/* ScummVM - Graphic Adventure Engine * * ScummVM is the legal property of its developers, whose names * are too numerous to list here. Please refer to the COPYRIGHT * file distributed with this source distribution. * * 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 2 * of the License, or (at your option) 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * */ #include "sci/sci.h" #include "common/file.h" #include "common/system.h" #include "common/textconsole.h" #include "audio/softsynth/fmtowns_pc98/pc98_audio.h" #include "sci/resource.h" #include "sci/sound/drivers/mididriver.h" /* PC-98 sound driver for: Quest for Glory 1 SCI_VERSION_0_LATE first driver type Police Quest 2 SCI_VERSION_0_LATE second driver type Castle of Dr. Brain SCI_VERSION_1_LATE third driver type Space Quest IV SCI_VERSION_1_LATE third driver type King's Quest V SCI_VERSION_1_LATE latest driver type */ namespace Sci { class MidiPart_PC9801; class SoundChannel_PC9801 { public: SoundChannel_PC9801(PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, int type, SciSpan instrumentData, bool &soundOn); virtual ~SoundChannel_PC9801(); void noteOff(); void noteOn(uint8 note, uint8 velo); virtual void processNoteEvent(uint8 note, bool noteOn); void update(); void setVolume(uint8 volume); virtual void reset(); virtual void toggleNoiseGenerator(bool) {} int getType() const { return _type; } uint8 _assign; uint8 _note; uint8 _sustain; uint16 _duration; protected: enum ChannelStatusFlags { kChanVbrEnable = 0x01, kChanVbrRestartEnv = 0x02, kChanKeyOn = 0x04, kChanNgEnable = 0x08, kChanNgRestartEnv = 0x10, kChanNgDecrease = 0x20, kChanVbrMode = 0x40, kChanVbrDecrease = 0x80 }; int recalculateFrequency(uint16 note, uint16 modifier, uint8 *destOctaveBlock, uint16 *destFrequency, uint8 *destVbrFrequencyModifier); uint8 getVolume(); virtual void processSounds(); void programChangeInit(SciSpan &data); void writeReg(uint8 part, uint8 reg, uint8 val); int8 _transpose; uint8 _vbrInitialDelay; uint8 _vbrEnvelopeTimer; uint8 _vbrEnvelopeSpeed; uint16 _frequencyCourse; uint8 _frequencyBlock; uint8 _frequencyNoteModifier; uint8 _vbrDepthIncr; uint8 _vbrDecrTime; uint8 _vbrDepthDecr; uint8 _vbrIncrTime; uint8 _vbrSensitivity; uint16 _vbrIncrStep; uint16 _vbrDecrStep; uint8 _vbrModulationTimer; uint16 _vbrFrequencyModifier; uint8 _vbrCur; uint8 _flags; const uint16 *_noteFrequency; const uint16 *_noteFrequencyModifier; SciSpan _instrumentData; const SciVersion _version; private: virtual void programChange(uint8 program) = 0; virtual bool prepareFrequencyAndVolume(bool updateVolume); virtual void sendSoundOnOff(bool noteOn) = 0; virtual void sendFrequency() = 0; virtual void sendVolume() = 0; uint8 _velo; uint8 _volume; uint8 _program; bool &_soundOn; MidiPart_PC9801 **_parts; PC98AudioCore *_pc98a; const int _type; }; class SoundChannel_PC9801_FM4OP : public SoundChannel_PC9801 { public: SoundChannel_PC9801_FM4OP(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchSize, bool &soundOn); virtual ~SoundChannel_PC9801_FM4OP() {} private: void programChange(uint8 program); void sendSoundOnOff(bool noteOn); void sendVolume(); void sendFrequency(); uint8 _operatorLevel[4]; uint8 _carrier; uint8 _operatorFlags; const uint8 _regPrt; const uint8 _regOffs; const uint8 _patchSize; }; class SoundChannel_PC9801_FM2OP : public SoundChannel_PC9801 { public: SoundChannel_PC9801_FM2OP(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchSize, bool &soundOn); virtual ~SoundChannel_PC9801_FM2OP() {} void processNoteEvent(uint8 note, bool noteOn); void reset(); private: void programChange(uint8 program); bool prepareFrequencyAndVolume(bool updateVolume); void processSounds(); void sendSoundOnOff(bool noteOn); void sendVolume(); void sendFrequency(); uint8 _operatorLevel[2]; uint8 _operatorFrqIndex[2]; uint16 _frequencyCourse2; uint8 _frequencyNoteModifier2; int16 _vbrFrequencyModifier2; uint16 _vbrIncrStep2; uint16 _vbrDecrStep2; uint8 _vbrCur2; static uint8 _activeOperators; const uint16 *_opFreqOffset; const uint8 _patchOffset; const uint8 _regPrt; const uint8 _regOffs; const uint8 _patchSize; }; class SoundChannel_PC9801_SSG : public SoundChannel_PC9801 { public: SoundChannel_PC9801_SSG(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchOffset, uint8 patchSize, bool &soundOn); virtual ~SoundChannel_PC9801_SSG() {} void reset(); void toggleNoiseGenerator(bool enable); private: enum { kEnvSSG_silent = 0x00, kEnvSSG_decay = 0x01, kEnvSSG_sustain = 0x02, kEnvSSG_attack = 0x03, kEnvSSG_keyOn = 0x10 }; void programChange(uint8 program); void processSounds(); void sendSoundOnOff(bool noteOn); void sendVolume(); void sendFrequency(); void updateNg(); void sendActiveChannelsStatus(); uint8 _instrumentChanMask; uint8 _chanDisableMask; uint8 _chanEnableMask1; uint8 _chanEnableMask2; uint8 _currentLevel; uint8 _ngPhaseStep; uint8 _ngPhase; uint8 _ngEnvelopeTimer; uint8 _ngSpeed; uint8 _ssgEnvelopeTimer; uint8 _ssgLevel; uint8 _ssgSpeed; uint8 _ssgEnvelopeState; bool _ccngEnabled; static uint8 _activeChannnelsStatus; SciSpan _selectedInstrument; const uint8 *_ngFreq; const uint8 _regOffs; const uint8 _patchOffset; const uint8 _patchSize; }; class MidiPart_PC9801 { public: MidiPart_PC9801(uint8 id, SoundChannel_PC9801 **channels, uint8 numChan, SciVersion version); ~MidiPart_PC9801() {} void noteOff(uint8 note); void noteOn(uint8 