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zmusic/thirdparty/opnmidi/opnmidi_midiplay.hpp
Wohlstand 72c23d98a3 Update libOPNMIDI library to 1.5.0 
## 1.5.0   2020-09-28
 * Drum note length expanding is now supported in real-time mode (Thanks to [Jean Pierre Cimalando](https://github.com/jpcima) for a work!)
 * Added support for OPNA chip with Neko Project II Kai YM2602 emulator usage (Thanks to [Jean Pierre Cimalando](https://github.com/jpcima) for a work!)
 * Added VGM file dumper which allows to output OPN2 commands into VGM file. (A new MIDI to VGM tool is now created with basing on libOPNMIDI)
 * Fixed an incorrect work of CC-121 (See https://github.com/Wohlstand/libADLMIDI/issues/227 for details)
 * Internality has been refactored and improved
2020-10-04 08:03:44 +02:00

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/*
* libOPNMIDI is a free Software MIDI synthesizer library with OPN2 (YM2612) emulation
*
* MIDI parser and player (Original code from ADLMIDI): Copyright (c) 2010-2014 Joel Yliluoma <bisqwit@iki.fi>
* OPNMIDI Library and YM2612 support: Copyright (c) 2017-2020 Vitaly Novichkov <admin@wohlnet.ru>
*
* Library is based on the ADLMIDI, a MIDI player for Linux and Windows with OPL3 emulation:
* http://iki.fi/bisqwit/source/adlmidi.html
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef OPNMIDI_MIDIPLAY_HPP
#define OPNMIDI_MIDIPLAY_HPP
#include "opnbank.h"
#include "opnmidi_private.hpp"
#include "opnmidi_ptr.hpp"
#include "structures/pl_list.hpp"
/**
* @brief Hooks of the internal events
*/
struct MIDIEventHooks
{
MIDIEventHooks() :
onNote(NULL),
onNote_userData(NULL),
onDebugMessage(NULL),
onDebugMessage_userData(NULL)
{}
//! Note on/off hooks
typedef void (*NoteHook)(void *userdata, int adlchn, int note, int ins, int pressure, double bend);
NoteHook onNote;
void *onNote_userData;
//! Library internal debug messages
typedef void (*DebugMessageHook)(void *userdata, const char *fmt, ...);
DebugMessageHook onDebugMessage;
void *onDebugMessage_userData;
};
class OPNMIDIplay
{
friend void opn2_reset(struct OPN2_MIDIPlayer*);
public:
explicit OPNMIDIplay(unsigned long sampleRate = 22050);
~OPNMIDIplay();
void applySetup();
void partialReset();
void resetMIDI();
private:
void resetMIDIDefaults(int offset = 0);
public:
/**********************Internal structures and classes**********************/
/**
* @brief Persistent settings for each MIDI channel
*/
struct MIDIchannel
{
//! Default MIDI volume
uint8_t def_volume;
//! Default LSB of a bend sensitivity
int def_bendsense_lsb;
//! Default MSB of a bend sensitivity
int def_bendsense_msb;
//! LSB Bank number
uint8_t bank_lsb,
//! MSB Bank number
bank_msb;
//! Current patch number
uint8_t patch;
//! Volume level
uint8_t volume,
//! Expression level
expression;
//! Panning level
uint8_t panning,
//! Vibrato level
vibrato,
//! Channel aftertouch level
aftertouch;
//! Portamento time
uint16_t portamento;
//! Is Pedal sustain active
bool sustain;
//! Is Soft pedal active
bool softPedal;
//! Is portamento enabled
bool portamentoEnable;
//! Source note number used by portamento
int8_t portamentoSource; // note number or -1
//! Portamento rate
double portamentoRate;
//! Per note Aftertouch values
uint8_t noteAftertouch[128];
//! Is note aftertouch has any non-zero value
bool noteAfterTouchInUse;
//! Reserved
char _padding[6];
//! Pitch bend value
int bend;
//! Pitch bend sensitivity
