#pragma once #include #include namespace trnr { // modeled tube preamp based on tube2 by Chris Johnson class aw_tube2 { public: aw_tube2() { samplerate = 44100; A = 0.5; B = 0.5; previousSampleA = 0.0; previousSampleB = 0.0; previousSampleC = 0.0; previousSampleD = 0.0; previousSampleE = 0.0; previousSampleF = 0.0; fpdL = 1.0; while (fpdL < 16386) fpdL = rand() * UINT32_MAX; fpdR = 1.0; while (fpdR < 16386) fpdR = rand() * UINT32_MAX; // this is reset: values being initialized only once. Startup values, whatever they are. } void set_input(double value) { A = clamp(value); } void set_tube(double value) { B = clamp(value); } void set_samplerate(double _samplerate) { samplerate = _samplerate; } void process_block(double** inputs, double** outputs, long 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 *= samplerate; double inputPad = A; double iterations = 1.0 - B; int powerfactor = (9.0 * iterations) + 1; double asymPad = (double)powerfactor; double gainscaling = 1.0 / (double)(powerfactor + 1); double outputscaling = 1.0 + (1.0 / (double)(powerfactor)); 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; if (inputPad < 1.0) { inputSampleL *= inputPad; inputSampleR *= inputPad; } if (overallscale > 1.9) { double stored = inputSampleL; inputSampleL += previousSampleA; previousSampleA = stored; inputSampleL *= 0.5; stored = inputSampleR; inputSampleR += previousSampleB; previousSampleB = stored; inputSampleR *= 0.5; } // for high sample rates on this plugin we are going to do a simple average if (inputSampleL > 1.0) inputSampleL = 1.0; if (inputSampleL < -1.0) inputSampleL = -1.0; if (inputSampleR > 1.0) inputSampleR = 1.0; if (inputSampleR < -1.0) inputSampleR = -1.0; // flatten bottom, point top of sine waveshaper L inputSampleL /= asymPad; double sharpen = -inputSampleL; if (sharpen > 0.0) sharpen = 1.0 + sqrt(sharpen); else sharpen = 1.0 - sqrt(-sharpen); inputSampleL -= inputSampleL * fabs(inputSampleL) * sharpen * 0.25; // this will take input from exactly -1.0 to 1.0 max inputSampleL *= asymPad; // flatten bottom, point top of sine waveshaper R inputSampleR /= asymPad; sharpen = -inputSampleR; if (sharpen > 0.0) sharpen = 1.0 + sqrt(sharpen); else sharpen = 1.0 - sqrt(-sharpen); inputSampleR -= inputSampleR * fabs(inputSampleR) * sharpen * 0.25; // this will take input from exactly -1.0 to 1.0 max inputSampleR *= asymPad; // end first asym section: later boosting can mitigate the extreme // softclipping of one side of the wave // and we are asym clipping more when Tube is cranked, to compensate // original Tube algorithm: powerfactor widens the more linear region of the wave double factor = inputSampleL; // Left channel for (int x = 0; x < powerfactor; x++) factor *= inputSampleL; if ((powerfactor % 2 == 1) && (inputSampleL != 0.0)) factor = (factor / inputSampleL) * fabs(inputSampleL); factor *= gainscaling; inputSampleL -= factor; inputSampleL *= outputscaling; factor = inputSampleR; // Right channel for (int x = 0; x < powerfactor; x++) factor *= inputSampleR; if ((powerfactor % 2 == 1) && (inputSampleR != 0.0)) factor = (factor / inputSampleR) * fabs(inputSampleR); factor *= gainscaling; inputSampleR -= factor; inputSampleR *= outputscaling; if (overallscale > 1.9) { double stored = inputSampleL; inputSampleL += previousSampleC; previousSampleC = stored; inputSampleL *= 0.5; stored = inputSampleR; inputSampleR += previousSampleD; previousSampleD = stored; inputSampleR *= 0.5; } // for high sample rates on this plugin we are going to do a simple average // end original Tube. Now we have a boosted fat sound peaking at 0dB exactly // hysteresis and spiky fuzz L double slew = previousSampleE - inputSampleL; if (overallscale > 1.9) { double stored = inputSampleL; inputSampleL += previousSampleE; previousSampleE = stored; inputSampleL *= 0.5; } else previousSampleE = inputSampleL; // for this, need previousSampleC always if (slew > 0.0) slew = 1.0 + (sqrt(slew) * 0.5); else slew = 1.0 - (sqrt(-slew) * 0.5); inputSampleL -= inputSampleL * fabs(inputSampleL) * slew * gainscaling; // reusing gainscaling that's part of another algorithm if (inputSampleL > 0.52) inputSampleL = 0.52; if (inputSampleL < -0.52) inputSampleL = -0.52; inputSampleL *= 1.923076923076923; // hysteresis and spiky fuzz R slew = previousSampleF - inputSampleR; if (overallscale > 1.9) { double stored = inputSampleR; inputSampleR += previousSampleF; previousSampleF = stored; inputSampleR *= 0.5; } else previousSampleF = inputSampleR; // for this, need previousSampleC always if (slew > 0.0) slew = 1.0 + (sqrt(slew) * 0.5); else slew = 1.0 - (sqrt(-slew) * 0.5); inputSampleR -= inputSampleR * fabs(inputSampleR) * slew * gainscaling; // reusing gainscaling that's part of another algorithm if (inputSampleR > 0.52) inputSampleR = 0.52; if (inputSampleR < -0.52) inputSampleR = -0.52; inputSampleR *= 1.923076923076923; // end hysteresis and spiky fuzz section // 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++; } } private: double samplerate; double previousSampleA; double previousSampleB; double previousSampleC; double previousSampleD; double previousSampleE; double previousSampleF; uint32_t fpdL; uint32_t fpdR; // default stuff float A; float B; double clamp(double& value) { if (value > 1) { value = 1; } else if (value < 0) { value = 0; } return value; } }; } // namespace trnr