winamp/Src/external_dependencies/openmpt-trunk/soundlib/plugins/PlugInterface.cpp
2024-09-24 14:54:57 +02:00

1066 lines
28 KiB
C++

/*
* PlugInterface.cpp
* -----------------
* Purpose: Default plugin interface implementation
* Notes : (currently none)
* Authors: OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*/
#include "stdafx.h"
#include "../Sndfile.h"
#include "PlugInterface.h"
#include "PluginManager.h"
#include "../../common/FileReader.h"
#ifdef MODPLUG_TRACKER
#include "../../mptrack/Moddoc.h"
#include "../../mptrack/Mainfrm.h"
#include "../../mptrack/InputHandler.h"
#include "../../mptrack/AbstractVstEditor.h"
#include "../../mptrack/DefaultVstEditor.h"
// LoadProgram/SaveProgram
#include "../../mptrack/FileDialog.h"
#include "../../mptrack/VstPresets.h"
#include "../../common/mptFileIO.h"
#include "../mod_specifications.h"
#endif // MODPLUG_TRACKER
#include "mpt/base/aligned_array.hpp"
#include "mpt/io/base.hpp"
#include "mpt/io/io.hpp"
#include "mpt/io/io_span.hpp"
#include <cmath>
#ifndef NO_PLUGINS
OPENMPT_NAMESPACE_BEGIN
#ifdef MODPLUG_TRACKER
CModDoc *IMixPlugin::GetModDoc() { return m_SndFile.GetpModDoc(); }
const CModDoc *IMixPlugin::GetModDoc() const { return m_SndFile.GetpModDoc(); }
#endif // MODPLUG_TRACKER
IMixPlugin::IMixPlugin(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
: m_Factory(factory)
, m_SndFile(sndFile)
, m_pMixStruct(mixStruct)
{
m_SndFile.m_loadedPlugins++;
m_MixState.pMixBuffer = mpt::align_bytes<8, MIXBUFFERSIZE * 2>(m_MixBuffer);
while(m_pMixStruct != &(m_SndFile.m_MixPlugins[m_nSlot]) && m_nSlot < MAX_MIXPLUGINS - 1)
{
m_nSlot++;
}
}
IMixPlugin::~IMixPlugin()
{
#ifdef MODPLUG_TRACKER
CloseEditor();
CriticalSection cs;
#endif // MODPLUG_TRACKER
// First thing to do, if we don't want to hang in a loop
if (m_Factory.pPluginsList == this) m_Factory.pPluginsList = m_pNext;
if (m_pMixStruct)
{
m_pMixStruct->pMixPlugin = nullptr;
m_pMixStruct = nullptr;
}
if (m_pNext) m_pNext->m_pPrev = m_pPrev;
if (m_pPrev) m_pPrev->m_pNext = m_pNext;
m_pPrev = nullptr;
m_pNext = nullptr;
m_SndFile.m_loadedPlugins--;
}
void IMixPlugin::InsertIntoFactoryList()
{
m_pMixStruct->pMixPlugin = this;
m_pNext = m_Factory.pPluginsList;
if(m_Factory.pPluginsList)
{
m_Factory.pPluginsList->m_pPrev = this;
}
m_Factory.pPluginsList = this;
}
#ifdef MODPLUG_TRACKER
void IMixPlugin::SetSlot(PLUGINDEX slot)
{
m_nSlot = slot;
m_pMixStruct = &m_SndFile.m_MixPlugins[slot];
}
PlugParamValue IMixPlugin::GetScaledUIParam(PlugParamIndex param)
{
const auto [paramMin, paramMax] = GetParamUIRange(param);
return (std::clamp(GetParameter(param), paramMin, paramMax) - paramMin) / (paramMax - paramMin);
}
void IMixPlugin::SetScaledUIParam(PlugParamIndex param, PlugParamValue value)
{
const auto [paramMin, paramMax] = GetParamUIRange(param);
const auto scaledVal = paramMin + std::clamp(value, 0.0f, 1.0f) * (paramMax - paramMin);
SetParameter(param, scaledVal);
}
CString IMixPlugin::GetFormattedParamName(PlugParamIndex param)
{
CString paramName = GetParamName(param);
CString name;
if(paramName.IsEmpty())
{
name = MPT_CFORMAT("{}: Parameter {}")(mpt::cfmt::dec0<2>(param), mpt::cfmt::dec0<2>(param));
} else
{
name = MPT_CFORMAT("{}: {}")(mpt::cfmt::dec0<2>(param), paramName);
}
return name;
}
// Get a parameter's current value, represented by the plugin.
