winamp/Src/external_dependencies/openmpt-trunk/soundlib/plugins/DigiBoosterEcho.cpp

236 lines
5.7 KiB
C++

/*
* DigiBoosterEcho.cpp
* -------------------
* Purpose: Implementation of the DigiBooster Pro Echo DSP
* Notes : (currently none)
* Authors: OpenMPT Devs, based on original code by Grzegorz Kraszewski (BSD 2-clause)
* 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 "DigiBoosterEcho.h"
OPENMPT_NAMESPACE_BEGIN
IMixPlugin* DigiBoosterEcho::Create(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
{
return new (std::nothrow) DigiBoosterEcho(factory, sndFile, mixStruct);
}
DigiBoosterEcho::DigiBoosterEcho(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
: IMixPlugin(factory, sndFile, mixStruct)
, m_sampleRate(sndFile.GetSampleRate())
, m_chunk(PluginChunk::Default())
{
m_mixBuffer.Initialize(2, 2);
InsertIntoFactoryList();
}
void DigiBoosterEcho::Process(float *pOutL, float *pOutR, uint32 numFrames)
{
if(!m_bufferSize)
return;
const float *srcL = m_mixBuffer.GetInputBuffer(0), *srcR = m_mixBuffer.GetInputBuffer(1);
float *outL = m_mixBuffer.GetOutputBuffer(0), *outR = m_mixBuffer.GetOutputBuffer(1);
for(uint32 i = numFrames; i != 0; i--)
{
int readPos = m_writePos - m_delayTime;
if(readPos < 0)
readPos += m_bufferSize;
float l = *srcL++, r = *srcR++;
float lDelay = m_delayLine[readPos * 2], rDelay = m_delayLine[readPos * 2 + 1];
// Calculate the delay
float al = l * m_NCrossNBack;
al += r * m_PCrossNBack;
al += lDelay * m_NCrossPBack;
al += rDelay * m_PCrossPBack;
float ar = r * m_NCrossNBack;
ar += l * m_PCrossNBack;
ar += rDelay * m_NCrossPBack;
ar += lDelay * m_PCrossPBack;
// Prevent denormals
if(std::abs(al) < 1e-24f)
al = 0.0f;
if(std::abs(ar) < 1e-24f)
ar = 0.0f;
m_delayLine[m_writePos * 2] = al;
m_delayLine[m_writePos * 2 + 1] = ar;
m_writePos++;
if(m_writePos == m_bufferSize)
m_writePos = 0;
// Output samples now
*outL++ = (l * m_NMix + lDelay * m_PMix);
*outR++ = (r * m_NMix + rDelay * m_PMix);
}
ProcessMixOps(pOutL, pOutR, m_mixBuffer.GetOutputBuffer(0), m_mixBuffer.GetOutputBuffer(1), numFrames);
}
void DigiBoosterEcho::SaveAllParameters()
{
m_pMixStruct->defaultProgram = -1;
try
{
m_pMixStruct->pluginData.resize(sizeof(m_chunk));
memcpy(m_pMixStruct->pluginData.data(), &m_chunk, sizeof(m_chunk));
} catch(mpt::out_of_memory e)
{
mpt::delete_out_of_memory(e);
m_pMixStruct->pluginData.clear();
}
}
void DigiBoosterEcho::RestoreAllParameters(int32 program)
{
if(m_pMixStruct->pluginData.size() == sizeof(m_chunk) && !memcmp(m_pMixStruct->pluginData.data(), "Echo", 4))
{
memcpy(&m_chunk, m_pMixStruct->pluginData.data(), sizeof(m_chunk));
} else
{
IMixPlugin::RestoreAllParameters(program);
}
RecalculateEchoParams();
}
PlugParamValue DigiBoosterEcho::GetParameter(PlugParamIndex index)
{
if(index < kEchoNumParameters)
{