double bendsense;
//! Pitch bend sensitivity LSB value
int bendsense_lsb,
//! Pitch bend sensitivity MSB value
bendsense_msb;
//! Vibrato position value
double vibpos,
//! Vibrato speed value
vibspeed,
//! Vibrato depth value
vibdepth;
//! Vibrato delay time
int64_t vibdelay_us;
//! Last LSB part of RPN value received
uint8_t lastlrpn,
//! Last MSB poart of RPN value received
lastmrpn;
//! Interpret RPN value as NRPN
bool nrpn;
//! Brightness level
uint8_t brightness;
//! Is melodic channel turned into percussion
bool is_xg_percussion;
/**
* @brief Per-Note information
*/
struct NoteInfo
{
//! Note number
uint8_t note;
//! Current pressure
uint8_t vol;
//! Note vibrato (a part of Note Aftertouch feature)
uint8_t vibrato;
//! Tone selected on noteon:
int16_t noteTone;
//! Current tone (!= noteTone if gliding note)
double currentTone;
//! Gliding rate
double glideRate;
//! Patch selected on noteon; index to bank.ins[]
size_t midiins;
//! Is note the percussion instrument
bool isPercussion;
//! Note that plays missing instrument. Doesn't using any chip channels
bool isBlank;
//! Whether releasing and on extended life time defined by TTL
bool isOnExtendedLifeTime;
//! Time-to-live until release (short percussion note fix)
double ttl;
//! Patch selected
const OpnInstMeta *ains;
enum
{
MaxNumPhysChans = 2,
MaxNumPhysItemCount = MaxNumPhysChans
};
struct FindPredicate
{
explicit FindPredicate(unsigned note)
: note(note) {}
bool operator()(const NoteInfo &ni) const
{ return ni.note == note; }
unsigned note;
};
/**
* @brief Reference to currently using chip channel
*/
struct Phys
{
//! Destination chip channel
uint16_t chip_chan;
//! ins, inde to adl[]
OpnTimbre ains;
void assign(const Phys &oth)
{
ains = oth.ains;
}
bool operator==(const Phys &oth) const
{
return (ains == oth.ains);
}
bool operator!=(const Phys &oth) const
{
return !operator==(oth);
}
};
//! List of OPN2 channels it is currently occupying.
Phys chip_channels[MaxNumPhysItemCount];
//! Count of used channels.
unsigned chip_channels_count;
Phys *phys_find(unsigned chip_chan)
{
Phys *ph = NULL;
for(unsigned i = 0; i < chip_channels_count && !ph; ++i)
if(chip_channels[i].chip_chan == chip_chan)
ph = &chip_channels[i];
return ph;
}
Phys *phys_find_or_create(uint16_t chip_chan)
{
Phys *ph = phys_find(chip_chan);
if(!ph) {
if(chip_channels_count < MaxNumPhysItemCount) {
ph = &chip_channels[chip_channels_count++];
ph->chip_chan = chip_chan;
}
}
return ph;
}
Phys *phys_ensure_find_or_create(uint16_t chip_chan)
{
Phys *ph = phys_find_or_create(chip_chan);
assert(ph);
return ph;
}
void phys_erase_at(const Phys *ph)
{
intptr_t pos = ph - chip_channels;
assert(pos < static_cast<intptr_t>(chip_channels_count));
for(intptr_t i = pos + 1; i < static_cast<intptr_t>(chip_channels_count); ++i)
chip_channels[i - 1] = chip_channels[i];
--chip_channels_count;
}
void phys_erase(unsigned chip_chan)
{
Phys *ph = phys_find(chip_chan);
if(ph)
phys_erase_at(ph);
}
};
//! Reserved
char _padding2[5];
//! Count of gliding notes in this channel
unsigned gliding_note_count;
//! Count of notes having a TTL countdown in this channel
unsigned extended_note_count;
//! Active notes in the channel
pl_list<NoteInfo> activenotes;
typedef pl_list<NoteInfo>::iterator notes_iterator;
typedef pl_list<NoteInfo>::const_iterator const_notes_iterator;
notes_iterator find_activenote(unsigned note)
{