CString IMixPlugin::GetFormattedParamValue(PlugParamIndex param)
{
CString paramDisplay = GetParamDisplay(param);
CString paramUnits = GetParamLabel(param);
paramDisplay.Trim();
paramUnits.Trim();
paramDisplay += _T(" ") + paramUnits;
return paramDisplay;
}
CString IMixPlugin::GetFormattedProgramName(int32 index)
{
CString rawname = GetProgramName(index);
// Let's start counting at 1 for the program name (as most MIDI hardware / software does)
index++;
CString formattedName;
if(rawname[0] >= 0 && rawname[0] < _T(' '))
formattedName = MPT_CFORMAT("{} - Program {}")(mpt::cfmt::dec0<2>(index), index);
else
formattedName = MPT_CFORMAT("{} - {}")(mpt::cfmt::dec0<2>(index), rawname);
return formattedName;
}
void IMixPlugin::SetEditorPos(int32 x, int32 y)
{
m_pMixStruct->editorX = x;
m_pMixStruct->editorY = y;
}
void IMixPlugin::GetEditorPos(int32 &x, int32 &y) const
{
x = m_pMixStruct->editorX;
y = m_pMixStruct->editorY;
}
#endif // MODPLUG_TRACKER
bool IMixPlugin::IsBypassed() const
{
return m_pMixStruct != nullptr && m_pMixStruct->IsBypassed();
}
void IMixPlugin::RecalculateGain()
{
float gain = 0.1f * static_cast<float>(m_pMixStruct ? m_pMixStruct->GetGain() : 10);
if(gain < 0.1f) gain = 1.0f;
if(IsInstrument())
{
gain /= m_SndFile.GetPlayConfig().getVSTiAttenuation();
gain = static_cast<float>(gain * (m_SndFile.m_nVSTiVolume / m_SndFile.GetPlayConfig().getNormalVSTiVol()));
}
m_fGain = gain;
}
void IMixPlugin::SetDryRatio(float dryRatio)
{
m_pMixStruct->fDryRatio = std::clamp(dryRatio, 0.0f, 1.0f);
#ifdef MODPLUG_TRACKER
m_SndFile.m_pluginDryWetRatioChanged.set(m_nSlot);
#endif // MODPLUG_TRACKER
}
void IMixPlugin::Bypass(bool bypass)
{
m_pMixStruct->Info.SetBypass(bypass);
#ifdef MODPLUG_TRACKER
if(m_SndFile.GetpModDoc())
m_SndFile.GetpModDoc()->UpdateAllViews(nullptr, PluginHint(m_nSlot + 1).Info(), nullptr);
#endif // MODPLUG_TRACKER
}
double IMixPlugin::GetOutputLatency() const
{
if(GetSoundFile().IsRenderingToDisc())
return 0;
else
return GetSoundFile().m_TimingInfo.OutputLatency;
}
void IMixPlugin::ProcessMixOps(float * MPT_RESTRICT pOutL, float * MPT_RESTRICT pOutR, float * MPT_RESTRICT leftPlugOutput, float * MPT_RESTRICT rightPlugOutput, uint32 numFrames)
{
/* float *leftPlugOutput;
float *rightPlugOutput;
if(m_Effect.numOutputs == 1)
{
// If there was just the one plugin output we copy it into our 2 outputs
leftPlugOutput = rightPlugOutput = mixBuffer.GetOutputBuffer(0);
} else if(m_Effect.numOutputs > 1)
{
// Otherwise we actually only cater for two outputs max (outputs > 2 have been mixed together already).
