airwindows/plugins/MacAU/Channel9/Channel9.cpp

/*
*	File:		Channel9.cpp
*	
*	Version:	1.0
* 
*	Created:	1/4/21
*	
*	Copyright:  Copyright © 2021 Airwindows, Airwindows uses the MIT license
* 
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/*=============================================================================
	Channel9.cpp
	
=============================================================================*/
#include "Channel9.h"


//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

COMPONENT_ENTRY(Channel9)


//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::Channel9
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Channel9::Channel9(AudioUnit component)
	: AUEffectBase(component)
{
	CreateElements();
	Globals()->UseIndexedParameters(kNumberOfParameters);
	SetParameter(kParam_One, kDefaultValue_ParamOne );
	SetParameter(kParam_Two, kDefaultValue_ParamTwo );
	SetParameter(kParam_Three, kDefaultValue_ParamThree );
         
#if AU_DEBUG_DISPATCHER
	mDebugDispatcher = new AUDebugDispatcher (this);
#endif
	
}


//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::GetParameterValueStrings
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ComponentResult			Channel9::GetParameterValueStrings(AudioUnitScope		inScope,
                                                                AudioUnitParameterID	inParameterID,
                                                                CFArrayRef *		outStrings)
{
    if ((inScope == kAudioUnitScope_Global) && (inParameterID == kParam_One)) //ID must be actual name of parameter identifier, not number
	{
		if (outStrings == NULL) return noErr;
		CFStringRef strings [] =
		{
			kMenuItem_Neve,
			kMenuItem_API,
			kMenuItem_SSL,
			kMenuItem_Teac,
			kMenuItem_Mackie,
		};
		*outStrings = CFArrayCreate (
									 NULL,
									 (const void **) strings,
									 (sizeof (strings) / sizeof (strings [0])),
									 NULL
									 );
		return noErr;
	}
    return kAudioUnitErr_InvalidProperty;
}



//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::GetParameterInfo
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ComponentResult			Channel9::GetParameterInfo(AudioUnitScope		inScope,
                                                        AudioUnitParameterID	inParameterID,
                                                        AudioUnitParameterInfo	&outParameterInfo )
{
	ComponentResult result = noErr;

	outParameterInfo.flags = 	kAudioUnitParameterFlag_IsWritable
						|		kAudioUnitParameterFlag_IsReadable;
    
    if (inScope == kAudioUnitScope_Global) {
        switch(inParameterID)
        {
            case kParam_One:
                AUBase::FillInParameterName (outParameterInfo, kParameterOneName, false);
				outParameterInfo.unit = kAudioUnitParameterUnit_Indexed;
                outParameterInfo.minValue = kNeve;
                outParameterInfo.maxValue = kMackie;
                outParameterInfo.defaultValue = kDefaultValue_ParamOne;
                break;
            case kParam_Two:
                AUBase::FillInParameterName (outParameterInfo, kParameterTwoName, false);
                outParameterInfo.unit = kAudioUnitParameterUnit_Percent;
                outParameterInfo.minValue = 0.0;
                outParameterInfo.maxValue = 200.0;
                outParameterInfo.defaultValue = kDefaultValue_ParamTwo;
                break;
            case kParam_Three:
                AUBase::FillInParameterName (outParameterInfo, kParameterThreeName, false);
                outParameterInfo.unit = kAudioUnitParameterUnit_Generic;
                outParameterInfo.minValue = 0.0;
                outParameterInfo.maxValue = 1.0;
                outParameterInfo.defaultValue = kDefaultValue_ParamThree;
                break;
           default:
                result = kAudioUnitErr_InvalidParameter;
                break;
            }
	} else {
        result = kAudioUnitErr_InvalidParameter;
    }
    


	return result;
}

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::GetPropertyInfo
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ComponentResult			Channel9::GetPropertyInfo (AudioUnitPropertyID	inID,
                                                        AudioUnitScope		inScope,
                                                        AudioUnitElement	inElement,
                                                        UInt32 &		outDataSize,
                                                        Boolean &		outWritable)
{
	return AUEffectBase::GetPropertyInfo (inID, inScope, inElement, outDataSize, outWritable);
}