return activenotes.find_if(NoteInfo::FindPredicate(note));
}
notes_iterator ensure_find_activenote(unsigned note)
{
notes_iterator it = find_activenote(note);
assert(!it.is_end());
return it;
}
notes_iterator find_or_create_activenote(unsigned note)
{
notes_iterator it = find_activenote(note);
if(!it.is_end())
cleanupNote(it);
else
{
NoteInfo ni;
ni.note = note;
it = activenotes.insert(activenotes.end(), ni);
}
return it;
}
notes_iterator ensure_find_or_create_activenote(unsigned note)
{
notes_iterator it = find_or_create_activenote(note);
assert(!it.is_end());
return it;
}
/**
* @brief Reset channel into initial state
*/
void reset()
{
resetAllControllers();
patch = 0;
vibpos = 0;
bank_lsb = 0;
bank_msb = 0;
lastlrpn = 0;
lastmrpn = 0;
nrpn = false;
is_xg_percussion = false;
}
void resetAllControllers()
{
volume = def_volume;
brightness = 127;
panning = 64;
resetAllControllers121();
}
/**
* @brief Reset all MIDI controllers into initial state
*/
void resetAllControllers121()
{
bend = 0;
bendsense_msb = def_bendsense_msb;
bendsense_lsb = def_bendsense_lsb;
updateBendSensitivity();
expression = 127;
sustain = false;
softPedal = false;
vibrato = 0;
aftertouch = 0;
std::memset(noteAftertouch, 0, 128);
noteAfterTouchInUse = false;
vibspeed = 2 * 3.141592653 * 5.0;
vibdepth = 0.5 / 127;
vibdelay_us = 0;
portamento = 0;
portamentoEnable = false;
portamentoSource = -1;
portamentoRate = HUGE_VAL;
}
/**
* @brief Has channel vibrato to process
* @return
*/
bool hasVibrato()
{
return (vibrato > 0) || (aftertouch > 0) || noteAfterTouchInUse;
}
/**
* @brief Commit pitch bend sensitivity value from MSB and LSB
*/
void updateBendSensitivity()
{
int cent = bendsense_msb * 128 + bendsense_lsb;
bendsense = cent * (1.0 / (128 * 8192));
}
/**
* @brief Clean up the state of the active note before removal
*/
void cleanupNote(notes_iterator i)
{
NoteInfo &info = i->value;
if(info.glideRate != HUGE_VAL)
--gliding_note_count;
if(info.ttl > 0)
--extended_note_count;
}
MIDIchannel() :
def_volume(100),
def_bendsense_lsb(0),
def_bendsense_msb(2),
activenotes(128)
{
gliding_note_count = 0;
extended_note_count = 0;
reset();
}
};
/**
* @brief Additional information about OPN2 channels
*/
struct OpnChannel
{
struct Location
{
uint16_t MidCh;
uint8_t note;
bool operator==(const Location &l) const
{ return MidCh == l.MidCh && note == l.note; }
bool operator!=(const Location &l) const
{ return !operator==(l); }
char _padding[1];
};
struct LocationData
{
Location loc;
enum {
Sustain_None = 0x00,
Sustain_Pedal = 0x01,
Sustain_Sostenuto = 0x02,
Sustain_ANY = Sustain_Pedal | Sustain_Sostenuto
};
uint32_t sustained;
char _padding[3];
MIDIchannel::NoteInfo::Phys ins; // a copy of that in phys[]
//! Has fixed sustain, don't iterate "on" timeout
bool fixed_sustain;
//! Timeout until note will be allowed to be killed by channel manager while it is on
int64_t kon_time_until_neglible_us;
int64_t vibdelay_us;
struct FindPredicate
{
explicit FindPredicate(Location loc)
: loc(loc) {}
bool operator()(const LocationData &ld) const
{ return ld.loc == loc; }
Location loc;
};
};
//! Time left until sounding will be muted after key off
int64_t koff_time_until_neglible_us;
//! Recently passed instrument, improves a goodness of released but busy channel when matching
MIDIchannel::NoteInfo::Phys recent_ins;
pl_list<LocationData> users;
typedef pl_list<LocationData>::iterator users_iterator;
