path: root/plugins/MacVST/HighImpact/source/HighImpactProc.cpp

/* ========================================
 *  HighImpact - HighImpact.h
 *  Copyright (c) 2016 airwindows, All rights reserved
 * ======================================== */

#ifndef __HighImpact_H
#include "HighImpact.h"
#endif

void HighImpact::processReplacing(float **inputs, float **outputs, VstInt32 sampleFrames) 
{
    float* in1  =  inputs[0];
    float* in2  =  inputs[1];
    float* out1 = outputs[0];
    float* out2 = outputs[1];


	long double inputSampleL;
	long double inputSampleR;
	long double drySampleL;
	long double drySampleR;
	
	double density = A*5.0;
	double out = density / 5.0;
	double sustain = 1.0 - (1.0/(1.0 + (density*A)));
	double bridgerectifier;
	double count;
	double output = B;
	double wet = C;
	double dry = 1.0-wet;	
	double clamp;
	double threshold = (1.25 - out);
    
    while (--sampleFrames >= 0)
    {
		inputSampleL = *in1;
		inputSampleR = *in2;
		if (inputSampleL<1.2e-38 && -inputSampleL<1.2e-38) {
			static int noisesource = 0;
			//this declares a variable before anything else is compiled. It won't keep assigning
			//it to 0 for every sample, it's as if the declaration doesn't exist in this context,
			//but it lets me add this denormalization fix in a single place rather than updating
			//it in three different locations. The variable isn't thread-safe but this is only
			//a random seed and we can share it with whatever.
			noisesource = noisesource % 1700021; noisesource++;
			int residue = noisesource * noisesource;
			residue = residue % 170003; residue *= residue;
			residue = residue % 17011; residue *= residue;
			residue = residue % 1709; residue *= residue;
			residue = residue % 173; residue *= residue;
			residue = residue % 17;
			double applyresidue = residue;
			applyresidue *= 0.00000001;
			applyresidue *= 0.00000001;
			inputSampleL = applyresidue;
		}
		if (inputSampleR<1.2e-38 && -inputSampleR<1.2e-38) {
			static int noisesource = 0;
			noisesource = noisesource % 1700021; noisesource++;
			int residue = noisesource * noisesource;
			residue = residue % 170003; residue *= residue;
			residue = residue % 17011; residue *= residue;
			residue = residue % 1709; residue *= residue;
			residue = residue % 173; residue *= residue;
			residue = residue % 17;
			double applyresidue = residue;
			applyresidue *= 0.00000001;
			applyresidue *= 0.00000001;
			inputSampleR = applyresidue;
			//this denormalization routine produces a white noise at -300 dB which the noise
			//shaping will interact with to produce a bipolar output, but the noise is actually
			//all positive. That should stop any variables from going denormal, and the routine
			//only kicks in if digital black is input. As a final touch, if you save to 24-bit
			//the silence will return to being digital black again.
		}
		drySampleL = inputSampleL;
		drySampleR = inputSampleR;

		count = density;
		while (count > 1.0)
		{
			bridgerectifier = fabs(inputSampleL)*1.57079633;
			if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
			//max value for sine function
			bridgerectifier = sin(bridgerectifier);
			if (inputSampleL > 0.0) inputSampleL = bridgerectifier;
			else inputSampleL = -bridgerectifier;
			
			bridgerectifier = fabs(inputSampleR)*1.57079633;
			if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
			//max value for sine function
			bridgerectifier = sin(bridgerectifier);
			if (inputSampleR > 0.0) inputSampleR = bridgerectifier;
			else inputSampleR = -bridgerectifier;
			
			count = count - 1.0;
		}
		//we have now accounted for any really high density settings.
		
		while (out > 1.0) out = out - 1.0;
		
		bridgerectifier = fabs(inputSampleL)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		//max value for sine function
		if (density > 0) bridgerectifier = sin(bridgerectifier);
		else bridgerectifier = 1-cos(bridgerectifier);
		//produce either boosted or starved version
		if (inputSampleL > 0) inputSampleL = (inputSampleL*(1-out))+(bridgerectifier*out);
		else inputSampleL = (inputSampleL*(1-out))-(bridgerectifier*out);
		//blend according to density control

		bridgerectifier = fabs(inputSampleR)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		//max value for sine function
		if (density > 0) bridgerectifier = sin(bridgerectifier);
		else bridgerectifier = 1-cos(bridgerectifier);
		//produce either boosted or starved version
		if (inputSampleR > 0) inputSampleR = (inputSampleR*(1-out))+(bridgerectifier*out);
		else inputSampleR = (inputSampleR*(1-out))-(bridgerectifier*out);
		//blend according to density control
		
