remove pop2

2025-06-23 14:40:28 +02:00
parent c6def58726
commit d7945451f2
1 changed files with 0 additions and 281 deletions
--- a/dynamics/aw_pop2.h
+++ b/dynamics/aw_pop2.h
@@ -1,281 +0,0 @@
 #pragma once
 #include <cstdlib>
 #include <stdint.h>
 #include <cmath>
 namespace trnr {
 // compressor based on pop2 by Chris Johnson
 class aw_pop2 {
 public:
 	aw_pop2()
 	{
 		samplerate = 44100;
 		A = 0.5;
 		B = 0.5;
 		C = 0.5;
 		D = 0.5;
 		E = 1.0;
 		fpdL = 1.0;
 		while (fpdL < 16386) fpdL = rand() * UINT32_MAX;
 		fpdR = 1.0;
 		while (fpdR < 16386) fpdR = rand() * UINT32_MAX;
 		lastSampleL = 0.0;
 		wasPosClipL = false;
 		wasNegClipL = false;
 		lastSampleR = 0.0;
 		wasPosClipR = false;
 		wasNegClipR = false;
 		for (int x = 0; x < 16; x++) {
 			intermediateL[x] = 0.0;
 			intermediateR[x] = 0.0;
 		}
 		muVaryL = 0.0;
 		muAttackL = 0.0;
 		muNewSpeedL = 1000.0;
 		muSpeedAL = 1000.0;
 		muSpeedBL = 1000.0;
 		muCoefficientAL = 1.0;
 		muCoefficientBL = 1.0;
 		muVaryR = 0.0;
 		muAttackR = 0.0;
 		muNewSpeedR = 1000.0;
 		muSpeedAR = 1000.0;
 		muSpeedBR = 1000.0;
 		muCoefficientAR = 1.0;
 		muCoefficientBR = 1.0;
 		flip = false;
 		// this is reset: values being initialized only once. Startup values, whatever they are.
 	}
 	void set_compression(double value) { A = clamp(value); }
 	void set_attack(double value) { B = clamp(value); }
 	void set_release(double value) { C = clamp(value); }
 	void set_drive(double value) { D = clamp(value); }
 	void set_drywet(double value) { E = clamp(value); }
 	void set_samplerate(double _samplerate) { samplerate = _samplerate; }
 	template <typename t_sample>
 	void process_block(t_sample** inputs, t_sample** outputs, long sampleframes)
 	{
 		t_sample* in1 = inputs[0];
 		t_sample* in2 = inputs[1];
 		t_sample* out1 = outputs[0];
 		t_sample* out2 = outputs[1];
 		double overallscale = 1.0;
 		overallscale /= 44100.0;
 		overallscale *= samplerate;
 		int spacing = floor(overallscale); // should give us working basic scaling, usually 2 or 4
 		if (spacing < 1) spacing = 1;
 		if (spacing > 16) spacing = 16;
 		double threshold = 1.0 - ((1.0 - pow(1.0 - A, 2)) * 0.9);
 		double attack = ((pow(B, 4) * 100000.0) + 10.0) * overallscale;
 		double release = ((pow(C, 5) * 2000000.0) + 20.0) * overallscale;
 		double maxRelease = release * 4.0;
 		double muPreGain = 1.0 / threshold;
 		double muMakeupGain = sqrt(1.0 / threshold) * D;
 		double wet = E;
 		// compressor section
 		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;
 			// begin compressor section
 			inputSampleL *= muPreGain;
 			inputSampleR *= muPreGain;
 			// adjust coefficients for L
 			if (flip) {
 				if (fabs(inputSampleL) > threshold) {
 					muVaryL = threshold / fabs(inputSampleL);
 					muAttackL = sqrt(fabs(muSpeedAL));
 					muCoefficientAL = muCoefficientAL * (muAttackL - 1.0);
 					if (muVaryL < threshold) muCoefficientAL = muCoefficientAL + threshold;
 					else muCoefficientAL = muCoefficientAL + muVaryL;
 					muCoefficientAL = muCoefficientAL / muAttackL;
 					muNewSpeedL = muSpeedAL * (muSpeedAL - 1.0);
 					muNewSpeedL = muNewSpeedL + release;
 					muSpeedAL = muNewSpeedL / muSpeedAL;
 					if (muSpeedAL > maxRelease) muSpeedAL = maxRelease;
 				} else {
 					muCoefficientAL = muCoefficientAL * ((muSpeedAL * muSpeedAL) - 1.0);
 					muCoefficientAL = muCoefficientAL + 1.0;
 					muCoefficientAL = muCoefficientAL / (muSpeedAL * muSpeedAL);
 					muNewSpeedL = muSpeedAL * (muSpeedAL - 1.0);
 					muNewSpeedL = muNewSpeedL + attack;
 					muSpeedAL = muNewSpeedL / muSpeedAL;
 				}
 			} else {
 				if (fabs(inputSampleL) > threshold) {
 					muVaryL = threshold / fabs(inputSampleL);
 					muAttackL = sqrt(fabs(muSpeedBL));
 					muCoefficientBL = muCoefficientBL * (muAttackL - 1);
 					if (muVaryL < threshold) muCoefficientBL = muCoefficientBL + threshold;
 					else muCoefficientBL = muCoefficientBL + muVaryL;
 					muCoefficientBL = muCoefficientBL / muAttackL;