leftPlugOutput = mixBuffer.GetOutputBuffer(0);
rightPlugOutput = mixBuffer.GetOutputBuffer(1);
} else
{
return;
}*/
// -> mixop == 0 : normal processing
// -> mixop == 1 : MIX += DRY - WET * wetRatio
// -> mixop == 2 : MIX += WET - DRY * dryRatio
// -> mixop == 3 : MIX -= WET - DRY * wetRatio
// -> mixop == 4 : MIX -= middle - WET * wetRatio + middle - DRY
// -> mixop == 5 : MIX_L += wetRatio * (WET_L - DRY_L) + dryRatio * (DRY_R - WET_R)
// MIX_R += dryRatio * (WET_L - DRY_L) + wetRatio * (DRY_R - WET_R)
MPT_ASSERT(m_pMixStruct != nullptr);
int mixop;
if(IsInstrument())
{
// Force normal mix mode for instruments
mixop = 0;
} else
{
mixop = m_pMixStruct->GetMixMode();
}
float wetRatio = 1 - m_pMixStruct->fDryRatio;
float dryRatio = IsInstrument() ? 1 : m_pMixStruct->fDryRatio; // Always mix full dry if this is an instrument
// Wet / Dry range expansion [0,1] -> [-1,1]
if(GetNumInputChannels() > 0 && m_pMixStruct->IsExpandedMix())
{
wetRatio = 2.0f * wetRatio - 1.0f;
dryRatio = -wetRatio;
}
wetRatio *= m_fGain;
dryRatio *= m_fGain;
float * MPT_RESTRICT plugInputL = m_mixBuffer.GetInputBuffer(0);
float * MPT_RESTRICT plugInputR = m_mixBuffer.GetInputBuffer(1);
// Mix operation
switch(mixop)
{
// Default mix
case 0:
for(uint32 i = 0; i < numFrames; i++)
{
//rewbs.wetratio - added the factors. [20040123]
pOutL[i] += leftPlugOutput[i] * wetRatio + plugInputL[i] * dryRatio;
pOutR[i] += rightPlugOutput[i] * wetRatio + plugInputR[i] * dryRatio;
}
break;
// Wet subtract
case 1:
for(uint32 i = 0; i < numFrames; i++)
{
pOutL[i] += plugInputL[i] - leftPlugOutput[i] * wetRatio;
pOutR[i] += plugInputR[i] - rightPlugOutput[i] * wetRatio;
}
break;
// Dry subtract
case 2:
for(uint32 i = 0; i < numFrames; i++)
{
pOutL[i] += leftPlugOutput[i] - plugInputL[i] * dryRatio;
pOutR[i] += rightPlugOutput[i] - plugInputR[i] * dryRatio;
}
break;
// Mix subtract
case 3:
for(uint32 i = 0; i < numFrames; i++)
{
pOutL[i] -= leftPlugOutput[i] - plugInputL[i] * wetRatio;
pOutR[i] -= rightPlugOutput[i] - plugInputR[i] * wetRatio;
}
break;
// Middle subtract
case 4:
for(uint32 i = 0; i < numFrames; i++)
{
float middle = (pOutL[i] + plugInputL[i] + pOutR[i] + plugInputR[i]) / 2.0f;
pOutL[i] -= middle - leftPlugOutput[i] * wetRatio + middle - plugInputL[i];
pOutR[i] -= middle - rightPlugOutput[i] * wetRatio + middle - plugInputR[i];
}
break;
// Left / Right balance
case 5:
if(m_pMixStruct->IsExpandedMix())
{
wetRatio /= 2.0f;
dryRatio /= 2.0f;
}
for(uint32 i = 0; i < numFrames; i++)
{
pOutL[i] += wetRatio * (leftPlugOutput[i] - plugInputL[i]) + dryRatio * (plugInputR[i] - rightPlugOutput[i]);
pOutR[i] += dryRatio * (leftPlugOutput[i] - plugInputL[i]) + wetRatio * (plugInputR[i] - rightPlugOutput[i]);
}
break;
}
// If dry mix is ticked, we add the unprocessed buffer,
// except if this is an instrument since then it has already been done:
if(m_pMixStruct->IsWetMix() && !IsInstrument())
{
for(uint32 i = 0; i < numFrames; i++)
{
pOutL[i] += plugInputL[i];
pOutR[i] += plugInputR[i];
}
}
}
// Render some silence and return maximum level returned by the plugin.
float IMixPlugin::RenderSilence(uint32 numFrames)
{
// The JUCE framework doesn't like processing while being suspended.
const bool wasSuspended = !IsResumed();
if(wasSuspended)
{
Resume();
}
float out[2][MIXBUFFERSIZE]; // scratch buffers
float maxVal = 0.0f;
m_mixBuffer.ClearInputBuffers(MIXBUFFERSIZE);
while(numFrames > 0)
{
uint32 renderSamples = numFrames;
LimitMax(renderSamples, mpt::saturate_cast<uint32>(std::size(out[0])));
MemsetZero(out);
Process(out[0], out[1], renderSamples);
for(size_t i = 0; i < renderSamples; i++)
{
maxVal = std::max(maxVal, std::fabs(out[0][i]));
maxVal = std::max(maxVal, std::fabs(out[1][i]));
}
numFrames -= renderSamples;
}
if(wasSuspended)
{
Suspend();
}
return maxVal;
}
// Get list of plugins to which output is sent. A nullptr indicates master output.
size_t IMixPlugin::GetOutputPlugList(std::vector<IMixPlugin *> &list)
{
// At the moment we know there will only be 1 output.