note, uint8 velo); void controlChangeVolume(uint8 vol); void controlChangeSustain(uint8 sus); void controlChangePolyphony(uint8 numChan); void controlChangeNoiseGenerator(uint8 status); void controlChangeAllNotesOff(); void programChange(uint8 prg); void pitchBend(int16 val); void addChannels(int num, int resetMissingChannels = -1, int channelType = -1); void dropChannels(int num); uint8 getCurrentProgram() const { return _program; } uint8 getCurrentVolume() const { return _volume; } uint16 getCurrentPitchBend() const { return _pitchBend; } uint8 getMissingChannels() const { return _chanMissing; } private: int allocateChannel(); void assignFreeChannels(); uint8 _id; uint8 _program; uint8 _volume; uint8 _sustain; uint16 _pitchBend; uint8 _outChan; uint8 _chanMissing; SoundChannel_PC9801 **_chan; const SciVersion _version; const int _numChan; const uint8 _noteRangeLow; const uint8 _noteRangeHigh; }; class MidiDriver_PC9801 : public MidiDriver, public PC98AudioPluginDriver { public: enum { MIDI_PROP_PLAYSWITCH = 1, MIDI_PROP_POLYPHONY = 2, MIDI_PROP_CHANNEL_ID = 3 }; MidiDriver_PC9801(Audio::Mixer *mixer, SciVersion version); ~MidiDriver_PC9801(); int open(); bool isOpen() const { return _isOpen; } void close(); void send(uint32 b); static void assignFreeChannels(int num); uint32 property(int prop, uint32 param); void initTrack(SciSpan &header); void setTimerCallback(void *timer_param, Common::TimerManager::TimerProc timer_proc); uint32 getBaseTempo(); MidiChannel *allocateChannel() { return 0; } MidiChannel *getPercussionChannel() { return 0; } void timerCallbackB(); private: bool loadInstruments(const SciSpan &data); void updateParser(); void updateChannels(); void reset(); Common::TimerManager::TimerProc _timerProc; void *_timerProcPara; static MidiPart_PC9801 **_parts; SoundChannel_PC9801 **_chan; Common::SpanOwner > _instrumentData; uint8 _masterVolume; bool _soundOn; uint8 _numChan; uint8 _ssgPatchOffset; uint8 _patchSize; uint8 _internalVersion; const uint8 _playID; const uint8 _channelMask1; uint8 _channelMask2; uint8 _polyphony; bool _isOpen; bool _ready; const uint16 _baseTempo; PC98AudioCore *_pc98a; const SciVersion _version; }; class MidiPlayer_PC9801 : public MidiPlayer { public: enum { MIDI_PROP_PLAYSWITCH = 1, MIDI_PROP_POLYPHONY = 2, MIDI_PROP_CHANNEL_ID = 3 }; MidiPlayer_PC9801(SciVersion version); ~MidiPlayer_PC9801(); bool hasRhythmChannel() const; byte getPlayId() const; int getPolyphony() const; void playSwitch(bool play); void initTrack(SciSpan &trackData); }; SoundChannel_PC9801::SoundChannel_PC9801(PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, int type, SciSpan instrumentData, bool &soundOn) : _pc98a(pc98a), _parts(parts), _version(version), _type(type), _instrumentData(instrumentData), _soundOn(soundOn), _assign(0xff), _note(0xff), _velo(0), _volume(0), _transpose(0), _sustain(0), _duration(0), _program(0xff), _vbrInitialDelay(0), _vbrEnvelopeTimer(0), _vbrEnvelopeSpeed(0), _vbrDepthIncr(0), _vbrDecrTime(0), _vbrDepthDecr(0), _vbrIncrTime(0), _vbrSensitivity(0), _vbrFrequencyModifier(0), _vbrIncrStep(0), _vbrDecrStep(0), _vbrModulationTimer(0), _flags(0), _vbrCur(0x80), _frequencyBlock(0), _frequencyCourse(0), _frequencyNoteModifier(0) { static const uint16 courseV0[] = { 0x269, 0x28D, 0x2B5, 0x2DE, 0x30A, 0x339, 0x368, 0x39D, 0x3D4, 0x40E, 0x44A, 0x48C }; static const uint16 courseV1[] = { 0x26A, 0x28E, 0x2B5, 0x2DF, 0x30A, 0x339, 0x36A, 0x39E, 0x3D5, 0x40F, 0x44D, 0x48F }; static const uint16 fine[] = { 0x24, 0x27, 0x2A, 0x2B, 0x2F, 0x31, 0x34, 0x37, 0x3A, 0x3E, 0x42, 0x45 }; _noteFrequency = (version > SCI_VERSION_0_LATE) ? courseV1 : courseV0; _noteFrequencyModifier = fine; } SoundChannel_PC9801::~SoundChannel_PC9801() { _instrumentData.clear(); } void SoundChannel_PC9801::noteOff() { if (_sustain) return; processNoteEvent(_note, false); _note = 0xFF; _duration = 0; } void SoundChannel_PC9801::noteOn(uint8 note, uint8 velo) { _duration = 0; if (_program != _parts[_assign]->getCurrentProgram() && _soundOn) { _program = _parts[_assign]->getCurrentProgram(); programChange(_program); } if (_version > SCI_VERSION_0_LATE) { velo >>= 1; if (velo > 63) velo = 63; _velo = velo; } processNoteEvent(note, true); } void SoundChannel_PC9801::processNoteEvent(uint8 note, bool noteOn) { if (_note != note) { _note = note; _vbrEnvelopeTimer = _vbrInitialDelay; _vbrFrequencyModifier = 0; _vbrCur = 0x80; _flags |= kChanVbrRestartEnv; } if (!prepareFrequencyAndVolume(noteOn)) noteOn = false; sendSoundOnOff(noteOn); } void SoundChannel_PC9801::update() { processSounds(); if (_note != 0xFF) _duration++; } void SoundChannel_PC9801::setVolume(uint8 volume) { static const uint8 volumeTable[] = { 0x7F, 0x7F, 0x30, 0x30, 0x28, 0x28, 0x20, 0x20, 0x18, 0x18, 0x10, 0x10, 0x08, 0x08, 0x00, 0x00 }; assert(volume < 16); _volume = volumeTable[volume]; } void SoundChannel_PC9801::reset() { _assign = 0xFF; _note = 0xFF; _volume = 0; } int SoundChannel_PC9801::recalculateFrequency(uint16 note, uint16 modifier, uint8 *destOctaveBlock, uint16 *destFrequency, uint8 *destVbrFrequencyModifier) { note += _transpose; uint16 pb = _parts[_assign]->getCurrentPitchBend(); if (pb == 0x2000) { pb = 0; } else { int dir = 1; if (pb > 0x2000) { pb -= 0x2000; } else if (pb < 0x2000) { pb = 0x2000 - pb; dir = -1; } uint8 noteDiff = pb / 684; note += (noteDiff * dir); pb %= 684; if (pb > 682) pb = 682; pb = ((pb * 6) >> 4); pb *= dir; } note += (modifier >> 8); pb += (modifier & 0xff); if ((pb >> 8) == 1) { pb &= 0xFF; note++; } if (_version == SCI_VERSION_0_LATE) note -= 12; if (note < 12 || note > 107) return -1; if (_version == SCI_VERSION_0_LATE && _type == 2) { uint16 rs = _noteFrequency[note - 12]; if (destFrequency) *destFrequency = rs; return rs; } uint8 block = (note / 12) - 1; note %= 12; uint16 res =_noteFrequency[note]; uint16 pitchVbrMultiplier = _noteFrequencyModifier[note]; if (_type != 2) res |= (block << 11); else if (block == 0) return -1; if (pb) res += (((pb * pitchVbrMultiplier) & 0x0FF0) >> 8); if (res < 0x4000) { if (destFrequency) *destFrequency = res; if (destOctaveBlock) *destOctaveBlock = block; if (destVbrFrequencyModifier) *destVbrFrequencyModifier = pitchVbrMultiplier; return res; } return -1; } uint8 SoundChannel_PC9801::getVolume() { static const uint8 volumeTable1[] = { 0x00, 0x0c, 0x0d, 0x0e, 0x0f, 0x11, 0x12, 0x13, 0x14, 0x16, 0x17, 0x18, 0x1a, 0x1b, 0x1c, 0x1d, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2d, 0x2d, 0x2e, 0x2f, 0x30, 0x31, 0x32, 0x32, 0x33, 0x34, 0x34, 0x35, 0x36, 0x36, 0x37, 0x38, 0x38, 0x39, 0x3a, 0x3b, 0x3b, 0x3b, 0x3c, 0x3c, 0x3c, 0x3d, 0x3d, 0x3d, 0x3e, 0x3e, 0x3e, 0x3e, 0x3f, 0x3f, 0x3f }; static const uint8 volumeTable2[] = { 0x00, 0x54, 0x55, 0x56, 0x57, 0x58, 0x59, 0x5a, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60, 0x61, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68, 0x69, 0x6a, 0x6b, 0x6c, 0x6d, 0x6e, 0x6f, 0x6f, 0x70, 0x71, 0x72, 0x72, 0x73, 0x74, 0x74, 0x75, 0x76, 0x76, 0x77, 0x78, 0x78, 0x79, 0x79, 0x7a, 0x7a, 0x7b, 0x7b, 0x7b, 0x7c, 0x7c, 0x7c, 0x7d, 0x7d, 0x7d, 0x7e, 0x7e, 0x7e, 0x7e, 0x7f, 0x7f, 0x7f }; uint16 partVolume = ((_assign != 0xFF) ? _parts[_assign]->getCurrentVolume() : 0); if (_version == SCI_VERSION_0_LATE) return partVolume; partVolume += 1; uint16 velocity = volumeTable1[_velo] + 1; uint16 volume = _soundOn ? (partVolume * velocity) >> 6 : 0; volume = volumeTable2[volume] - _volume; return (volume < 0x7F ? volume : 0); } void SoundChannel_PC9801::processSounds() { if (!(_flags & kChanVbrEnable)) return; if (_flags & kChanVbrRestartEnv) { if (--_vbrEnvelopeTimer) return; _vbrIncrStep = _vbrDepthIncr * _vbrSensitivity * _frequencyNoteModifier; _vbrDecrStep = _vbrDepthDecr * _vbrSensitivity * _frequencyNoteModifier; _vbrModulationTimer = ((_flags & kChanVbrMode) ? _vbrIncrTime : _vbrDecrTime) >> 1; _vbrCur = 0x80; _flags &= ~(kChanVbrDecrease | kChanVbrRestartEnv); if (_flags & kChanVbrMode) _flags |= kChanVbrDecrease; } uint16 t = _vbrEnvelopeTimer + _vbrEnvelopeSpeed; _vbrEnvelopeTimer = t & 0xFF; if (t & 0x100) return; if (!--_vbrModulationTimer) { _vbrModulationTimer = (_flags & kChanVbrDecrease) ? _vbrDecrTime : _vbrIncrTime; _flags ^= kChanVbrDecrease; } if (_flags & kChanVbrDecrease) { uint8 sL = _vbrDecrStep & 0xFF; uint8 sH = _vbrDecrStep >> 8; bool ovrflow = (sL > _vbrCur); _vbrCur -= sL; if (!ovrflow) return; _vbrFrequencyModifier -= (sH + 1); } else { uint8 sL = _vbrDecrStep & 0xFF; uint8 sH = _vbrDecrStep >> 8; bool ovrflow = (sL + _vbrCur > 255); _vbrCur += sL; if (!ovrflow) return; _vbrFrequencyModifier += (sH + 1); } sendFrequency(); } void SoundChannel_PC9801::programChangeInit(SciSpan &data) { _transpose = (int8)(data[0] & 0xC0 && data[0] < 0xC0 ? data[0] ^ 0x80 : data[0]); _vbrInitialDelay = data[1]; _vbrDepthIncr = data[2]; _vbrDecrTime = data[3]; _vbrDepthDecr = data[4]; _vbrIncrTime = data[5]; _vbrSensitivity = (data[6] & 3) + 1; _vbrEnvelopeSpeed = data[6] >> 3; _flags = (_flags & ~(kChanVbrEnable | kChanVbrMode)) | ((data[6] << 4) & 0x40); if (_vbrInitialDelay) _flags |= (kChanVbrEnable | kChanVbrRestartEnv); } void SoundChannel_PC9801::writeReg(uint8 part, uint8 reg, uint8 val) { _pc98a->writeReg(part, reg, val); } bool SoundChannel_PC9801::prepareFrequencyAndVolume(bool updateVolume) { if (recalculateFrequency(_note, 0, &_frequencyBlock, &_frequencyCourse, &_frequencyNoteModifier) == -1) return false; sendFrequency(); if (updateVolume) sendVolume(); return true; } SoundChannel_PC9801_FM4OP::SoundChannel_PC9801_FM4OP(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchSize, bool &soundOn) : SoundChannel_PC9801(pc98a, parts, version, 0, instrumentData, soundOn), _carrier(0), _regPrt(id > 2 ? 1 : 0), _regOffs(id % 3), _operatorFlags((id > 2 ? 4 : 0) | (id % 3) | 0xF0), _patchSize(patchSize) { _operatorLevel[0] = _operatorLevel[1] = _operatorLevel[2] = _operatorLevel[3] = 0x7F; } void SoundChannel_PC9801_FM4OP::programChange(uint8 program) { static const uint8 carrier[] = { 0x10, 0x10, 0x10, 0x10, 0x30, 0x70, 0x70, 0xF0 }; static const uint8 steps[] = { 0, 16, 8, 24 }; SciSpan data = _instrumentData.subspan(program * _patchSize); if (_version == SCI_VERSION_1_LATE) { programChangeInit(data); uint8 pos = 8; for (uint8 i = 0x40 + _regOffs; i < 0x50 + _regOffs; i += 4) writeReg(_regPrt, i, 0xFF); for (uint8 i = 0x30 + _regOffs; i < 0x40 + _regOffs; i += 4) writeReg(_regPrt, i, data[pos++]); for (int i = 0; i < 4; ++i) _operatorLevel[i] = data[pos++]; for (uint8 i = 0x50 + _regOffs; i < 0xA0 + _regOffs; i += 4) writeReg(_regPrt, i, data[pos++]); writeReg(_regPrt, 0xB0 + _regOffs, data[pos]); _carrier = carrier[data[pos] & 7]; } else { uint8 pos = 11; uint8 opFlags = data[pos]; uint8 fba = data[pos + 1] & 0x3F; _carrier = carrier[fba & 7]; pos += 8; uint8 reg = 0x30 + _regOffs; for (int i = 0; i < 4; ++i) writeReg(_regPrt, reg + (i << 2), data[pos + steps[i & 3]] & 0x7F); pos -= 3; _operatorLevel[0] = (opFlags & 0x08) ? data[pos + steps[0]] : 0x7F; _operatorLevel[1] = (opFlags & 0x20) ? data[pos + steps[1]] : 0x7F; _operatorLevel[2] = (opFlags & 0x10) ? data[pos + steps[2]] : 0x7F; _operatorLevel[3] = (opFlags & 0x40) ? data[pos + steps[3]] : 0x7F; pos += 4; reg = 0x50 + _regOffs; for (int i = 0; i < 16; ++i) writeReg(_regPrt, reg + (i << 2), data[pos + steps[i & 3] + (i >> 2)]); if (fba >= 24) fba -= 24; else fba &= 7; writeReg(_regPrt, 0xB0 + _regOffs, fba); _operatorFlags = (_operatorFlags & 7) | (opFlags << 1); } } void SoundChannel_PC9801_FM4OP::sendSoundOnOff(bool noteOn) { _flags = noteOn ? (_flags | kChanKeyOn) : (_flags & ~kChanKeyOn); writeReg(0, 0x28, noteOn ? _operatorFlags : _operatorFlags & 7); } void SoundChannel_PC9801_FM4OP::sendVolume() { uint8 vol = getVolume(); uint16 c = _carrier; for (uint8 i = 0; i < 4; ++i) { uint8 r = _operatorLevel[i]; c += c; if (c & 0x100) { c &= 0xFF; if (_version == SCI_VERSION_1_LATE) { r = (((r ^ 0x7F) * vol) / 0x7F) * 2; r = ((r < 0x7F) ? 0x7F - r : 0) + 20; if (r > 0x7F) r = 0x7F; } else { r = 127 - ((127 - r) * vol / 128); } } writeReg(_regPrt, 0x40 + (i << 2) + _regOffs, r); } } void SoundChannel_PC9801_FM4OP::sendFrequency() { uint16 freq = _frequencyCourse + _vbrFrequencyModifier; writeReg(_regPrt, 0xA4 + _regOffs, freq >> 8); writeReg(_regPrt, 0xA0 + _regOffs, freq & 0xFF); } uint8 SoundChannel_PC9801_FM2OP::_activeOperators = 0; SoundChannel_PC9801_FM2OP::SoundChannel_PC9801_FM2OP(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchSize, bool &soundOn) : SoundChannel_PC9801(pc98a, parts, version, 1, instrumentData, soundOn), _patchOffset(37), _patchSize(patchSize), _frequencyCourse2(0), _frequencyNoteModifier2(0), _vbrFrequencyModifier2(0), _vbrCur2(0x80), _vbrIncrStep2(0), _vbrDecrStep2(0), _regPrt(id > 3 ? 1 : 0), _regOffs(id & 1) { static const uint16 opFreqOffset[] = { 0x0000, 0x0600, 0x07CF, 0x0980 }; _operatorLevel[0] = _operatorLevel[1] = 0x7F; _operatorFrqIndex[0] = _operatorFrqIndex[1] = 0; _opFreqOffset = opFreqOffset; } void SoundChannel_PC9801_FM2OP::processNoteEvent(uint8 note, bool noteOn) { if (_note != note) { _vbrCur2 = 0x80; _vbrFrequencyModifier2 = 0; } SoundChannel_PC9801::processNoteEvent(note, noteOn); } void SoundChannel_PC9801_FM2OP::reset() { SoundChannel_PC9801::reset(); _activeOperators = 0; } void SoundChannel_PC9801_FM2OP::programChange(uint8 program) { SciSpan data = _instrumentData.subspan(program * _patchSize + _patchOffset); programChangeInit(data); uint8 pos = 7; for (uint8 i = 0x42 + (_regOffs << 2); i < 0x52 + (_regOffs << 2); i += 8) writeReg(_regPrt, i, 0xFF); for (uint8 i = 0x32 + (_regOffs << 2); i < 0x42 + (_regOffs << 2); i += 8) writeReg(_regPrt, i, data[pos++]); for (int i = 0; i < 2; ++i) _operatorLevel[i] = data[pos++]; for (uint8 i = 0x52 + (_regOffs << 2); i < 0x72 + (_regOffs << 2); i += 8) writeReg(_regPrt, i, data[pos++]); _operatorFrqIndex[0] = data[pos] >> 6; _operatorFrqIndex[1] = data[pos + 1] >> 6; for (uint8 i = 0x72 + (_regOffs << 2); i < 0xA2 + (_regOffs << 2); i += 8) writeReg(_regPrt, i, data[pos++]); } bool SoundChannel_PC9801_FM2OP::prepareFrequencyAndVolume(bool updateVolume) { if (recalculateFrequency(_note, _opFreqOffset[_operatorFrqIndex[0]], 0, &_frequencyCourse, &_frequencyNoteModifier) == -1) return false; if (recalculateFrequency(_note, _opFreqOffset[_operatorFrqIndex[1]], 0, &_frequencyCourse2, &_frequencyNoteModifier2) == -1) return false; sendFrequency(); if (updateVolume) sendVolume(); return true; } void SoundChannel_PC9801_FM2OP::sendSoundOnOff(bool noteOn) { uint8 op = 0x30 << (_regOffs << 1); if (noteOn) { _flags |= kChanKeyOn; _activeOperators |= op; } else { _flags &= ~kChanKeyOn; _activeOperators &= ~op; } writeReg(0, 0x28, _activeOperators | (_regPrt << 2) | 2); } void SoundChannel_PC9801_FM2OP::sendVolume() { writeReg(_regPrt, 0x42 + (_regOffs << 2), _operatorLevel[0]); uint8 r = (((_operatorLevel[1] ^ 0x7F) * getVolume()) / 0x7F) * 2; r = ((r < 0x7F) ? 0x7F - r : 0) + 16; writeReg(_regPrt, 0x4A + (_regOffs << 2), r); } void SoundChannel_PC9801_FM2OP::processSounds() { if (!(_flags & kChanVbrEnable)) return; if (_flags & kChanVbrRestartEnv) { if (--_vbrEnvelopeTimer) return; _vbrIncrStep = _vbrDepthIncr * _vbrSensitivity * _frequencyNoteModifier; _vbrIncrStep2 = _vbrDepthIncr * _vbrSensitivity * _frequencyNoteModifier2; _vbrDecrStep = _vbrDepthDecr * _vbrSensitivity * _frequencyNoteModifier; _vbrDecrStep2 = _vbrDepthDecr * _vbrSensitivity * _frequencyNoteModifier2; _vbrModulationTimer = ((_flags & kChanVbrMode) ? _vbrIncrTime : _vbrDecrTime) >> 1; _vbrCur = 0x80; _flags &= ~(kChanVbrDecrease | kChanVbrRestartEnv); if (_flags & kChanVbrMode) _flags |= kChanVbrDecrease; } uint16 t = _vbrEnvelopeTimer + _vbrEnvelopeSpeed; _vbrEnvelopeTimer = t & 0xFF; if (t & 0x100) return; if (!