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::GetProperty
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ComponentResult			Channel9::GetProperty(	AudioUnitPropertyID inID,
                                                        AudioUnitScope 		inScope,
                                                        AudioUnitElement 	inElement,
                                                        void *			outData )
{
	return AUEffectBase::GetProperty (inID, inScope, inElement, outData);
}

//	Channel9::Initialize
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
ComponentResult Channel9::Initialize()
{
    ComponentResult result = AUEffectBase::Initialize();
    if (result == noErr)
        Reset(kAudioUnitScope_Global, 0);
    return result;
}

#pragma mark ____Channel9EffectKernel



//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::Channel9Kernel::Reset()
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
void		Channel9::Channel9Kernel::Reset()
{
	fpd = 1.0; while (fpd < 16386) fpd = rand()*UINT32_MAX;
	iirSampleA = iirSampleB = 0.0;
	flip = false;
	lastSampleA = lastSampleB = lastSampleC = 0.0;
	for (int x = 0; x < 11; x++) {biquadA[x] = 0.0;biquadB[x] = 0.0;}
}

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//	Channel9::Channel9Kernel::Process
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
void		Channel9::Channel9Kernel::Process(	const Float32 	*inSourceP,
                                                    Float32		 	*inDestP,
                                                    UInt32 			inFramesToProcess,
                                                    UInt32			inNumChannels, 
                                                    bool			&ioSilence )
{
	UInt32 nSampleFrames = inFramesToProcess;
	const Float32 *sourceP = inSourceP;
	Float32 *destP = inDestP;
	Float64 overallscale = 1.0;
	overallscale /= 44100.0;
	overallscale *= GetSampleRate();
	int console = (int) GetParameter( kParam_One );
	Float64 density = GetParameter( kParam_Two )/100.0; //0-2
	Float64 phattity = density - 1.0;
	if (density > 1.0) density = 1.0; //max out at full wet for Spiral aspect
	if (phattity < 0.0) phattity = 0.0; //
	Float64 nonLin = 5.0-density; //number is smaller for more intense, larger for more subtle
	Float64 output = GetParameter( kParam_Three );
	Float64 iirAmount = 0.005832;
	Float64 threshold = 0.33362176;
	Float64 cutoff = 28811.0;

	switch (console)
	{
		case 1: iirAmount = 0.005832; threshold = 0.33362176; cutoff = 28811.0; break; //Neve
		case 2: iirAmount = 0.004096; threshold = 0.59969536; cutoff = 27216.0; break; //API
		case 3: iirAmount = 0.004913; threshold = 0.84934656; cutoff = 23011.0; break; //SSL
		case 4: iirAmount = 0.009216; threshold = 0.149; cutoff = 18544.0; break; //Teac
		case 5: iirAmount = 0.011449; threshold = 0.092; cutoff = 19748.0; break; //Mackie
	}
	iirAmount /= overallscale; //we've learned not to try and adjust threshold for sample rate
	
	biquadB[0] = biquadA[0] = cutoff / GetSampleRate();
    biquadA[1] = 1.618033988749894848204586;
	biquadB[1] = 0.618033988749894848204586;
	
	double K = tan(M_PI * biquadA[0]); //lowpass
	double norm = 1.0 / (1.0 + K / biquadA[1] + K * K);
	biquadA[2] = K * K * norm;
	biquadA[3] = 2.0 * biquadA[2];
	biquadA[4] = biquadA[2];
	biquadA[5] = 2.0 * (K * K - 1.0) * norm;
	biquadA[6] = (1.0 - K / biquadA[1] + K * K) * norm;
	