// Returning nullptr means plugin outputs directly to master.
list.clear();
IMixPlugin *outputPlug = nullptr;
if(!m_pMixStruct->IsOutputToMaster())
{
PLUGINDEX nOutput = m_pMixStruct->GetOutputPlugin();
if(nOutput > m_nSlot && nOutput != PLUGINDEX_INVALID)
{
outputPlug = m_SndFile.m_MixPlugins[nOutput].pMixPlugin;
}
}
list.push_back(outputPlug);
return 1;
}
// Get a list of plugins that send data to this plugin.
size_t IMixPlugin::GetInputPlugList(std::vector<IMixPlugin *> &list)
{
std::vector<IMixPlugin *> candidatePlugOutputs;
list.clear();
for(PLUGINDEX plug = 0; plug < MAX_MIXPLUGINS; plug++)
{
IMixPlugin *candidatePlug = m_SndFile.m_MixPlugins[plug].pMixPlugin;
if(candidatePlug)
{
candidatePlug->GetOutputPlugList(candidatePlugOutputs);
for(auto &outPlug : candidatePlugOutputs)
{
if(outPlug == this)
{
list.push_back(candidatePlug);
break;
}
}
}
}
return list.size();
}
// Get a list of instruments that send data to this plugin.
size_t IMixPlugin::GetInputInstrumentList(std::vector<INSTRUMENTINDEX> &list)
{
list.clear();
const PLUGINDEX nThisMixPlug = m_nSlot + 1; //m_nSlot is position in mixplug array.
for(INSTRUMENTINDEX ins = 0; ins <= m_SndFile.GetNumInstruments(); ins++)
{
if(m_SndFile.Instruments[ins] != nullptr && m_SndFile.Instruments[ins]->nMixPlug == nThisMixPlug)
{
list.push_back(ins);
}
}
return list.size();
}
size_t IMixPlugin::GetInputChannelList(std::vector<CHANNELINDEX> &list)
{
list.clear();
PLUGINDEX nThisMixPlug = m_nSlot + 1; //m_nSlot is position in mixplug array.
const CHANNELINDEX chnCount = m_SndFile.GetNumChannels();
for(CHANNELINDEX nChn=0; nChn<chnCount; nChn++)
{
if(m_SndFile.ChnSettings[nChn].nMixPlugin == nThisMixPlug)
{
list.push_back(nChn);
}
}
return list.size();
}
void IMixPlugin::SaveAllParameters()
{
if (m_pMixStruct == nullptr)
{
return;
}
m_pMixStruct->defaultProgram = -1;
// Default implementation: Save all parameter values
PlugParamIndex numParams = std::min(GetNumParameters(), static_cast<PlugParamIndex>((std::numeric_limits<uint32>::max() - sizeof(uint32)) / sizeof(IEEE754binary32LE)));
uint32 nLen = numParams * sizeof(IEEE754binary32LE);
if (!nLen) return;
nLen += sizeof(uint32);
try
{
m_pMixStruct->pluginData.resize(nLen);
auto memFile = std::make_pair(mpt::as_span(m_pMixStruct->pluginData), mpt::IO::Offset(0));
mpt::IO::WriteIntLE<uint32>(memFile, 0); // Plugin data type
BeginGetProgram();
for(PlugParamIndex i = 0; i < numParams; i++)
{
mpt::IO::Write(memFile, IEEE754binary32LE(GetParameter(i)));
}
EndGetProgram();
} catch(mpt::out_of_memory e)
{
m_pMixStruct->pluginData.clear();
mpt::delete_out_of_memory(e);
}
}
void IMixPlugin::RestoreAllParameters(int32 /*program*/)
{
if(m_pMixStruct != nullptr && m_pMixStruct->pluginData.size() >= sizeof(uint32))
{
FileReader memFile(mpt::as_span(m_pMixStruct->pluginData));
uint32 type = memFile.ReadUint32LE();
if(type == 0)
{
const uint32 numParams = GetNumParameters();
if((m_pMixStruct->pluginData.size() - sizeof(uint32)) >= (numParams * sizeof(IEEE754binary32LE)))
{
BeginSetProgram();
for(uint32 i = 0; i < numParams; i++)
{
const auto value = memFile.ReadFloatLE();
SetParameter(i, std::isfinite(value) ? value : 0.0f);
}
EndSetProgram();
}
}
}
}
#ifdef MODPLUG_TRACKER
void IMixPlugin::ToggleEditor()
{
// We only really need this mutex for bridged plugins, as we may be processing window messages (in the same thread) while the editor opens.
// The user could press the toggle button while the editor is loading and thus close the editor while still being initialized.