return m_chunk.param[index] / 255.0f;
}
return 0;
}
void DigiBoosterEcho::SetParameter(PlugParamIndex index, PlugParamValue value)
{
if(index < kEchoNumParameters)
{
m_chunk.param[index] = mpt::saturate_round<uint8>(mpt::safe_clamp(value, 0.0f, 1.0f) * 255.0f);
RecalculateEchoParams();
}
}
void DigiBoosterEcho::Resume()
{
m_isResumed = true;
m_sampleRate = m_SndFile.GetSampleRate();
RecalculateEchoParams();
PositionChanged();
}
void DigiBoosterEcho::PositionChanged()
{
m_bufferSize = (m_sampleRate >> 1) + (m_sampleRate >> 6);
try
{
m_delayLine.assign(m_bufferSize * 2, 0);
} catch(mpt::out_of_memory e)
{
mpt::delete_out_of_memory(e);
m_bufferSize = 0;
}
m_writePos = 0;
}
#ifdef MODPLUG_TRACKER
CString DigiBoosterEcho::GetParamName(PlugParamIndex param)
{
switch(param)
{
case kEchoDelay: return _T("Delay");
case kEchoFeedback: return _T("Feedback");
case kEchoMix: return _T("Wet / Dry Ratio");
case kEchoCross: return _T("Cross Echo");
}
return CString();
}
CString DigiBoosterEcho::GetParamLabel(PlugParamIndex param)
{
if(param == kEchoDelay)
return _T("ms");
return CString();
}
CString DigiBoosterEcho::GetParamDisplay(PlugParamIndex param)
{
CString s;
if(param == kEchoMix)
{
int wet = (m_chunk.param[kEchoMix] * 100) / 255;
s.Format(_T("%d%% / %d%%"), wet, 100 - wet);
} else if(param < kEchoNumParameters)
{
int val = m_chunk.param[param];
if(param == kEchoDelay)
{
if(val == 0)
val = 167;
val *= 2;
}
s.Format(_T("%d"), val);
}
return s;
}
#endif // MODPLUG_TRACKER
IMixPlugin::ChunkData DigiBoosterEcho::GetChunk(bool)
{
auto data = reinterpret_cast<const std::byte *>(&m_chunk);
return ChunkData(data, sizeof(m_chunk));
}
void DigiBoosterEcho::SetChunk(const ChunkData &chunk, bool)
{
auto data = chunk.data();
if(chunk.size() == sizeof(chunk) && !memcmp(data, "Echo", 4))
{
memcpy(&m_chunk, data, chunk.size());
RecalculateEchoParams();
}
}
void DigiBoosterEcho::RecalculateEchoParams()
{
// The fallback value when the delay is 0 was determined experimentally from DBPro 2.21 output.
// The C implementation of libdigibooster3 has no specific handling of this value and thus produces a delay with maximum length.
m_delayTime = ((m_chunk.param[kEchoDelay] ? m_chunk.param[kEchoDelay] : 167u) * m_sampleRate + 250u) / 500u;
m_PMix = (m_chunk.param[kEchoMix]) * (1.0f / 256.0f);
m_NMix = (256 - m_chunk.param[kEchoMix]) * (1.0f / 256.0f);
m_PCrossPBack = (m_chunk.param[kEchoCross] * m_chunk.param[kEchoFeedback]) * (1.0f / 65536.0f);
m_PCrossNBack = (m_chunk.param[kEchoCross] * (256 - m_chunk.param[kEchoFeedback])) * (1.0f / 65536.0f);
m_NCrossPBack = ((m_chunk.param[kEchoCross] - 256) * m_chunk.param[kEchoFeedback]) * (1.0f / 65536.0f);
m_NCrossNBack = ((m_chunk.param[kEchoCross] - 256) * (m_chunk.param[kEchoFeedback] - 256)) * (1.0f / 65536.0f);
}
OPENMPT_NAMESPACE_END
#endif // NO_PLUGINS