	K = tan(M_PI * biquadA[0]);
	norm = 1.0 / (1.0 + K / biquadB[1] + K * K);
	biquadB[2] = K * K * norm;
	biquadB[3] = 2.0 * biquadB[2];
	biquadB[4] = biquadB[2];
	biquadB[5] = 2.0 * (K * K - 1.0) * norm;
	biquadB[6] = (1.0 - K / biquadB[1] + K * K) * norm;
	
	
	while (nSampleFrames-- > 0) {
		double inputSample = *sourceP;
		if (fabs(inputSample)<1.18e-23) inputSample = fpd * 1.18e-17;
		
		if (biquadA[0] < 0.49999) {
			double tempSample = biquadA[2]*inputSample+biquadA[3]*biquadA[7]+biquadA[4]*biquadA[8]-biquadA[5]*biquadA[9]-biquadA[6]*biquadA[10];
			biquadA[8] = biquadA[7]; biquadA[7] = inputSample; if (fabs(tempSample)<1.18e-37) tempSample = 0.0; inputSample = tempSample; 
			biquadA[10] = biquadA[9]; biquadA[9] = inputSample; //DF1
		}
				
		Float64 dielectricScale = fabs(2.0-((inputSample+nonLin)/nonLin));
		
		if (flip)
		{
			if (fabs(iirSampleA)<1.18e-37) iirSampleA = 0.0;
			iirSampleA = (iirSampleA * (1.0 - (iirAmount * dielectricScale))) + (inputSample * iirAmount * dielectricScale);
			inputSample = inputSample - iirSampleA;
		}
		else
		{
			if (fabs(iirSampleB)<1.18e-37) iirSampleB = 0.0;
			iirSampleB = (iirSampleB * (1.0 - (iirAmount * dielectricScale))) + (inputSample * iirAmount * dielectricScale);
			inputSample = inputSample - iirSampleB;
		}
		//highpass section including capacitor modeling nonlinearity
		double drySample = inputSample;
		
		if (inputSample > 1.0) inputSample = 1.0;
		if (inputSample < -1.0) inputSample = -1.0;
		
		double phatSample = sin(inputSample * 1.57079633);
		inputSample *= 1.2533141373155;
		//clip to 1.2533141373155 to reach maximum output, or 1.57079633 for pure sine 'phat' version
		double distSample = sin(inputSample * fabs(inputSample)) / ((fabs(inputSample) == 0.0) ?1:fabs(inputSample));
		
		inputSample = distSample; //purest form is full Spiral
		if (density < 1.0) inputSample = (drySample*(1-density))+(distSample*density); //fade Spiral aspect
		if (phattity > 0.0) inputSample = (inputSample*(1-phattity))+(phatSample*phattity); //apply original Density on top
		
		Float64 clamp = (lastSampleB - lastSampleC) * 0.381966011250105;
		clamp -= (lastSampleA - lastSampleB) * 0.6180339887498948482045;
		clamp += inputSample - lastSampleA; //regular slew clamping added
		
		lastSampleC = lastSampleB;
		lastSampleB = lastSampleA;
		lastSampleA = inputSample; //now our output relates off lastSampleB
		
		if (clamp > threshold)
			inputSample = lastSampleB + threshold;
		if (-clamp > threshold)
			inputSample = lastSampleB - threshold;
		//slew section		
		lastSampleA = (lastSampleA*0.381966011250105)+(inputSample*0.6180339887498948482045); //split the difference between raw and smoothed for buffer
		
		flip = !flip;
		
		if (output < 1.0)
		{
			inputSample *= output;
		}
		
		if (biquadB[0] < 0.49999) {
			double tempSample = biquadB[2]*inputSample+biquadB[3]*biquadB[7]+biquadB[4]*biquadB[8]-biquadB[5]*biquadB[9]-biquadB[6]*biquadB[10];
			biquadB[8] = biquadB[7]; biquadB[7] = inputSample; if (fabs(tempSample)<1.18e-37) tempSample = 0.0; inputSample = tempSample; 
			biquadB[10] = biquadB[9]; biquadB[9] = inputSample; //DF1
		}
		
		//begin 32 bit floating point dither
		int expon; frexpf((float)inputSample, &expon);
		fpd ^= fpd << 13; fpd ^= fpd >> 17; fpd ^= fpd << 5;
		inputSample += ((double(fpd)-uint32_t(0x7fffffff)) * 5.5e-36l * pow(2,expon+62));
		//end 32 bit floating point dither
		
		*destP = inputSample;
		
		sourceP += inNumChannels; destP += inNumChannels;
	}
}