 					muNewSpeedL = muSpeedBL * (muSpeedBL - 1.0);
 					muNewSpeedL = muNewSpeedL + release;
 					muSpeedBL = muNewSpeedL / muSpeedBL;
 					if (muSpeedBL > maxRelease) muSpeedBL = maxRelease;
 				} else {
 					muCoefficientBL = muCoefficientBL * ((muSpeedBL * muSpeedBL) - 1.0);
 					muCoefficientBL = muCoefficientBL + 1.0;
 					muCoefficientBL = muCoefficientBL / (muSpeedBL * muSpeedBL);
 					muNewSpeedL = muSpeedBL * (muSpeedBL - 1.0);
 					muNewSpeedL = muNewSpeedL + attack;
 					muSpeedBL = muNewSpeedL / muSpeedBL;
 				}
 			}
 			// got coefficients, adjusted speeds for L
 			// adjust coefficients for R
 			if (flip) {
 				if (fabs(inputSampleR) > threshold) {
 					muVaryR = threshold / fabs(inputSampleR);
 					muAttackR = sqrt(fabs(muSpeedAR));
 					muCoefficientAR = muCoefficientAR * (muAttackR - 1.0);
 					if (muVaryR < threshold) muCoefficientAR = muCoefficientAR + threshold;
 					else muCoefficientAR = muCoefficientAR + muVaryR;
 					muCoefficientAR = muCoefficientAR / muAttackR;
 					muNewSpeedR = muSpeedAR * (muSpeedAR - 1.0);
 					muNewSpeedR = muNewSpeedR + release;
 					muSpeedAR = muNewSpeedR / muSpeedAR;
 					if (muSpeedAR > maxRelease) muSpeedAR = maxRelease;
 				} else {
 					muCoefficientAR = muCoefficientAR * ((muSpeedAR * muSpeedAR) - 1.0);
 					muCoefficientAR = muCoefficientAR + 1.0;
 					muCoefficientAR = muCoefficientAR / (muSpeedAR * muSpeedAR);
 					muNewSpeedR = muSpeedAR * (muSpeedAR - 1.0);
 					muNewSpeedR = muNewSpeedR + attack;
 					muSpeedAR = muNewSpeedR / muSpeedAR;
 				}
 			} else {
 				if (fabs(inputSampleR) > threshold) {
 					muVaryR = threshold / fabs(inputSampleR);
 					muAttackR = sqrt(fabs(muSpeedBR));
 					muCoefficientBR = muCoefficientBR * (muAttackR - 1);
 					if (muVaryR < threshold) muCoefficientBR = muCoefficientBR + threshold;
 					else muCoefficientBR = muCoefficientBR + muVaryR;
 					muCoefficientBR = muCoefficientBR / muAttackR;
 					muNewSpeedR = muSpeedBR * (muSpeedBR - 1.0);
 					muNewSpeedR = muNewSpeedR + release;
 					muSpeedBR = muNewSpeedR / muSpeedBR;
 					if (muSpeedBR > maxRelease) muSpeedBR = maxRelease;
 				} else {
 					muCoefficientBR = muCoefficientBR * ((muSpeedBR * muSpeedBR) - 1.0);
 					muCoefficientBR = muCoefficientBR + 1.0;
 					muCoefficientBR = muCoefficientBR / (muSpeedBR * muSpeedBR);
 					muNewSpeedR = muSpeedBR * (muSpeedBR - 1.0);
 					muNewSpeedR = muNewSpeedR + attack;
 					muSpeedBR = muNewSpeedR / muSpeedBR;
 				}
 			}
 			// got coefficients, adjusted speeds for R
 			if (flip) {
 				inputSampleL *= pow(muCoefficientAL, 2);
 				inputSampleR *= pow(muCoefficientAR, 2);
 			} else {
 				inputSampleL *= pow(muCoefficientBL, 2);
 				inputSampleR *= pow(muCoefficientBR, 2);
 			}
 			inputSampleL *= muMakeupGain;
 			inputSampleR *= muMakeupGain;
 			flip = !flip;
 			// end compressor section
 			if (wet < 1.0) {
 				inputSampleL = (drySampleL * (1.0 - wet)) + (inputSampleL * wet);
 				inputSampleR = (drySampleR * (1.0 - wet)) + (inputSampleR * 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++;
 		}
 	}
 private:
 	double samplerate;
 	uint32_t fpdL;
 	uint32_t fpdR;
 	// default stuff
 	double muVaryL;
 	double muAttackL;
 	double muNewSpeedL;
 	double muSpeedAL;
 	double muSpeedBL;
 	double muCoefficientAL;
 	double muCoefficientBL;
 	double muVaryR;
 	double muAttackR;
 	double muNewSpeedR;
 	double muSpeedAR;
 	double muSpeedBR;
 	double muCoefficientAR;
 	double muCoefficientBR;
 	bool flip;
 	double lastSampleL;
 	double intermediateL[16];
 	bool wasPosClipL;
 	bool wasNegClipL;
 	double lastSampleR;
 	double intermediateR[16];
 	bool wasPosClipR;
 	bool wasNegClipR; // Stereo ClipOnly2
 	float A;
 	float B;
 	float C;
 	float D;
 	float E; // parameters. Always 0-1, and we scale/alter them elsewhere.
 	double clamp(double& value)
 	{
 		if (value > 1) {
 			value = 1;
 		} else if (value < 0) {
 			value = 0;
 		}
 		return value;
 	}
 };
 } // namespace trnr