--_vbrModulationTimer) { _vbrModulationTimer = (_flags & kChanVbrDecrease) ? _vbrDecrTime : _vbrIncrTime; _flags ^= kChanVbrDecrease; } if (_flags & kChanVbrDecrease) { uint8 sL = _vbrDecrStep & 0xFF; uint8 sH = _vbrDecrStep >> 8; bool ovrflow = (sL > _vbrCur); _vbrCur -= sL; if (ovrflow) _vbrFrequencyModifier -= (sH + 1); sL = _vbrDecrStep2 & 0xFF; sH = _vbrDecrStep2 >> 8; ovrflow = (sL > _vbrCur2); _vbrCur2 -= sL; if (ovrflow) _vbrFrequencyModifier2 -= (sH + 1); } else { uint8 sL = _vbrDecrStep & 0xFF; uint8 sH = _vbrDecrStep >> 8; bool ovrflow = (sL + _vbrCur > 255); _vbrCur += sL; if (ovrflow) _vbrFrequencyModifier += (sH + 1); sL = _vbrDecrStep2 & 0xFF; sH = _vbrDecrStep2 >> 8; ovrflow = (sL + _vbrCur2 > 255); _vbrCur2 += sL; if (ovrflow) _vbrFrequencyModifier2 += (sH + 1); } sendFrequency(); } void SoundChannel_PC9801_FM2OP::sendFrequency() { uint16 freq = _frequencyCourse + _vbrFrequencyModifier; writeReg(_regPrt, 0xAD - _regOffs, freq >> 8); writeReg(_regPrt, 0xA9 - _regOffs, freq & 0xFF); freq = _frequencyCourse2 + _vbrFrequencyModifier2; writeReg(_regPrt, 0xAE - (_regOffs << 3), freq >> 8); writeReg(_regPrt, 0xAA - (_regOffs << 3), freq & 0xFF); } uint8 SoundChannel_PC9801_SSG::_activeChannnelsStatus = 0x3F; SoundChannel_PC9801_SSG::SoundChannel_PC9801_SSG(uint8 id, PC98AudioCore *pc98a, MidiPart_PC9801 **parts, SciVersion version, SciSpan instrumentData, uint8 patchOffset, uint8 patchSize, bool &soundOn) : SoundChannel_PC9801(pc98a, parts, version, 2, instrumentData, soundOn), _patchOffset(patchOffset), _patchSize(patchSize), _regOffs(id & 3), _instrumentChanMask(0x3F), _ngPhaseStep(0), _currentLevel(0), _ssgEnvelopeState(kEnvSSG_silent), _ngEnvelopeTimer(0), _ngSpeed(0), _ngPhase(0), _ssgEnvelopeTimer(0), _ssgLevel(0), _ssgSpeed(0), _ccngEnabled(false) { static const uint16 courseV0[] = { 0xfcf, 0xef1, 0xe16, 0xd59, 0xc87, 0xbcd, 0xb27, 0xa93, 0x9ee, 0x96a, 0x8da, 0x865, 0x778, 0x70d, 0x6a6, 0x643, 0x5ec, 0x599, 0x545, 0x4f7, 0x4b5, 0x46d, 0x432, 0x3f4, 0x3c5, 0x386, 0x353, 0x325, 0x2f6, 0x2cc, 0x2a3, 0x27d, 0x25a, 0x238, 0x218, 0x1fa, 0x1dd, 0x1c3, 0x1a9, 0x192, 0x17b, 0x166, 0x152, 0x13f, 0x12d, 0x11c, 0x10c, 0x0fd, 0x0ef, 0x0e1, 0x0d5, 0x0c9, 0x0bd, 0x0b3, 0x0a9, 0x09f, 0x096, 0x08e, 0x086, 0x07e, 0x077, 0x071, 0x06a, 0x064, 0x05f, 0x059, 0x054, 0x050, 0x04b, 0x047, 0x043, 0x03f, 0x03c, 0x038, 0x035, 0x032, 0x02f, 0x02d, 0x02a, 0x028, 0x026, 0x023, 0x021, 0x020, 0x01e, 0x01c, 0x01b, 0x019, 0x018, 0x016, 0x015, 0x014, 0x013, 0x012, 0x011, 0x010 }; static const uint16 courseV1[] = { 0x82D, 0x8A9, 0x92D, 0x9B6, 0xA4D, 0xAEA, 0xB90, 0xC40, 0xCFA, 0xDC0, 0xE90, 0xF6F }; static const uint16 fine[] = { 0x7C, 0x84, 0x8B, 0x94, 0x9D, 0xA6, 0xB0, 0xBA, 0xC5, 0xD0, 0xDE, 0xEB }; static const uint8 noiseFrq[] = { 0x00, 0x01, 0x04, 0x07, 0x0A, 0x0D, 0x10, 0x13, 0x16, 0x19, 0x1C, 0x1F }; static const uint8 disableMask[] = { 0xF6, 0xED, 0xDB }; static const uint8 enableMask1[] = { 0xBE, 0xBD, 0xBB }; static const uint8 enableMask2[] = { 0xB7, 0xAF, 0x9F }; _noteFrequency = (version > SCI_VERSION_0_LATE) ? courseV1 : courseV0; _noteFrequencyModifier = fine; _ngFreq = noiseFrq; _chanDisableMask = disableMask[id & 3]; _chanEnableMask1 = enableMask1[id & 3]; _chanEnableMask2 = enableMask2[id & 3]; } void SoundChannel_PC9801_SSG::reset() { SoundChannel_PC9801::reset(); _activeChannnelsStatus = (_version == SCI_VERSION_1_LATE) ? 0x3F : 0xFF; sendActiveChannelsStatus(); } void SoundChannel_PC9801_SSG::toggleNoiseGenerator(bool enable) { _ccngEnabled = enable; } void SoundChannel_PC9801_SSG::programChange(uint8 program) { _selectedInstrument = _instrumentData.subspan(program * _patchSize + _patchOffset); if (_version == SCI_VERSION_1_LATE) { programChangeInit(_selectedInstrument); _flags &= ~kChanNgEnable; if (_selectedInstrument[7]) _flags |= (kChanNgEnable | kChanNgRestartEnv); _instrumentChanMask = _selectedInstrument[22]; _activeChannnelsStatus = (_activeChannnelsStatus & _chanDisableMask) | (~_chanDisableMask & (_instrumentChanMask & 0x3F)); if (!(_instrumentChanMask & 8)) { _ngPhaseStep = _selectedInstrument[21] & 0x1F; updateNg(); } sendActiveChannelsStatus(); } else { writeReg(0, 13, _selectedInstrument[0]); writeReg(0, 6, _selectedInstrument[1]); writeReg(0, 11, _selectedInstrument[2]); writeReg(0, 12, _selectedInstrument[3]); } _currentLevel = 0; _ssgEnvelopeState = kEnvSSG_silent; } void SoundChannel_PC9801_SSG::processSounds() { if (_ssgEnvelopeState == kEnvSSG_silent) return; SoundChannel_PC9801::processSounds(); if (!(_instrumentChanMask & 0x38) && (_flags & kChanNgEnable)) { bool cont = false; if (_flags & kChanNgRestartEnv) { if (--_ngEnvelopeTimer) { cont = true; } else { uint8 flg = _selectedInstrument[10] & 4; _ngSpeed = ((flg ? _selectedInstrument[9] : _selectedInstrument[8]) & 0x1F) >> 1; _flags = (_flags & ~(kChanNgDecrease | kChanNgRestartEnv)) | (flg << 3); } } if (!cont) { uint16 s = _ngEnvelopeTimer + (_selectedInstrument[10] >> 3); _ngEnvelopeTimer = s & 0xFF; if (s & 0x100) cont = true; if (!cont) { if (--_ngSpeed) { if (_flags & kChanNgDecrease) { _ngSpeed = _selectedInstrument[8] & 0x1F; _flags &= ~kChanNgDecrease; } else { _ngSpeed = _selectedInstrument[9] & 0x1F; _flags |= kChanNgDecrease; } } if (_flags & kChanNgDecrease) { _ngPhase -= (_selectedInstrument[9] >> 5) * ((_selectedInstrument[10] & 3) + 1); } else { _ngPhase += (_selectedInstrument[8] >> 5) * ((_selectedInstrument[10] & 3) + 1); } updateNg(); } } } uint16 s = _ssgEnvelopeTimer + (_selectedInstrument[21] & 0x60); _ssgEnvelopeTimer = s & 0xFF; if ((s & 0x100) || !(_ssgEnvelopeState & 0x0F)) return; uint8 vol = _currentLevel; if (_ssgLevel & 1) vol = (vol > (_ssgLevel & ~1)) ? vol - (_ssgLevel & ~1) : 0; else vol = (vol + _ssgLevel > 255) ? 