typedef pl_list<LocationData>::const_iterator const_users_iterator;
users_iterator find_user(const Location &loc)
{
return users.find_if(LocationData::FindPredicate(loc));
}
users_iterator find_or_create_user(const Location &loc)
{
users_iterator it = find_user(loc);
if(it.is_end() && users.size() != users.capacity())
{
LocationData ld;
ld.loc = loc;
it = users.insert(users.end(), ld);
}
return it;
}
// For channel allocation:
OpnChannel(): koff_time_until_neglible_us(0), users(128)
{
std::memset(&recent_ins, 0, sizeof(MIDIchannel::NoteInfo::Phys));
}
OpnChannel(const OpnChannel &oth): koff_time_until_neglible_us(oth.koff_time_until_neglible_us), users(oth.users)
{
}
OpnChannel &operator=(const OpnChannel &oth)
{
koff_time_until_neglible_us = oth.koff_time_until_neglible_us;
users = oth.users;
return *this;
}
/**
* @brief Increases age of active note in microseconds time
* @param us Amount time in microseconds
*/
void addAge(int64_t us);
};
#ifndef OPNMIDI_DISABLE_MIDI_SEQUENCER
/**
* @brief MIDI files player sequencer
*/
AdlMIDI_UPtr<MidiSequencer> m_sequencer;
/**
* @brief Interface between MIDI sequencer and this library
*/
AdlMIDI_UPtr<BW_MidiRtInterface> m_sequencerInterface;
/**
* @brief Initialize MIDI sequencer interface
*/
void initSequencerInterface();
#endif //OPNMIDI_DISABLE_MIDI_SEQUENCER
struct Setup
{
int emulator;
bool runAtPcmRate;
unsigned int OpnBank;
unsigned int numChips;
unsigned int LogarithmicVolumes;
int VolumeModel;
int lfoEnable;
int lfoFrequency;
int chipType;
//unsigned int SkipForward;
int ScaleModulators;
bool fullRangeBrightnessCC74;
double delay;
double carry;
/* The lag between visual content and audio content equals */
/* the sum of these two buffers. */
double mindelay;
double maxdelay;
/* For internal usage */
ssize_t tick_skip_samples_delay; /* Skip tick processing after samples count. */
/* For internal usage */
unsigned long PCM_RATE;
};
/**
* @brief MIDI Marker entry
*/
struct MIDI_MarkerEntry
{
//! Label of marker
std::string label;
//! Absolute position in seconds
double pos_time;
//! Absolute position in ticks in the track
uint64_t pos_ticks;
};
//! Available MIDI Channels
std::vector<MIDIchannel> m_midiChannels;
//! SysEx device ID
uint8_t m_sysExDeviceId;
/**
* @brief MIDI Synthesizer mode
*/
enum SynthMode
{
Mode_GM = 0x00,
Mode_GS = 0x01,
Mode_XG = 0x02,
Mode_GM2 = 0x04
};
//! MIDI Synthesizer mode
uint32_t m_synthMode;
//! Installed function hooks
MIDIEventHooks hooks;
private:
//! Per-track MIDI devices map
std::map<std::string, size_t> m_midiDevices;
//! Current MIDI device per track
std::map<size_t /*track*/, size_t /*channel begin index*/> m_currentMidiDevice;
//! Chip channels map
std::vector<OpnChannel> m_chipChannels;
//! Counter of arpeggio processing
size_t m_arpeggioCounter;
#if defined(ADLMIDI_AUDIO_TICK_HANDLER)
//! Audio tick counter
uint32_t m_audioTickCounter;
#endif
//! Local error string
std::string errorStringOut;
//! Missing instruments catches
std::set<size_t> caugh_missing_instruments;
//! Missing melodic banks catches
std::set<size_t> caugh_missing_banks_melodic;
//! Missing percussion banks catches
std::set<size_t> caugh_missing_banks_percussion;
public:
const std::string &getErrorString();
void setErrorString(const std::string &err);
//! OPN2 Chip manager
AdlMIDI_UPtr<Synth> m_synth;
//! Generator output buffer
int32_t m_outBuf[1024];
//! Synthesizer setup
Setup m_setup;
/**
* @brief Load bank from file