// Note that this does not protect against closing the module while the editor is still loading.
static bool initializing = false;
if(initializing)
return;
initializing = true;
if (m_pEditor)
{
CloseEditor();
} else
{
m_pEditor = OpenEditor();
if (m_pEditor)
m_pEditor->OpenEditor(CMainFrame::GetMainFrame());
}
initializing = false;
}
// Provide default plugin editor
CAbstractVstEditor *IMixPlugin::OpenEditor()
{
try
{
return new CDefaultVstEditor(*this);
} catch(mpt::out_of_memory e)
{
mpt::delete_out_of_memory(e);
return nullptr;
}
}
void IMixPlugin::CloseEditor()
{
if(m_pEditor)
{
if (m_pEditor->m_hWnd) m_pEditor->DoClose();
delete m_pEditor;
m_pEditor = nullptr;
}
}
// Automate a parameter from the plugin GUI (both custom and default plugin GUI)
void IMixPlugin::AutomateParameter(PlugParamIndex param)
{
CModDoc *modDoc = GetModDoc();
if(modDoc == nullptr)
{
return;
}
// TODO: Check if any params are actually automatable, and if there are but this one isn't, chicken out
if(m_recordAutomation)
{
// Record parameter change
modDoc->RecordParamChange(GetSlot(), param);
}
modDoc->SendNotifyMessageToAllViews(WM_MOD_PLUGPARAMAUTOMATE, m_nSlot, param);
if(auto *vstEditor = GetEditor(); vstEditor && vstEditor->m_hWnd)
{
// Mark track modified if GUI is open and format supports plugins
SetModified();
// Do not use InputHandler in case we are coming from a bridged plugin editor
if((GetAsyncKeyState(VK_SHIFT) & 0x8000) && TrackerSettings::Instance().midiMappingInPluginEditor)
{
// Shift pressed -> Open MIDI mapping dialog
CMainFrame::GetMainFrame()->PostMessage(WM_MOD_MIDIMAPPING, m_nSlot, param);
}
// Learn macro
int macroToLearn = vstEditor->GetLearnMacro();
if (macroToLearn > -1)
{
modDoc->LearnMacro(macroToLearn, param);
vstEditor->SetLearnMacro(-1);
}
}
}
void IMixPlugin::SetModified()
{
CModDoc *modDoc = GetModDoc();
if(modDoc != nullptr && m_SndFile.GetModSpecifications().supportsPlugins)
{
modDoc->SetModified();
}
}
bool IMixPlugin::SaveProgram()
{
mpt::PathString defaultDir = TrackerSettings::Instance().PathPluginPresets.GetWorkingDir();
const bool useDefaultDir = !defaultDir.empty();
if(!useDefaultDir && m_Factory.dllPath.IsFile())
{
defaultDir = m_Factory.dllPath.GetPath();
}
CString progName = m_Factory.libraryName.ToCString() + _T(" - ") + GetCurrentProgramName();
SanitizeFilename(progName);
FileDialog dlg = SaveFileDialog()
.DefaultExtension("fxb")
.DefaultFilename(progName)
.ExtensionFilter("VST Plugin Programs (*.fxp)|*.fxp|"
"VST Plugin Banks (*.fxb)|*.fxb||")
.WorkingDirectory(defaultDir);
if(!dlg.Show(m_pEditor)) return false;
if(useDefaultDir)
{
TrackerSettings::Instance().PathPluginPresets.SetWorkingDir(dlg.GetWorkingDirectory());
}
const bool isBank = (dlg.GetExtension() == P_("fxb"));
try
{
mpt::SafeOutputFile sf(dlg.GetFirstFile(), std::ios::binary, mpt::FlushModeFromBool(TrackerSettings::Instance().MiscFlushFileBuffersOnSave));
mpt::ofstream &f = sf;
f.exceptions(f.exceptions() | std::ios::badbit | std::ios::failbit);
if(f.good() && VSTPresets::SaveFile(f, *this, isBank))
return true;
} catch(const std::exception &)
{
}
Reporting::Error("Error saving preset.", m_pEditor);
return false;
}
bool IMixPlugin::LoadProgram(mpt::PathString fileName)
{
mpt::PathString defaultDir = TrackerSettings::Instance().PathPluginPresets.GetWorkingDir();
bool useDefaultDir = !defaultDir.empty();
if(!useDefaultDir && m_Factory.dllPath.IsFile())
{
defaultDir = m_Factory.dllPath.GetPath();
}
if(fileName.empty())
{
FileDialog dlg = OpenFileDialog()
.DefaultExtension("fxp")
.ExtensionFilter("VST Plugin Programs and Banks (*.fxp,*.fxb)|*.fxp;*.fxb|"
"VST Plugin Programs (*.fxp)|*.fxp|"
"VST Plugin Banks (*.fxb)|*.fxb|"
"All Files|*.*||")
.WorkingDirectory(defaultDir);
if(!dlg.Show(m_pEditor)) return false;
if(useDefaultDir)
{
TrackerSettings::Instance().PathPluginPresets.SetWorkingDir(dlg.GetWorkingDirectory());
}
fileName = dlg.GetFirstFile();
}
const char *errorStr = nullptr;
