cog/Frameworks/OpenMPT/OpenMPT/soundlib/plugins/dmo/Distortion.cpp

/*
 * Distortion.cpp
 * --------------
 * Purpose: Implementation of the DMO Distortion DSP (for non-Windows platforms)
 * Notes  : The original plugin's integer and floating point code paths only
 *          behave identically when feeding floating point numbers in range
 *          [-32768, +32768] rather than the usual [-1, +1] into the plugin.
 * Authors: OpenMPT Devs
 * The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
 */


#include "stdafx.h"

#ifndef NO_PLUGINS
#include "../../Sndfile.h"
#include "Distortion.h"
#include "DMOUtils.h"
#include "mpt/base/numbers.hpp"
#endif // !NO_PLUGINS

OPENMPT_NAMESPACE_BEGIN

#ifndef NO_PLUGINS

namespace DMO
{

IMixPlugin* Distortion::Create(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
{
	return new (std::nothrow) Distortion(factory, sndFile, mixStruct);
}


Distortion::Distortion(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
	: IMixPlugin(factory, sndFile, mixStruct)
{
	m_param[kDistGain] = 0.7f;
	m_param[kDistEdge] = 0.15f;
	m_param[kDistPreLowpassCutoff] = 1.0f;
	m_param[kDistPostEQCenterFrequency] = 0.291f;
	m_param[kDistPostEQBandwidth] = 0.291f;

	m_mixBuffer.Initialize(2, 2);
	InsertIntoFactoryList();
}


void Distortion::Process(float *pOutL, float *pOutR, uint32 numFrames)
{
	if(!m_mixBuffer.Ok())
		return;

	const float *in[2] = { m_mixBuffer.GetInputBuffer(0), m_mixBuffer.GetInputBuffer(1) };
	float *out[2] = { m_mixBuffer.GetOutputBuffer(0), m_mixBuffer.GetOutputBuffer(1) };

	for(uint32 i = numFrames; i != 0; i--)
	{
		for(uint8 channel = 0; channel < 2; channel++)
		{
			float x = *(in[channel])++;

			// Pre EQ
			float z = x * m_preEQa0 + m_preEQz1[channel] * m_preEQb1;
			m_preEQz1[channel] = z;

			z *= 1073741824.0f;	// 32768^2

			// The actual distortion
			z = logGain(z, m_edge, m_shift);

			// Post EQ / Gain
			z = (z * m_postEQa0) - m_postEQz1[channel] * m_postEQb1 - m_postEQz2[channel] * m_postEQb0;
			m_postEQz1[channel] = z * m_postEQb0 + m_postEQz2[channel];
			m_postEQz2[channel] = z;

			z *= (1.0f / 1073741824.0f);	// 32768^2
			*(out[channel])++ = z;
		}
	}

	ProcessMixOps(pOutL, pOutR, m_mixBuffer.GetOutputBuffer(0), m_mixBuffer.GetOutputBuffer(1), numFrames);
}


PlugParamValue Distortion::GetParameter(PlugParamIndex index)
{
	if(index < kDistNumParameters)
	{
		return m_param[index];
	}
	return 0;
}


void Distortion::SetParameter(PlugParamIndex index, PlugParamValue value)
{
	if(index < kDistNumParameters)
	{
		value = mpt::safe_clamp(value, 0.0f, 1.0f);
		m_param[index] = value;
		RecalculateDistortionParams();
	}
}


void Distortion::Resume()
{
	m_isResumed = true;
	RecalculateDistortionParams();
	PositionChanged();
}


void Distortion::PositionChanged()
{
	// Reset filter state
	m_preEQz1[0] = m_preEQz1[1] = 0;
	m_postEQz1[0] = m_postEQz2[0] = 0;
	m_postEQz1[1] = m_postEQz2[1] = 0;
}


#ifdef MODPLUG_TRACKER

CString Distortion::GetParamName(PlugParamIndex param)
{
	switch(param)
	{
	case kDistGain: return _T("Gain");
	case kDistEdge: return _T("Edge");
	case kDistPreLowpassCutoff: return _T("PreLowpassCutoff");
	case kDistPostEQCenterFrequency: return _T("PostEQCenterFrequency");
	case kDistPostEQBandwidth: return _T("PostEQBandwidth");
	}
	return CString();
}


CString Distortion::GetParamLabel(PlugParamIndex param)
{
	switch(param)
	{
	case kDistGain:
		return _T("dB");
	case kDistPreLowpassCutoff:
	case kDistPostEQCenterFrequency:
	case kDistPostEQBandwidth:
		return _T("Hz");
	}
	return CString();
}


CString Distortion::GetParamDisplay(PlugParamIndex param)
{
	float value = m_param[param];
	switch(param)
	{
	case kDistGain:
		value = GainInDecibel();
		break;
	case kDistEdge:
		value *= 100.0f;
		break;
	case kDistPreLowpassCutoff:
	case kDistPostEQCenterFrequency:
	case kDistPostEQBandwidth:
		value = FreqInHertz(value);
		break;
	}
	CString s;
	s.Format(_T("%.2f"), value);
	return s;
}

#endif // MODPLUG_TRACKER


void Distortion::RecalculateDistortionParams()
{
	// Pre-EQ
	m_preEQb1 = std::sqrt((2.0f * std::cos(2.0f * mpt::numbers::pi_v<float> * std::min(FreqInHertz(m_param[kDistPreLowpassCutoff]) / m_SndFile.GetSampleRate(), 0.5f)) + 3.0f) / 5.0f);
	m_preEQa0 = std::sqrt(1.0f - m_preEQb1 * m_preEQb1);

	// Distortion
	float edge = 2.0f + m_param[kDistEdge] * 29.0f;
	m_edge = static_cast<uint8>(edge);  // 2...31 shifted bits
	m_shift = static_cast<uint8>(mpt::bit_width(m_edge));

	static constexpr float LogNorm[32] =
	{
		1.00f, 1.00f, 1.50f, 1.00f, 1.75f, 1.40f, 1.17f, 1.00f,
		1.88f, 1.76f, 1.50f, 1.36f, 1.25f, 1.15f, 1.07f, 1.00f,
		1.94f, 1.82f, 1.72f, 1.63f, 1.55f, 1.48f, 1.41f, 1.35f,
		1.29f, 1.24f, 1.19f, 1.15f, 1.11f, 1.07f, 1.03f, 1.00f,
	};

	// Post-EQ
	const float gain = std::pow(10.0f, GainInDecibel() / 20.0f);
	const float postFreq = 2.0f * mpt::numbers::pi_v<float> * std::min(FreqInHertz(m_param[kDistPostEQCenterFrequency]) / m_SndFile.GetSampleRate(), 0.5f);
	const float postBw = 2.0f * mpt::numbers::pi_v<float> * std::min(FreqInHertz(m_param[kDistPostEQBandwidth]) / m_SndFile.GetSampleRate(), 0.5f);
	const float t = std::tan(5.0e-1f * postBw);
	m_postEQb1 = ((1.0f - t) / (1.0f + t));
	m_postEQb0 = -std::cos(postFreq);
	m_postEQa0 = gain * std::sqrt(1.0f - m_postEQb0 * m_postEQb0) * std::sqrt(1.0f - m_postEQb1 * m_postEQb1) * LogNorm[m_edge];
}

} // namespace DMO

#else
MPT_MSVC_WORKAROUND_LNK4221(Distortion)

#endif // !NO_PLUGINS

OPENMPT_NAMESPACE_END