35] * fR[35]); inputSampleR += (bR[36] * fR[36]); inputSampleR += (bR[37] * fR[37]); inputSampleR += (bR[38] * fR[38]); inputSampleR += (bR[39] * fR[39]); inputSampleR += (bR[40] * fR[40]); inputSampleR += (bR[41] * fR[41]); inputSampleR += (bR[42] * fR[42]); inputSampleR += (bR[43] * fR[43]); inputSampleR += (bR[44] * fR[44]); inputSampleR += (bR[45] * fR[45]); inputSampleR += (bR[46] * fR[46]); inputSampleR += (bR[47] * fR[47]); inputSampleR += (bR[48] * fR[48]); inputSampleR += (bR[49] * fR[49]); inputSampleR += (bR[50] * fR[50]); inputSampleR += (bR[51] * fR[51]); inputSampleR += (bR[52] * fR[52]); inputSampleR += (bR[53] * fR[53]); inputSampleR += (bR[54] * fR[54]); inputSampleR += (bR[55] * fR[55]); inputSampleR += (bR[56] * fR[56]); inputSampleR += (bR[57] * fR[57]); inputSampleR += (bR[58] * fR[58]); inputSampleR += (bR[59] * fR[59]); inputSampleR /= 12.0; //inlined- this is our little EQ kernel. Longer will give better tightness on bass frequencies. //Note that normal programmers will make this a loop, which isn't much slower if at all, on modern CPUs. //It was unrolled more or less to show how much is done when you define a loop like that: it's easy to specify stuff where a lot of grinding is done. if (wet !=1.0) { 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); fpd ^= fpd << 13; fpd ^= fpd >> 17; fpd ^= fpd << 5; inputSampleL += ((double(fpd)-uint32_t(0x7fffffff)) * 5.5e-36l * pow(2,expon+62)); frexpf((float)inputSampleR, &expon); fpd ^= fpd << 13; fpd ^= fpd >> 17; fpd ^= fpd << 5; inputSampleR += ((double(fpd)-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 ResEQ::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 v1 = A; double v2 = B; double v3 = C; double v4 = D; double v5 = E; double v6 = F; double v7 = G; double v8 = H; double f1 = pow(v1,2); double f2 = pow(v2,2); double f3 = pow(v3,2); double f4 = pow(v4,2); double f5 = pow(v5,2); double f6 = pow(v6,2); double f7 = pow(v7,2); double f8 = pow(v8,2); double wet = I; double falloff; v1 += 0.2; v2 += 0.2; v3 += 0.2; v4 += 0.2; v5 += 0.2; v6 += 0.2; v7 += 0.2; v8 += 0.2; v1 /= overallscale; v2 /= overallscale; v3 /= overallscale; v4 /= overallscale; v5 /= overallscale; v6 /= overallscale; v7 /= overallscale; v8 /= overallscale; //each process frame we'll update some of the kernel frames. That way we don't have to crunch the whole thing at once, //and we can load a LOT more resonant peaks into the kernel. framenumber += 1; if (framenumber > 59) framenumber = 1; falloff = sin(framenumber / 19.098992); fL[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fL[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fL[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fL[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fL[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fL[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fL[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fL[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fL[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fL[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fL[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fL[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fL[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fL[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fL[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fL[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fL[framenumber] += (cos(framenumber * f8) * falloff * v8); fR[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fR[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fR[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fR[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fR[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fR[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fR[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fR[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fR[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fR[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fR[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fR[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fR[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fR[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fR[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fR[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fR[framenumber] += (cos(framenumber * f8) * falloff * v8); framenumber += 1; if (framenumber > 59) framenumber = 1; falloff = sin(framenumber / 19.098992); fL[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fL[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fL[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fL[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fL[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fL[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fL[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fL[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fL[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fL[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fL[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fL[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fL[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fL[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fL[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fL[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fL[framenumber] += (cos(framenumber * f8) * falloff * v8); fR[framenumber] = 0.0; if ((framenumber * f1) < 1.57079633) fR[framenumber] += (sin((framenumber * f1)*2.0) * falloff * v1); else fR[framenumber] += (cos(framenumber * f1) * falloff * v1); if ((framenumber * f2) < 1.57079633) fR[framenumber] += (sin((framenumber * f2)*2.0) * falloff * v2); else fR[framenumber] += (cos(framenumber * f2) * falloff * v2); if ((framenumber * f3) < 1.57079633) fR[framenumber] += (sin((framenumber * f3)*2.0) * falloff * v3); else fR[framenumber] += (cos(framenumber * f3) * falloff * v3); if ((framenumber * f4) < 1.57079633) fR[framenumber] += (sin((framenumber * f4)*2.0) * falloff * v4); else fR[framenumber] += (cos(framenumber * f4) * falloff * v4); if ((framenumber * f5) < 1.57079633) fR[framenumber] += (sin((framenumber * f5)*2.0) * falloff * v5); else fR[framenumber] += (cos(framenumber * f5) * falloff * v5); if ((framenumber * f6) < 1.57079633) fR[framenumber] += (sin((framenumber * f6)*2.0) * falloff * v6); else fR[framenumber] += (cos(framenumber * f6) * falloff * v6); if ((framenumber * f7) < 1.57079633) fR[framenumber] += (sin((framenumber * f7)*2.0) * falloff * v7); else fR[framenumber] += (cos(framenumber * f7) * falloff * v7); if ((framenumber * f8) < 1.57079633) fR[framenumber] += (sin((framenumber * f8)*2.0) * falloff * v8); else fR[framenumber] += (cos(framenumber * f8) * falloff * v8); //done updating the kernel for this go-round while (--sampleFrames >= 0) { long double inputSampleL = *in1; long double inputSampleR = *in2; if (fabs(inputSampleL)<1.18e-43) inputSampleL = fpd * 1.18e-43; if (fabs(inputSampleR)<1.18e-43) inputSampleR = fpd * 1.18e-43; long double drySampleL = inputSampleL; long double drySampleR = inputSampleR; 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] * fL[1]); inputSampleL += (bL[2] * fL[2]); inputSampleL += (bL[3] * fL[3]); inputSampleL += (bL[4] * fL[4]); inputSampleL += (bL[5] * fL[5]); inputSampleL += (bL[6] * fL[6]); inputSampleL += (bL[7] * fL[7]); inputSampleL += (bL[8] * fL[8]); inputSampleL += (bL[9] * fL[9]); inputSampleL += (bL[10] * fL[10]); inputSampleL += (bL[11] * fL[11]); inputSampleL += (bL[12] * fL[12]); inputSampleL += (bL[13] * fL[13]); inputSampleL += (bL[14] * fL[14]); inputSampleL += (bL[15] * fL[15]); inputSampleL += (bL[16] * fL[16]); inputSampleL += (bL[17] * fL[17]); inputSampleL += (bL[18] * fL[18]); inputSampleL += (bL[19] * fL[19]); inputSampleL += (bL[20] * fL[20]); inputSampleL += (bL[21] * fL[21]); inputSampleL += (bL[22] * fL[22]); inputSampleL += (bL[23] * fL[23]); inputSampleL += (bL[24] * fL[24]); inputSampleL += (bL[25] * fL[25]); inputSampleL += (bL[26] * fL[26]); inputSampleL += (bL[27] * fL[27]); inputSampleL += (bL[28] * fL[28]); inputSampleL += (bL[29] * fL[29]); inputSampleL += (bL[30] * fL[30]); inputSampleL += (bL[31] * fL[31]); inputSampleL += (bL[32] * fL[32]); inputSampleL += (bL[33] * fL[33]); inputSampleL += (bL[34] * fL[34]); inputSampleL += (bL[35] * fL[35]); inputSampleL += (bL[36] * fL[36]); inputSampleL += (bL[37] * fL[37]); inputSampleL += (bL[38] * fL[38]); inputSampleL += (bL[39] * fL[39]); inputSampleL += (bL[40] * fL[40]); inputSampleL += (bL[41] * fL[41]); inputSampleL += (bL[42] * fL[42]); inputSampleL += (bL[43] * fL[43]); inputSampleL += (bL[44] * fL[44]); inputSampleL += (bL[45] * fL[45]); inputSampleL += (bL[46] * fL[46]); inputSampleL += (bL[47] * fL[47]); inputSampleL += (bL[48] * fL[48]); inputSampleL += (bL[49] * fL[49]); inputSampleL += (bL[50] * fL[50]); inputSampleL += (bL[51] * fL[51]); inputSampleL += (bL[52] * fL[52]); inputSampleL += (bL[53] * fL[53]); inputSampleL += (bL[54] * fL[54]); inputSampleL += (bL[55] * fL[55]); inputSampleL += (bL[56] * fL[56]); inputSampleL += (bL[57] * fL[57]); inputSampleL += (bL[58] * fL[58]); inputSampleL += (bL[59] * fL[59]); inputSampleL /= 12.0; //inlined- this is our little EQ kernel. Longer will give better tightness on bass frequencies. //Note that normal programmers will make this a loop, which isn't much slower if at all, on modern CPUs. //It was unrolled more or less to show how much is done when you define a loop like that: it's easy to specify stuff where a lot of grinding is done. 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] * fR[1]); inputSampleR += (bR[2] * fR[2]); inputSampleR += (bR[3] * fR[3]); inputSampleR += (bR[4] * fR[4]); inputSampleR += (bR[5] * fR[5]); inputSampleR += (bR[6] * fR[6]); inputSampleR += (bR[7] * fR[7]); inputSampleR += (bR[8] * fR[8]); inputSampleR += (bR[9] * fR[9]); inputSampleR += (bR[10] * fR[10]); inputSampleR += (bR[11] * fR[11]); inputSampleR += (bR[12] * fR[12]); inputSampleR += (bR[13] * fR[13]); inputSampleR += (bR[14] * fR[14]); inputSampleR += (bR[15] * fR[15]); inputSampleR += (bR[16] * fR[16]); inputSampleR += (bR[17] * fR[17]); inputSampleR += (bR[18] * fR[18]); inputSampleR += (bR[19] * fR[19]); inputSampleR += (bR[20] * fR[20]); inputSampleR += (bR[21] * fR[21]); inputSampleR += (bR[22] * fR[22]); inputSampleR += (bR[23] * fR[23]); inputSampleR += (bR[24] * fR[24]); inputSampleR += (bR[25] * fR[25]); inputSampleR += (bR[26] * fR[26]); inputSampleR += (bR[27] * fR[27]); inputSampleR += (bR[28] * fR[28]); inputSampleR += (bR[29] * fR[29]); inputSampleR += (bR[30] * fR[30]); inputSampleR += (bR[31] * fR[31]); inputSampleR += (bR[32] * fR[32]); inputSampleR += (bR[33] * fR[33]); inputSampleR += (bR[34] * fR[34]); inputSampleR += (bR[35] * fR[35]); inputSampleR += (bR[36] * fR[36]); inputSampleR += (bR[37] * fR[37]); inputSampleR += (bR[38] * fR[38]); inputSampleR += (bR[39] * fR[39]); inputSampleR += (bR[40] * fR[40]); inputSampleR += (bR[41] * fR[41]); inputSampleR += (bR[42] * fR[42]); inputSampleR += (bR[43] * fR[43]); inputSampleR += (bR[44] * fR[44]); inputSampleR += (bR[45] * fR[45]); inputSampleR += (bR[46] * fR[46]); inputSampleR += (bR[47] * fR[47]); inputSampleR += (bR[48] * fR[48]); inputSampleR += (bR[49] * fR[49]); inputSampleR += (bR[50] * fR[50]); inputSampleR += (bR[51] * fR[51]); inputSampleR += (bR[52] * fR[52]); inputSampleR += (bR[53] * fR[53]); inputSampleR += (bR[54] * fR[54]); inputSampleR += (bR[55] * fR[55]); inputSampleR += (bR[56] * fR[56]); inputSampleR += (bR[57] * fR[57]); inputSampleR += (bR[58] * fR[58]); inputSampleR += (bR[59] * fR[59]); inputSampleR /= 12.0; //inlined- this is our little EQ kernel. Longer will give better tightness on bass frequencies. //Note that normal programmers will make this a loop, which isn't much slower if at all, on modern CPUs. //It was unrolled more or less to show how much is done when you define a loop like that: it's easy to specify stuff where a lot of grinding is done. if (wet !=1.0) { 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); fpd ^= fpd << 13; fpd ^= fpd >> 17; fpd ^= fpd << 5; inputSampleL += ((double(fpd)-uint32_t(0x7fffffff)) * 1.1e-44l * pow(2,expon+62)); frexp((double)inputSampleR, &expon); fpd ^= fpd << 13; fpd ^= fpd >> 17; fpd ^= fpd << 5; inputSampleR += ((double(fpd)-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++; } }