InputFile f(fileName, SettingCacheCompleteFileBeforeLoading());
if(f.IsValid())
{
FileReader file = GetFileReader(f);
errorStr = VSTPresets::GetErrorMessage(VSTPresets::LoadFile(file, *this));
} else
{
errorStr = "Can't open file.";
}
if(errorStr == nullptr)
{
if(GetModDoc() != nullptr && GetSoundFile().GetModSpecifications().supportsPlugins)
{
GetModDoc()->SetModified();
}
return true;
} else
{
Reporting::Error(errorStr, m_pEditor);
return false;
}
}
#endif // MODPLUG_TRACKER
////////////////////////////////////////////////////////////////////
// IMidiPlugin: Default implementation of plugins with MIDI input //
////////////////////////////////////////////////////////////////////
IMidiPlugin::IMidiPlugin(VSTPluginLib &factory, CSoundFile &sndFile, SNDMIXPLUGIN *mixStruct)
: IMixPlugin(factory, sndFile, mixStruct)
, m_MidiCh{{}}
{
for(auto &chn : m_MidiCh)
{
chn.midiPitchBendPos = EncodePitchBendParam(MIDIEvents::pitchBendCentre); // centre pitch bend on all channels
chn.ResetProgram();
}
}
void IMidiPlugin::ApplyPitchWheelDepth(int32 &value, int8 pwd)
{
if(pwd != 0)
{
value = (value * ((MIDIEvents::pitchBendMax - MIDIEvents::pitchBendCentre + 1) / 64)) / pwd;
} else
{
value = 0;
}
}
// Get the MIDI channel currently associated with a given tracker channel
uint8 IMidiPlugin::GetMidiChannel(const ModChannel &chn, CHANNELINDEX trackChannel) const
{
if(auto ins = chn.pModInstrument; ins != nullptr)
return ins->GetMIDIChannel(chn, trackChannel);
else
return 0;
}
uint8 IMidiPlugin::GetMidiChannel(CHANNELINDEX trackChannel) const
{
if(trackChannel < std::size(m_SndFile.m_PlayState.Chn))
return GetMidiChannel(m_SndFile.m_PlayState.Chn[trackChannel], trackChannel);
else
return 0;
}
void IMidiPlugin::MidiCC(MIDIEvents::MidiCC nController, uint8 nParam, CHANNELINDEX trackChannel)
{
//Error checking
LimitMax(nController, MIDIEvents::MIDICC_end);
LimitMax(nParam, uint8(127));
auto midiCh = GetMidiChannel(trackChannel);
if(m_SndFile.m_playBehaviour[kMIDICCBugEmulation])
MidiSend(MIDIEvents::Event(MIDIEvents::evControllerChange, midiCh, nParam, static_cast<uint8>(nController))); // param and controller are swapped (old broken implementation)
else
MidiSend(MIDIEvents::CC(nController, midiCh, nParam));
}
// Set MIDI pitch for given MIDI channel to the specified raw 14-bit position
void IMidiPlugin::MidiPitchBendRaw(int32 pitchbend, CHANNELINDEX trackerChn)
{
SendMidiPitchBend(GetMidiChannel(trackerChn), EncodePitchBendParam(Clamp(pitchbend, MIDIEvents::pitchBendMin, MIDIEvents::pitchBendMax)));
}
// Bend MIDI pitch for given MIDI channel using fine tracker param (one unit = 1/64th of a note step)
void IMidiPlugin::MidiPitchBend(int32 increment, int8 pwd, CHANNELINDEX trackerChn)
{
auto midiCh = GetMidiChannel(trackerChn);
if(m_SndFile.m_playBehaviour[kOldMIDIPitchBends])
{
// OpenMPT Legacy: Old pitch slides never were really accurate, but setting the PWD to 13 in plugins would give the closest results.
increment = (increment * 0x800 * 13) / (0xFF * pwd);
increment = EncodePitchBendParam(increment);
} else
{
increment = EncodePitchBendParam(increment);
ApplyPitchWheelDepth(increment, pwd);
}
int32 newPitchBendPos = (increment + m_MidiCh[midiCh].midiPitchBendPos) & kPitchBendMask;
Limit(newPitchBendPos, EncodePitchBendParam(MIDIEvents::pitchBendMin), EncodePitchBendParam(MIDIEvents::pitchBendMax));
SendMidiPitchBend(midiCh, newPitchBendPos);
}
// Set MIDI pitch for given MIDI channel using fixed point pitch bend value (converted back to 0-16383 MIDI range)
void IMidiPlugin::SendMidiPitchBend(uint8 midiCh, int32 newPitchBendPos)
{
MPT_ASSERT(EncodePitchBendParam(MIDIEvents::pitchBendMin) <= newPitchBendPos && newPitchBendPos <= EncodePitchBendParam(MIDIEvents::pitchBendMax));
m_MidiCh[midiCh].midiPitchBendPos = newPitchBendPos;
MidiSend(MIDIEvents::PitchBend(midiCh, DecodePitchBendParam(newPitchBendPos)));
}
// Apply vibrato effect through pitch wheel commands on a given MIDI channel.