		
		//done first density. Next, sustain-reducer
		bridgerectifier = fabs(inputSampleL)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		bridgerectifier = 1-cos(bridgerectifier);
		if (inputSampleL > 0) inputSampleL = (inputSampleL*(1-sustain))+(bridgerectifier*sustain);
		else inputSampleL = (inputSampleL*(1-sustain))-(bridgerectifier*sustain);
		//done sustain removing, converted to Slew inputs

		//done first density. Next, sustain-reducer
		bridgerectifier = fabs(inputSampleR)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		bridgerectifier = 1-cos(bridgerectifier);
		if (inputSampleR > 0) inputSampleR = (inputSampleR*(1-sustain))+(bridgerectifier*sustain);
		else inputSampleR = (inputSampleR*(1-sustain))-(bridgerectifier*sustain);
		//done sustain removing, converted to Slew inputs
		
		clamp = inputSampleL - lastSampleL;
		if (clamp > threshold)
			inputSampleL = lastSampleL + threshold;
		if (-clamp > threshold)
			inputSampleL = lastSampleL - threshold;
		lastSampleL = inputSampleL;

		clamp = inputSampleR - lastSampleR;
		if (clamp > threshold)
			inputSampleR = lastSampleR + threshold;
		if (-clamp > threshold)
			inputSampleR = lastSampleR - threshold;
		lastSampleR = inputSampleR;
		
		if (output < 1.0) {inputSampleL *= output; inputSampleR *= output;}
		if (wet < 1.0) {
			inputSampleL = (drySampleL * dry)+(inputSampleL*wet);
			inputSampleR = (drySampleR * dry)+(inputSampleR*wet);
		}
		//nice little output stage template: if we have another scale of floating point
		//number, we really don't want to meaninglessly multiply that by 1.0.

		//stereo 32 bit dither, made small and tidy.
		int expon; frexpf((float)inputSampleL, &expon);
		long double dither = (rand()/(RAND_MAX*7.737125245533627e+25))*pow(2,expon+62);
		inputSampleL += (dither-fpNShapeL); fpNShapeL = dither;
		frexpf((float)inputSampleR, &expon);
		dither = (rand()/(RAND_MAX*7.737125245533627e+25))*pow(2,expon+62);
		inputSampleR += (dither-fpNShapeR); fpNShapeR = dither;
		//end 32 bit dither

		*out1 = inputSampleL;
		*out2 = inputSampleR;

		*in1++;
		*in2++;
		*out1++;
		*out2++;
    }
}

void HighImpact::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();

	long double inputSampleL;
	long double inputSampleR;
	long double drySampleL;
	long double drySampleR;
	
	double density = A*5.0;
	double out = density / 5.0;
	double sustain = 1.0 - (1.0/(1.0 + (density*A)));
	double bridgerectifier;
	double count;
	double output = B;
	double wet = C;
	double dry = 1.0-wet;	
	double clamp;
	double threshold = (1.25 - out);
	
    while (--sampleFrames >= 0)
    {
		inputSampleL = *in1;
		inputSampleR = *in2;
		if (inputSampleL<1.2e-38 && -inputSampleL<1.2e-38) {
			static int noisesource = 0;
			//this declares a variable before anything else is compiled. It won't keep assigning
			//it to 0 for every sample, it's as if the declaration doesn't exist in this context,
			//but it lets me add this denormalization fix in a single place rather than updating
			//it in three different locations. The variable isn't thread-safe but this is only
			//a random seed and we can share it with whatever.
			noisesource = noisesource % 1700021; noisesource++;
			int residue = noisesource * noisesource;
			residue = residue % 170003; residue *= residue;
			residue = residue % 17011; residue *= residue;
			residue = residue % 1709; residue *= residue;
			residue = residue % 173; residue *= residue;
			residue = residue % 17;
			double applyresidue = residue;
			applyresidue *= 0.00000001;
			applyresidue *= 0.00000001;
			inputSampleL = applyresidue;
		}
		if (inputSampleR<1.2e-38 && -inputSampleR<1.2e-38) {
			static int noisesource = 0;
			noisesource = noisesource % 1700021; noisesource++;
			int residue = noisesource * noisesource;
			residue = residue % 170003; residue *= residue;
			residue = residue % 17011; residue *= residue;
			residue = residue % 1709; residue *= residue;
			residue = residue % 173; residue *= residue;
			residue = residue % 17;
			double applyresidue = residue;
			applyresidue *= 0.00000001;
			applyresidue *= 0.00000001;
			inputSampleR = applyresidue;
			//this denormalization routine produces a white noise at -300 dB which the noise
			//shaping will interact with to produce a bipolar output, but the noise is actually
			//all positive. That should stop any variables from going denormal, and the routine
			//only kicks in if digital black is input. As a final touch, if you save to 24-bit
			//the silence will return to being digital black again.
		}
		drySampleL = inputSampleL;
		drySampleR = inputSampleR;
		