255 : vol + _ssgLevel; if (!--_ssgSpeed) { if (--_ssgEnvelopeState == (kEnvSSG_keyOn | kEnvSSG_sustain)) { _ssgLevel = _selectedInstrument[13]; _ssgSpeed = _selectedInstrument[14]; vol = (uint8)CLIP(vol + (int8)(_selectedInstrument[19] & 0xF0), 0, 255); } if (_ssgEnvelopeState == (kEnvSSG_keyOn | kEnvSSG_decay)) { _ssgLevel = _selectedInstrument[15]; _ssgSpeed = _selectedInstrument[16]; vol = (uint8)CLIP(vol + (int8)((_selectedInstrument[20] & 0x0F) << 4), 0, 255); } } if (_ssgEnvelopeState == kEnvSSG_silent) vol = 0; if (_currentLevel != vol) { _currentLevel = vol; sendVolume(); } } void SoundChannel_PC9801_SSG::sendSoundOnOff(bool noteOn) { if (_version == SCI_VERSION_1_LATE && noteOn && !(_ssgEnvelopeState & kEnvSSG_keyOn)) { _currentLevel = _selectedInstrument[19] << 4; _ssgEnvelopeState = (kEnvSSG_keyOn | kEnvSSG_attack); _ssgLevel = _selectedInstrument[11]; _ssgSpeed = _selectedInstrument[12]; _ssgEnvelopeTimer = 1; if (!(_selectedInstrument[22] & 0x38)) { if (_selectedInstrument[21] & 0x80) _ngPhaseStep = _ngFreq[_note % 12]; _ngEnvelopeTimer = _selectedInstrument[7]; _ngPhase = 0; updateNg(); _flags |= kChanNgRestartEnv; } } else if (_version == SCI_VERSION_1_LATE && !noteOn) { int16 l = _currentLevel + (int8)(_selectedInstrument[20] & 0xF0); _currentLevel = (uint8)CLIP(l, 0, 255); _ssgEnvelopeState = kEnvSSG_decay; _ssgLevel = _selectedInstrument[17]; _ssgSpeed = _selectedInstrument[18]; _note = 0xFF; } else if (_version == SCI_VERSION_0_LATE && noteOn) { _activeChannnelsStatus &= _chanEnableMask1; if (_ccngEnabled) _activeChannnelsStatus &= _chanEnableMask2; _currentLevel = 1; sendActiveChannelsStatus(); writeReg(0, 13, _selectedInstrument[0]); } else if (_version == SCI_VERSION_0_LATE) { _activeChannnelsStatus |= ~_chanEnableMask1; if (_ccngEnabled) _activeChannnelsStatus |= ~_chanEnableMask2; _currentLevel = 0; _note = 0xFF; sendActiveChannelsStatus(); } sendVolume(); } void SoundChannel_PC9801_SSG::sendVolume() { uint8 v1 = getVolume(); uint16 r = 0; if (_version == SCI_VERSION_1_LATE) { uint8 vol = v1 + (((v1 >> 1) + v1) >> 2); if (vol > 0x7F) vol = 0x7F; vol = (vol >> 3) & 0x0F; r = _currentLevel & 0xF0; for (uint8 i = 0; i < 4; ++i) { r += r; if (r & 0x100) r = (r + vol) & 0xFF; } r = (r + 15) >> 4; } else { r = _currentLevel * (0x10 | v1 >> 3); } writeReg(0, 8 + _regOffs, r); } void SoundChannel_PC9801_SSG::sendFrequency() { uint16 freq = _frequencyCourse; if (_version > SCI_VERSION_0_LATE) { freq = (uint16)(freq + _vbrFrequencyModifier) >> (8 - _frequencyBlock); if (!freq) return; freq = 62400 / freq; } writeReg(0, _regOffs << 1, freq & 0xFF); writeReg(0, (_regOffs << 1) + 1, freq >> 8); } void SoundChannel_PC9801_SSG::updateNg() { int p = _ngPhase + _ngPhaseStep; if (p > 255) p = 0; if (p > 31) p = 31; _ngPhase = p & 0xFF; writeReg(0, 6, _ngPhase); } void SoundChannel_PC9801_SSG::sendActiveChannelsStatus() { writeReg(0, 7, (_activeChannnelsStatus & 0x3F) | 0x80); } MidiPart_PC9801::MidiPart_PC9801(uint8 id, SoundChannel_PC9801 **channels, uint8 numChan, SciVersion version) : _chan(channels), _id(id), _version(version), _numChan(numChan), _program(0), _volume(0x3f), _sustain(0), _chanMissing(0), _pitchBend(0x2000), _outChan(0), _noteRangeLow(version > SCI_VERSION_0_LATE ? 12 : 24), _noteRangeHigh(version > SCI_VERSION_0_LATE ? 107 : 119) { } void MidiPart_PC9801::noteOff(uint8 note) { for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign != _id || _chan[i]->_note != note) continue; if (_sustain && _version > SCI_VERSION_0_LATE) _chan[i]->_sustain = 1; else _chan[i]->noteOff(); return; } } void MidiPart_PC9801::noteOn(uint8 note, uint8 velo) { if (note < _noteRangeLow || note > _noteRangeHigh) return; if (velo == 0) { noteOff(note); return; } velo >>= 1; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign != _id || _chan[i]->_note != note) continue; _chan[i]->_sustain = 0; _chan[i]->noteOff(); _chan[i]->noteOn(note, velo); return; } int chan = allocateChannel(); if (chan != -1) _chan[chan]->noteOn(note, velo); } void MidiPart_PC9801::controlChangeVolume(uint8 vol) { _volume = (_version < SCI_VERSION_1_LATE) ? vol : CLIP(vol >> 1, 0, 0x3f); for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id && _chan[i]->_note != 0xff) _chan[i]->processNoteEvent(_chan[i]->_note, true); } } void MidiPart_PC9801::controlChangeSustain(uint8 sus) { if (_version < SCI_VERSION_1_LATE) return; _sustain = sus; if (_sustain) return; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id && _chan[i]->_sustain) { _chan[i]->_sustain = 0; _chan[i]->noteOff(); } } } void MidiPart_PC9801::controlChangePolyphony(uint8 numChan) { if (_version < SCI_VERSION_1_LATE) return; uint8 numAssigned = 0; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id) numAssigned++; } numAssigned += _chanMissing; if (numAssigned < numChan) { addChannels(numChan - numAssigned); } else if (numAssigned > numChan) { dropChannels(numAssigned - numChan); assignFreeChannels(); } } void MidiPart_PC9801::controlChangeNoiseGenerator(uint8 enable) { if (_version > SCI_VERSION_0_LATE) return; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id) _chan[i]->toggleNoiseGenerator(enable); } } void MidiPart_PC9801::controlChangeAllNotesOff() { for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id && _chan[i]->_note != 0xff) _chan[i]->noteOff(); } } void MidiPart_PC9801::programChange(uint8 prg) { _program = prg; } void MidiPart_PC9801::pitchBend(int16 val) { if (_version < SCI_VERSION_1_LATE) return; _pitchBend = val; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign == _id && _chan[i]->_note != 0xff) _chan[i]->processNoteEvent(_chan[i]->_note, true); } } void MidiPart_PC9801::addChannels(int num, int resetMissingChannels, int channelType) { if (resetMissingChannels != -1) _chanMissing = resetMissingChannels; for (int i = 0; i < _numChan; ++i) { if (_chan[i]->_assign != 0xFF || (channelType != -1 && _chan[i]->getType() != channelType)) continue; _chan[i]->_assign = _id; #ifdef DEBUG_REMAP debug("===== MidiDriver_PC9801: hardware channel %d is assigned to device channel %d =====", i, _id); #endif if (_chan[i]->_note != 0xff) _chan[i]->noteOff(); if (!