* @param filename Path to bank file
* @return true on succes
*/
bool LoadBank(const std::string &filename);
/**
* @brief Load bank from memory block
* @param data Pointer to memory block where raw bank file is stored
* @param size Size of given memory block
* @return true on succes
*/
bool LoadBank(const void *data, size_t size);
/**
* @brief Load bank from opened FileAndMemReader class
* @param fr Instance with opened file
* @return true on succes
*/
bool LoadBank(FileAndMemReader &fr);
#ifndef OPNMIDI_DISABLE_MIDI_SEQUENCER
/**
* @brief MIDI file loading pre-process
* @return true on success, false on failure
*/
bool LoadMIDI_pre();
/**
* @brief MIDI file loading post-process
* @return true on success, false on failure
*/
bool LoadMIDI_post();
/**
* @brief Load music file from a file
* @param filename Path to music file
* @return true on success, false on failure
*/
bool LoadMIDI(const std::string &filename);
/**
* @brief Load music file from the memory block
* @param data pointer to the memory block
* @param size size of memory block
* @return true on success, false on failure
*/
bool LoadMIDI(const void *data, size_t size);
/**
* @brief Periodic tick handler.
* @param s seconds since last call
* @param granularity don't expect intervals smaller than this, in seconds
* @return desired number of seconds until next call
*/
double Tick(double s, double granularity);
#endif //OPNMIDI_DISABLE_MIDI_SEQUENCER
/**
* @brief Process extra iterators like vibrato or arpeggio
* @param s seconds since last call
*/
void TickIterators(double s);
/* RealTime event triggers */
/**
* @brief Reset state of all channels
*/
void realTime_ResetState();
/**
* @brief Note On event
* @param channel MIDI channel
* @param note Note key (from 0 to 127)
* @param velocity Velocity level (from 0 to 127)
* @return true if Note On event was accepted
*/
bool realTime_NoteOn(uint8_t channel, uint8_t note, uint8_t velocity);
/**
* @brief Note Off event
* @param channel MIDI channel
* @param note Note key (from 0 to 127)
*/
void realTime_NoteOff(uint8_t channel, uint8_t note);
/**
* @brief Note aftertouch event
* @param channel MIDI channel
* @param note Note key (from 0 to 127)
* @param atVal After-Touch level (from 0 to 127)
*/
void realTime_NoteAfterTouch(uint8_t channel, uint8_t note, uint8_t atVal);
/**
* @brief Channel aftertouch event
* @param channel MIDI channel
* @param atVal After-Touch level (from 0 to 127)
*/
void realTime_ChannelAfterTouch(uint8_t channel, uint8_t atVal);
/**
* @brief Controller Change event
* @param channel MIDI channel
* @param type Type of controller
* @param value Value of the controller (from 0 to 127)
*/
void realTime_Controller(uint8_t channel, uint8_t type, uint8_t value);
/**
* @brief Patch change
* @param channel MIDI channel
* @param patch Patch Number (from 0 to 127)
*/
void realTime_PatchChange(uint8_t channel, uint8_t patch);
/**
* @brief Pitch bend change
* @param channel MIDI channel
* @param pitch Concoctated raw pitch value
*/
void realTime_PitchBend(uint8_t channel, uint16_t pitch);
/**
* @brief Pitch bend change
* @param channel MIDI channel
* @param msb MSB of pitch value
* @param lsb LSB of pitch value
*/
void realTime_PitchBend(uint8_t channel, uint8_t msb, uint8_t lsb);
/**
* @brief LSB Bank Change CC
* @param channel MIDI channel
* @param lsb LSB value of bank number
*/
void realTime_BankChangeLSB(uint8_t channel, uint8_t lsb);