		count = density;
		while (count > 1.0)
		{
			bridgerectifier = fabs(inputSampleL)*1.57079633;
			if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
			//max value for sine function
			bridgerectifier = sin(bridgerectifier);
			if (inputSampleL > 0.0) inputSampleL = bridgerectifier;
			else inputSampleL = -bridgerectifier;
			
			bridgerectifier = fabs(inputSampleR)*1.57079633;
			if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
			//max value for sine function
			bridgerectifier = sin(bridgerectifier);
			if (inputSampleR > 0.0) inputSampleR = bridgerectifier;
			else inputSampleR = -bridgerectifier;
			
			count = count - 1.0;
		}
		//we have now accounted for any really high density settings.
		
		while (out > 1.0) out = out - 1.0;
		
		bridgerectifier = fabs(inputSampleL)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		//max value for sine function
		if (density > 0) bridgerectifier = sin(bridgerectifier);
		else bridgerectifier = 1-cos(bridgerectifier);
		//produce either boosted or starved version
		if (inputSampleL > 0) inputSampleL = (inputSampleL*(1-out))+(bridgerectifier*out);
		else inputSampleL = (inputSampleL*(1-out))-(bridgerectifier*out);
		//blend according to density control
		
		bridgerectifier = fabs(inputSampleR)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		//max value for sine function
		if (density > 0) bridgerectifier = sin(bridgerectifier);
		else bridgerectifier = 1-cos(bridgerectifier);
		//produce either boosted or starved version
		if (inputSampleR > 0) inputSampleR = (inputSampleR*(1-out))+(bridgerectifier*out);
		else inputSampleR = (inputSampleR*(1-out))-(bridgerectifier*out);
		//blend according to density control
		
		
		//done first density. Next, sustain-reducer
		bridgerectifier = fabs(inputSampleL)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		bridgerectifier = 1-cos(bridgerectifier);
		if (inputSampleL > 0) inputSampleL = (inputSampleL*(1-sustain))+(bridgerectifier*sustain);
		else inputSampleL = (inputSampleL*(1-sustain))-(bridgerectifier*sustain);
		//done sustain removing, converted to Slew inputs
		
		//done first density. Next, sustain-reducer
		bridgerectifier = fabs(inputSampleR)*1.57079633;
		if (bridgerectifier > 1.57079633) bridgerectifier = 1.57079633;
		bridgerectifier = 1-cos(bridgerectifier);
		if (inputSampleR > 0) inputSampleR = (inputSampleR*(1-sustain))+(bridgerectifier*sustain);
		else inputSampleR = (inputSampleR*(1-sustain))-(bridgerectifier*sustain);
		//done sustain removing, converted to Slew inputs
		
		clamp = inputSampleL - lastSampleL;
		if (clamp > threshold)
			inputSampleL = lastSampleL + threshold;
		if (-clamp > threshold)
			inputSampleL = lastSampleL - threshold;
		lastSampleL = inputSampleL;
		
		clamp = inputSampleR - lastSampleR;
		if (clamp > threshold)
			inputSampleR = lastSampleR + threshold;
		if (-clamp > threshold)
			inputSampleR = lastSampleR - threshold;
		lastSampleR = inputSampleR;
		
		if (output < 1.0) {inputSampleL *= output; inputSampleR *= output;}
		if (wet < 1.0) {
			inputSampleL = (drySampleL * dry)+(inputSampleL*wet);
			inputSampleR = (drySampleR * dry)+(inputSampleR*wet);
		}
		//nice little output stage template: if we have another scale of floating point
		//number, we really don't want to meaninglessly multiply that by 1.0.
		
		//stereo 64 bit dither, made small and tidy.
		int expon; frexp((double)inputSampleL, &expon);
		long double dither = (rand()/(RAND_MAX*7.737125245533627e+25))*pow(2,expon+62);
		dither /= 536870912.0; //needs this to scale to 64 bit zone
		inputSampleL += (dither-fpNShapeL); fpNShapeL = dither;
		frexp((double)inputSampleR, &expon);
		dither = (rand()/(RAND_MAX*7.737125245533627e+25))*pow(2,expon+62);
		dither /= 536870912.0; //needs this to scale to 64 bit zone
		inputSampleR += (dither-fpNShapeR); fpNShapeR = dither;
		//end 64 bit dither
		
		*out1 = inputSampleL;
		*out2 = inputSampleR;
		
		*in1++;
		*in2++;
		*out1++;
		*out2++;
    }
}