--num) break; } _chanMissing += num; } void MidiPart_PC9801::dropChannels(int num) { if (_chanMissing == num) { _chanMissing = 0; return; } else if (_chanMissing > num) { _chanMissing -= num; return; } num -= _chanMissing; _chanMissing = 0; for (int i = 0; i < _numChan; i++) { if (_chan[i]->_assign != _id || _chan[i]->_note != 0xff) continue; _chan[i]->_assign = 0xff; #ifdef DEBUG_REMAP debug("===== MidiDriver_PC9801: hardware channel %d is dropped from device channel %d =====", i, _id); #endif if (!--num) return; } for (int i = 0; i < _numChan; i++) { if (_chan[i]->_assign != _id) continue; _chan[i]->_sustain = 0; _chan[i]->noteOff(); _chan[i]->_assign = 0xff; if (!--num) return; } } int MidiPart_PC9801::allocateChannel() { int chan = _outChan; int ovrChan = 0; int ld = 0; bool found = false; for (bool loop = true; loop; ) { if (++chan == _numChan) chan = 0; if (chan == _outChan) loop = false; if (_id == _chan[chan]->_assign) { if (_chan[chan]->_note == 0xff || _version < SCI_VERSION_1_LATE) { found = true; break; } if (_chan[chan]->_duration >= ld) { ld = _chan[chan]->_duration; ovrChan = chan; } } } if (!found) { if (!ld) return -1; chan = ovrChan; _chan[chan]->_sustain = 0; _chan[chan]->noteOff(); } _outChan = chan; return chan; } void MidiPart_PC9801::assignFreeChannels() { uint8 freeChan = 0; for (int i = 0; i < _numChan; i++) { if (_chan[i]->_assign == 0xff) freeChan++; } if (!freeChan) return; MidiDriver_PC9801::assignFreeChannels(freeChan); } MidiPart_PC9801 **MidiDriver_PC9801::_parts = 0; MidiDriver_PC9801::MidiDriver_PC9801(Audio::Mixer *mixer, SciVersion version) : _version(version), _pc98a(0), _chan(0), _numChan(6), _internalVersion(0xFF), _ssgPatchOffset(0xFF), _patchSize(0), _timerProc(0), _timerProcPara(0), _baseTempo(10080), _ready(false), _isOpen(false), _masterVolume(0x0f) ,_soundOn(true), _playID(0), _polyphony(9), _channelMask1(0x10), _channelMask2(0x02) { _pc98a = #ifdef SCI_PC98_AUDIO_EXTENDED new PC98AudioCore(mixer, this, kType86, true); #else new PC98AudioCore(mixer, this, kType26, true); #endif } MidiDriver_PC9801::~MidiDriver_PC9801() { _ready = false; close(); delete _pc98a; } int MidiDriver_PC9801::open() { if (_isOpen) return MERR_ALREADY_OPEN; if (!_ready) { if (!_pc98a->init()) return MERR_CANNOT_CONNECT; _pc98a->setSoundEffectChanMask(0); _pc98a->ssgSetVolume(205); _ready = true; } ResourceManager *resMan = g_sci->getResMan(); if (!loadInstruments(*resMan->findResource(ResourceId(kResourceTypePatch, _version < SCI_VERSION_1_LATE ? 2 : 8), false))) return MERR_CANNOT_CONNECT; if (_version == SCI_VERSION_0_LATE && _channelMask2 == 0x00) { _internalVersion = 0; _polyphony = 3; } else if (_version == SCI_VERSION_0_LATE && _channelMask2 == 0x02) { _internalVersion = 1; _polyphony = 6; } else if (_patchSize == 60 && _ssgPatchOffset == 37) _internalVersion = 2; else if (_patchSize == 81 && _ssgPatchOffset == 58) _internalVersion = 3; else return MERR_CANNOT_CONNECT; if (_internalVersion == 3) _numChan++; int config = _internalVersion; #ifdef SCI_PC98_AUDIO_EXTENDED _numChan = 9; config = 4; #endif static const int channelConfig[6][11] = { { 0, 0, 0, 2, 2, 2, -1, -1, -1, -1, -1 }, { 0, 0, 0, 2, 2, 2, -1, -1, -1, -1, -1 }, { 0, 0, 0, 2, 2, 2, -1, -1, -1, -1, -1 }, { 0, 0, 1, 1, 2, 2, 2, -1, -1, -1, -1 }, { 0, 0, 0, 0, 0, 0, 2, 2, 2, -1, -1 } }; _parts = new MidiPart_PC9801*[16]; _chan = new SoundChannel_PC9801*[_numChan]; int numSSG = 0; for (int i = 0; i < _numChan; ++i) { if (channelConfig[config][i] == 0) _chan[i] = new SoundChannel_PC9801_FM4OP(i, _pc98a, _parts, _version, *_instrumentData, _patchSize, _soundOn); else if (channelConfig[config][i] == 1) _chan[i] = new SoundChannel_PC9801_FM2OP(i, _pc98a, _parts, _version, *_instrumentData, _patchSize, _soundOn); else if (channelConfig[config][i] == 2) _chan[i] = new SoundChannel_PC9801_SSG(numSSG++, _pc98a, _parts, _version, *_instrumentData, _ssgPatchOffset, _patchSize, _soundOn); else _chan[i] = 0; } for (int i = 0; i < 16; ++i) _parts[i] = new MidiPart_PC9801(i, _chan, _numChan, _version); _isOpen = true; reset(); return 0; } void MidiDriver_PC9801::close() { if (!_isOpen) return; bool ready = _ready; _isOpen = _ready = false; PC98AudioCore::MutexLock lock = _pc98a->stackLockMutex(); if (_parts) { for (int i = 0; i < 16; ++i) { delete _parts[i]; _parts[i] = 0; } delete[] _parts; _parts = 0; } if (_chan) { for (int i = 0; i < _numChan; ++i) { delete _chan[i]; _chan[i] = 0; } delete[] _chan; _chan = 0; } _instrumentData.clear(); _ready = ready; } void MidiDriver_PC9801::send(uint32 b) { if (!