void IMidiPlugin::MidiVibrato(int32 depth, int8 pwd, CHANNELINDEX trackerChn)
{
auto midiCh = GetMidiChannel(trackerChn);
depth = EncodePitchBendParam(depth);
if(depth != 0 || (m_MidiCh[midiCh].midiPitchBendPos & kVibratoFlag))
{
ApplyPitchWheelDepth(depth, pwd);
// Temporarily add vibrato offset to current pitch
int32 newPitchBendPos = (depth + m_MidiCh[midiCh].midiPitchBendPos) & kPitchBendMask;
Limit(newPitchBendPos, EncodePitchBendParam(MIDIEvents::pitchBendMin), EncodePitchBendParam(MIDIEvents::pitchBendMax));
MidiSend(MIDIEvents::PitchBend(midiCh, DecodePitchBendParam(newPitchBendPos)));
}
// Update vibrato status
if(depth != 0)
m_MidiCh[midiCh].midiPitchBendPos |= kVibratoFlag;
else
m_MidiCh[midiCh].midiPitchBendPos &= ~kVibratoFlag;
}
void IMidiPlugin::MidiCommand(const ModInstrument &instr, uint16 note, uint16 vol, CHANNELINDEX trackChannel)
{
if(trackChannel >= MAX_CHANNELS)
return;
auto midiCh = GetMidiChannel(trackChannel);
PlugInstrChannel &channel = m_MidiCh[midiCh];
uint16 midiBank = instr.wMidiBank - 1;
uint8 midiProg = instr.nMidiProgram - 1;
bool bankChanged = (channel.currentBank != midiBank) && (midiBank < 0x4000);
bool progChanged = (channel.currentProgram != midiProg) && (midiProg < 0x80);
//get vol in [0,128[
uint8 volume = static_cast<uint8>(std::min((vol + 1u) / 2u, 127u));
// Bank change
if(bankChanged)
{
uint8 high = static_cast<uint8>(midiBank >> 7);
uint8 low = static_cast<uint8>(midiBank & 0x7F);
//m_SndFile.ProcessMIDIMacro(trackChannel, false, m_SndFile.m_MidiCfg.Global[MIDIOUT_BANKSEL], 0, m_nSlot + 1);
MidiSend(MIDIEvents::CC(MIDIEvents::MIDICC_BankSelect_Coarse, midiCh, high));
MidiSend(MIDIEvents::CC(MIDIEvents::MIDICC_BankSelect_Fine, midiCh, low));
channel.currentBank = midiBank;
}
// Program change
// According to the MIDI specs, a bank change alone doesn't have to change the active program - it will only change the bank of subsequent program changes.
// Thus we send program changes also if only the bank has changed.
if(progChanged || (midiProg < 0x80 && bankChanged))
{
channel.currentProgram = midiProg;
//m_SndFile.ProcessMIDIMacro(trackChannel, false, m_SndFile.m_MidiCfg.Global[MIDIOUT_PROGRAM], 0, m_nSlot + 1);
MidiSend(MIDIEvents::ProgramChange(midiCh, midiProg));
}
// Specific Note Off
if(note > NOTE_MAX_SPECIAL)
{
uint8 i = static_cast<uint8>(note - NOTE_MAX_SPECIAL - NOTE_MIN);
if(channel.noteOnMap[i][trackChannel])
{
channel.noteOnMap[i][trackChannel]--;
MidiSend(MIDIEvents::NoteOff(midiCh, i, 0));
}
}
// "Hard core" All Sounds Off on this midi and tracker channel
// This one doesn't check the note mask - just one note off per note.