/**
* @brief MSB Bank Change CC
* @param channel MIDI channel
* @param lsb MSB value of bank number
*/
void realTime_BankChangeMSB(uint8_t channel, uint8_t msb);
/**
* @brief Bank Change (united value)
* @param channel MIDI channel
* @param bank Bank number value
*/
void realTime_BankChange(uint8_t channel, uint16_t bank);
/**
* @brief Sets the Device identifier
* @param id 7-bit Device identifier
*/
void setDeviceId(uint8_t id);
/**
* @brief System Exclusive message
* @param msg Raw SysEx Message
* @param size Length of SysEx message
* @return true if message was passed successfully. False on any errors
*/
bool realTime_SysEx(const uint8_t *msg, size_t size);
/**
* @brief Turn off all notes and mute the sound of releasing notes
*/
void realTime_panic();
/**
* @brief Device switch (to extend 16-channels limit of MIDI standard)
* @param track MIDI track index
* @param data Device name
* @param length Length of device name string
*/
void realTime_deviceSwitch(size_t track, const char *data, size_t length);
/**
* @brief Currently selected device index
* @param track MIDI track index
* @return Multiple 16 value
*/
size_t realTime_currentDevice(size_t track);
#if defined(ADLMIDI_AUDIO_TICK_HANDLER)
// Audio rate tick handler
void AudioTick(uint32_t chipId, uint32_t rate);
#endif
private:
/**
* @brief Hardware manufacturer (Used for SysEx)
*/
enum
{
Manufacturer_Roland = 0x41,
Manufacturer_Yamaha = 0x43,
Manufacturer_UniversalNonRealtime = 0x7E,
Manufacturer_UniversalRealtime = 0x7F
};
/**
* @brief Roland Mode (Used for SysEx)
*/
enum
{
RolandMode_Request = 0x11,
RolandMode_Send = 0x12
};
/**
* @brief Device model (Used for SysEx)
*/
enum
{
RolandModel_GS = 0x42,
RolandModel_SC55 = 0x45,
YamahaModel_XG = 0x4C
};
/**
* @brief Process generic SysEx events
* @param dev Device ID
* @param realtime Is real-time event
* @param data Raw SysEx data
* @param size Size of given SysEx data
* @return true when event was successfully handled
*/
bool doUniversalSysEx(unsigned dev, bool realtime, const uint8_t *data, size_t size);
/**
* @brief Process events specific to Roland devices
* @param dev Device ID
* @param data Raw SysEx data
* @param size Size of given SysEx data
* @return true when event was successfully handled
*/
bool doRolandSysEx(unsigned dev, const uint8_t *data, size_t size);
/**
* @brief Process events specific to Yamaha devices
* @param dev Device ID
* @param data Raw SysEx data
* @param size Size of given SysEx data
* @return true when event was successfully handled
*/
bool doYamahaSysEx(unsigned dev, const uint8_t *data, size_t size);
private:
/**
* @brief Note Update properties
*/
enum
{
Upd_Patch = 0x1,
Upd_Pan = 0x2,
Upd_Volume = 0x4,
Upd_Pitch = 0x8,
Upd_All = Upd_Pan + Upd_Volume + Upd_Pitch,
Upd_Off = 0x20,
Upd_Mute = 0x40,
Upd_OffMute = Upd_Off + Upd_Mute
};
/**
* @brief Update active note
* @param MidCh MIDI Channel where note is processing
* @param i Iterator that points to active note in the MIDI channel
* @param props_mask Properties to update
* @param select_adlchn Specify chip channel, or -1 - all chip channels used by the note
*/
void noteUpdate(size_t midCh,
MIDIchannel::notes_iterator i,
unsigned props_mask,
int32_t select_adlchn = -1);
void noteUpdateAll(size_t midCh, unsigned props_mask);
/**
* @brief Determine how good a candidate this adlchannel would be for playing a note from this instrument.