_isOpen) return; byte para2 = (b >> 16) & 0xFF; byte para1 = (b >> 8) & 0xFF; byte cmd = b & 0xF0; MidiPart_PC9801 *part = _parts[b & 0x0F]; switch (cmd) { case 0x80: part->noteOff(para1); break; case 0x90: part->noteOn(para1, para2); break; case 0xb0: switch (para1) { case 7: part->controlChangeVolume(para2); break; case 64: part->controlChangeSustain(para2); break; case SCI_MIDI_SET_POLYPHONY: part->controlChangePolyphony(para2); break; case 76: // This event (from the SCI0 driver) is parsing related and can't be handled here. Lets's see if this ever comes up. warning("MidiDriver_PC9801: Midi Control Change '0x%2x' not implemented", para1); break; case 81: part->controlChangeNoiseGenerator(para2); break; case 96: // This event (from the SCI0 driver) is parsing related. It is handled in MidiParser_SCI::processEvent(). break; case SCI_MIDI_CHANNEL_NOTES_OFF: part->controlChangeAllNotesOff(); break; default: break; } break; case 0xc0: part->programChange(para1); break; case 0xe0: part->pitchBend(para1 | (para2 << 7)); break; default: break; } } void MidiDriver_PC9801::assignFreeChannels(int num) { assert(_parts); for (int i = 0; i < 16; ++i) { uint8 missing = _parts[i]->getMissingChannels(); if (!missing) continue; if (missing < num) { num -= missing; _parts[i]->addChannels(num, 0); } else { _parts[i]->addChannels(num, missing - num); return; } } } uint32 MidiDriver_PC9801::property(int prop, uint32 param) { if (!_isOpen) return 0; switch(prop) { case MIDI_PROP_MASTER_VOLUME: if (param != 0xffff && param != _masterVolume && param < 16) { _masterVolume = param; for (int i = 0; i < _numChan; ++i) { _chan[i]->setVolume(_masterVolume); if (_chan[i]->_note != 0xFF) _chan[i]->processNoteEvent(_chan[i]->_note, true); } } return _masterVolume; case MIDI_PROP_PLAYSWITCH: _soundOn = param; break; case MIDI_PROP_POLYPHONY: return _polyphony; case MIDI_PROP_CHANNEL_ID: return _version < SCI_VERSION_1_LATE ? (_channelMask1 | _channelMask2) : _playID; default: break; } return 0; } void MidiDriver_PC9801::initTrack(SciSpan &header) { if (!_isOpen || _version > SCI_VERSION_0_LATE) return; for (int i = 0; i < _numChan; ++i) _chan[i]->reset(); uint8 readPos = 0; uint8 caps = header.getInt8At(readPos++); int numChan = (caps == 2) ? 15 : 16; if (caps != 0 && caps != 2) return; for (int i = 0; i < numChan; ++i) { _parts[i]->controlChangeVolume(103); uint8 num = (_internalVersion == 1) ? (header.getInt8At(readPos) & 0x7F) : 1; readPos++; uint8 flags = header.getInt8At(readPos); readPos++; if (flags & _channelMask1 && num) _parts[i]->addChannels(num, -1, 0); if (flags & _channelMask2 && num) _parts[i]->addChannels(num, -1, 2); if (_internalVersion == 0) _parts[i]->programChange(10); } } void MidiDriver_PC9801::setTimerCallback(void *timer_param, Common::TimerManager::TimerProc timer_proc) { _timerProc = timer_proc; _timerProcPara = timer_param; } uint32 MidiDriver_PC9801::getBaseTempo() { return _baseTempo; } void MidiDriver_PC9801::timerCallbackB() { if (!_isOpen) return; updateParser(); updateChannels(); } bool MidiDriver_PC9801::loadInstruments(const SciSpan &data) { if (!data) return false; SciSpan src = data; _instrumentData.clear(); if (_version == SCI_VERSION_0_LATE) { _ssgPatchOffset = 48; _patchSize = 52; _instrumentData->allocate(96 * _patchSize); SciSpan dst = *_instrumentData; for (bool load = true; load; ) { for (int i = 0; i < 48; ++i) { src.subspan(0, _patchSize).copyDataTo(dst); src += 64; dst += _patchSize; } uint16 id = (src.byteSize() >= 2) ? src.getInt16BEAt(0) : 0; if (id == 0xABCD || id == 0xCDAB) { src += 2; _channelMask2 = 0x00; } else { load = false; } } } else if (_version == SCI_VERSION_1_LATE) { _instrumentData->allocateFromSpan(++src); _patchSize = (data.byteSize() - 1) / 96; _ssgPatchOffset = (_patchSize == 81) ? 58 : 37; } return (_instrumentData->byteSize() && _patchSize && _ssgPatchOffset != 0xFF); } void MidiDriver_PC9801::updateParser() { if (_timerProc) _timerProc(_timerProcPara); } void MidiDriver_PC9801::updateChannels() { for (int i = 0; i < _numChan; ++i) _chan[i]->update(); } void MidiDriver_PC9801::reset() { if (!_ready) return; for (int i = 0; i < 3; ++i) { _pc98a->writeReg(0, 0x28, i); _pc98a->writeReg(0, i, 0); _pc98a->writeReg(0, 8 + i, 0); } uint8 flag = 0; #ifndef SCI_PC98_AUDIO_EXTENDED if (_internalVersion == 3) { _pc98a->writeReg(0, 0xB2, 0x04); flag = 0x40; } #endif _pc98a->writeReg(0, 0x27, 0x38); _pc98a->writeReg(0, 0x27, 0x3a | flag); if (!_isOpen) return; for (int i = 0; i < _numChan; ++i) _chan[i]->reset(); } MidiPlayer_PC9801::MidiPlayer_PC9801(SciVersion version) : MidiPlayer(version) { _driver = new MidiDriver_PC9801(g_system->getMixer(), version); } MidiPlayer_PC9801::~MidiPlayer_PC9801() { delete _driver; } bool MidiPlayer_PC9801::hasRhythmChannel() const { return false; } byte MidiPlayer_PC9801::getPlayId() const { return _driver ? _driver->property(MIDI_PROP_CHANNEL_ID, 0) : 0; } int MidiPlayer_PC9801::getPolyphony() const { return _driver ? _driver->property(MIDI_PROP_POLYPHONY, 0) : 0; } void MidiPlayer_PC9801::playSwitch(bool play) { if (_driver) _driver->property(MIDI_PROP_PLAYSWITCH, play ? 1 : 0); } void MidiPlayer_PC9801::initTrack(SciSpan &trackData) { if (_driver) static_cast(_driver)->initTrack(trackData); } MidiPlayer *MidiPlayer_PC9801_create(SciVersion _soundVersion) { return new MidiPlayer_PC9801(_soundVersion); } } // End of namespace Sci