// Also less likely to cause a VST event buffer overflow.
else if(note == NOTE_NOTECUT) // ^^
{
MidiSend(MIDIEvents::CC(MIDIEvents::MIDICC_AllNotesOff, midiCh, 0));
MidiSend(MIDIEvents::CC(MIDIEvents::MIDICC_AllSoundOff, midiCh, 0));
// Turn off all notes
for(uint8 i = 0; i < std::size(channel.noteOnMap); i++)
{
channel.noteOnMap[i][trackChannel] = 0;
MidiSend(MIDIEvents::NoteOff(midiCh, i, volume));
}
}
// All "active" notes off on this midi and tracker channel
// using note mask.
else if(note == NOTE_KEYOFF || note == NOTE_FADE) // ==, ~~
{
for(uint8 i = 0; i < std::size(channel.noteOnMap); i++)
{
// Some VSTis need a note off for each instance of a note on, e.g. fabfilter.
while(channel.noteOnMap[i][trackChannel])
{
MidiSend(MIDIEvents::NoteOff(midiCh, i, volume));
channel.noteOnMap[i][trackChannel]--;
}
}
}
// Note On
else if(note >= NOTE_MIN && note < NOTE_MIN + mpt::array_size<decltype(channel.noteOnMap)>::size)
{
note -= NOTE_MIN;
// Reset pitch bend on each new note, tracker style.
// This is done if the pitch wheel has been moved or there was a vibrato on the previous row (in which case the "vstVibratoFlag" bit of the pitch bend memory is set)
auto newPitchBendPos = EncodePitchBendParam(Clamp(m_SndFile.m_PlayState.Chn[trackChannel].GetMIDIPitchBend(), MIDIEvents::pitchBendMin, MIDIEvents::pitchBendMax));
if(m_MidiCh[midiCh].midiPitchBendPos != newPitchBendPos)
{
SendMidiPitchBend(midiCh, newPitchBendPos);
}
// count instances of active notes.
// This is to send a note off for each instance of a note, for plugs like Fabfilter.
// Problem: if a note dies out naturally and we never send a note off, this counter
// will block at max until note off. Is this a problem?
// Safe to assume we won't need more than 255 note offs max on a given note?
if(channel.noteOnMap[note][trackChannel] < uint8_max)
{
channel.noteOnMap[note][trackChannel]++;
}
MidiSend(MIDIEvents::NoteOn(midiCh, static_cast<uint8>(note), volume));
}
}
bool IMidiPlugin::IsNotePlaying(uint8 note, CHANNELINDEX trackerChn)
{
if(!ModCommand::IsNote(note) || trackerChn >= std::size(m_MidiCh[GetMidiChannel(trackerChn)].noteOnMap[note]))
return false;
note -= NOTE_MIN;
return (m_MidiCh[GetMidiChannel(trackerChn)].noteOnMap[note][trackerChn] != 0);
}
void IMidiPlugin::ReceiveMidi(uint32 midiCode)
{
ResetSilence();
// I think we should only route events to plugins that are explicitely specified as output plugins of the current plugin.
// This should probably use GetOutputPlugList here if we ever get to support multiple output plugins.
PLUGINDEX receiver;
if(m_pMixStruct != nullptr && (receiver = m_pMixStruct->GetOutputPlugin()) != PLUGINDEX_INVALID)
{
IMixPlugin *plugin = m_SndFile.m_MixPlugins[receiver].pMixPlugin;
// Add all events to the plugin's queue.
plugin->MidiSend(midiCode);
}
#ifdef MODPLUG_TRACKER
if(m_recordMIDIOut)
{
// Spam MIDI data to all views
::PostMessage(CMainFrame::GetMainFrame()->GetMidiRecordWnd(), WM_MOD_MIDIMSG, midiCode, reinterpret_cast<LPARAM>(this));
}
#endif // MODPLUG_TRACKER
}
void IMidiPlugin::ReceiveSysex(mpt::const_byte_span sysex)
{
ResetSilence();
// I think we should only route events to plugins that are explicitely specified as output plugins of the current plugin.
// This should probably use GetOutputPlugList here if we ever get to support multiple output plugins.
PLUGINDEX receiver;
if(m_pMixStruct != nullptr && (receiver = m_pMixStruct->GetOutputPlugin()) != PLUGINDEX_INVALID)
{
IMixPlugin *plugin = m_SndFile.m_MixPlugins[receiver].pMixPlugin;
// Add all events to the plugin's queue.
plugin->MidiSysexSend(sysex);
}
}
// SNDMIXPLUGIN functions
void SNDMIXPLUGIN::SetGain(uint8 gain)
{
Info.gain = gain;
if(pMixPlugin != nullptr) pMixPlugin->RecalculateGain();
}
void SNDMIXPLUGIN::SetBypass(bool bypass)
{
if(pMixPlugin != nullptr)
pMixPlugin->Bypass(bypass);
else
Info.SetBypass(bypass);
}
void SNDMIXPLUGIN::Destroy()
{
if(pMixPlugin)
{
pMixPlugin->Release();
pMixPlugin = nullptr;
}
pluginData.clear();
pluginData.shrink_to_fit();
}
OPENMPT_NAMESPACE_END
#endif // NO_PLUGINS