* @param c Wanted chip channel
* @param ins Instrument wanted to be used in this channel
* @return Calculated coodness points
*/
int64_t calculateChipChannelGoodness(size_t c, const MIDIchannel::NoteInfo::Phys &ins) const;
/**
* @brief A new note will be played on this channel using this instrument.
* @param c Wanted chip channel
* @param ins Instrument wanted to be used in this channel
* Kill existing notes on this channel (or don't, if we do arpeggio)
*/
void prepareChipChannelForNewNote(size_t c, const MIDIchannel::NoteInfo::Phys &ins);
/**
* @brief Kills note that uses wanted channel. When arpeggio is possible, note is evaluating to another channel
* @param from_channel Wanted chip channel
* @param j Chip channel instance
* @param i MIDI Channel active note instance
*/
void killOrEvacuate(
size_t from_channel,
OpnChannel::users_iterator j,
MIDIchannel::notes_iterator i);
/**
* @brief Off all notes and silence sound
*/
void panic();
/**
* @brief Kill note, sustaining by pedal or sostenuto
* @param MidCh MIDI channel, -1 - all MIDI channels
* @param this_adlchn Chip channel, -1 - all chip channels
* @param sustain_type Type of systain to process
*/
void killSustainingNotes(int32_t midCh = -1,
int32_t this_adlchn = -1,
uint32_t sustain_type = OpnChannel::LocationData::Sustain_ANY);
/**
* @brief Find active notes and mark them as sostenuto-sustained
* @param MidCh MIDI channel, -1 - all MIDI channels
*/
void markSostenutoNotes(int32_t midCh = -1);
/**
* @brief Set RPN event value
* @param MidCh MIDI channel
* @param value 1 byte part of RPN value
* @param MSB is MSB or LSB part of value
*/
void setRPN(size_t midCh, unsigned value, bool MSB);
/**
* @brief Update portamento setup in MIDI channel
* @param midCh MIDI channel where portamento needed to be updated
*/
void updatePortamento(size_t midCh);
/**
* @brief Off the note
* @param midCh MIDI channel
* @param note Note to off
* @param forceNow Do not delay the key-off to a later time
*/
void noteOff(size_t midCh, uint8_t note, bool forceNow = false);
/**
* @brief Update processing of vibrato to amount of seconds
* @param amount Amount value in seconds
*/
void updateVibrato(double amount);
/**
* @brief Update auto-arpeggio
* @param amount Amount value in seconds [UNUSED]
*/
void updateArpeggio(double /*amount*/);
/**
* @brief Update Portamento gliding to amount of seconds
* @param amount Amount value in seconds
*/
void updateGlide(double amount);
public:
/**
* @brief Checks was device name used or not
* @param name Name of MIDI device
* @return Offset of the MIDI Channels, multiple to 16
*/
size_t chooseDevice(const std::string &name);
/**
* @brief Gets a textual description of the state of chip channels
* @param text character pointer for text
* @param attr character pointer for text attributes
* @param size number of characters available to write
*/
void describeChannels(char *text, char *attr, size_t size);
};
#endif // OPNMIDI_MIDIPLAY_HPP
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