/* 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 "common/endian.h" #include "common/system.h" #include "common/textconsole.h" #include "cruise/cruise.h" #include "cruise/cruise_main.h" #include "cruise/sound.h" #include "cruise/volume.h" #include "audio/fmopl.h" namespace Audio { class Mixer; } namespace Cruise { class PCSoundDriver { public: typedef void (*UpdateCallback)(void *); PCSoundDriver() : _upCb(nullptr), _upRef(nullptr), _musicVolume(0), _sfxVolume(0) {} virtual ~PCSoundDriver() {} virtual void setupChannel(int channel, const byte *data, int instrument, int volume) = 0; virtual void setChannelFrequency(int channel, int frequency) = 0; virtual void stopChannel(int channel) = 0; virtual void playSample(const byte *data, int size, int channel, int volume) = 0; virtual void stopAll() = 0; virtual const char *getInstrumentExtension() const { return ""; } virtual void syncSounds(); void setUpdateCallback(UpdateCallback upCb, void *ref); void resetChannel(int channel); void findNote(int freq, int *note, int *oct) const; protected: UpdateCallback _upCb; void *_upRef; uint8 _musicVolume; uint8 _sfxVolume; static const int _noteTable[]; static const int _noteTableCount; }; const int PCSoundDriver::_noteTable[] = { 0xEEE, 0xE17, 0xD4D, 0xC8C, 0xBD9, 0xB2F, 0xA8E, 0x9F7, 0x967, 0x8E0, 0x861, 0x7E8, 0x777, 0x70B, 0x6A6, 0x647, 0x5EC, 0x597, 0x547, 0x4FB, 0x4B3, 0x470, 0x430, 0x3F4, 0x3BB, 0x385, 0x353, 0x323, 0x2F6, 0x2CB, 0x2A3, 0x27D, 0x259, 0x238, 0x218, 0x1FA, 0x1DD, 0x1C2, 0x1A9, 0x191, 0x17B, 0x165, 0x151, 0x13E, 0x12C, 0x11C, 0x10C, 0x0FD, 0x0EE, 0x0E1, 0x0D4, 0x0C8, 0x0BD, 0x0B2, 0x0A8, 0x09F, 0x096, 0x08E, 0x086, 0x07E, 0x077, 0x070, 0x06A, 0x064, 0x05E, 0x059, 0x054, 0x04F, 0x04B, 0x047, 0x043, 0x03F, 0x03B, 0x038, 0x035, 0x032, 0x02F, 0x02C, 0x02A, 0x027, 0x025, 0x023, 0x021, 0x01F, 0x01D, 0x01C, 0x01A, 0x019, 0x017, 0x016, 0x015, 0x013, 0x012, 0x011, 0x010, 0x00F }; const int PCSoundDriver::_noteTableCount = ARRAYSIZE(_noteTable); struct AdLibRegisterSoundInstrument { uint8 vibrato; uint8 attackDecay; uint8 sustainRelease; uint8 feedbackStrength; uint8 keyScaling; uint8 outputLevel; uint8 freqMod; }; struct AdLibSoundInstrument { byte mode; byte channel; AdLibRegisterSoundInstrument regMod; AdLibRegisterSoundInstrument regCar; byte waveSelectMod; byte waveSelectCar; byte amDepth; }; struct VolumeEntry { int original; int adjusted; }; class AdLibSoundDriver : public PCSoundDriver { public: AdLibSoundDriver(Audio::Mixer *mixer); virtual ~AdLibSoundDriver(); // PCSoundDriver interface virtual void setupChannel(int channel, const byte *data, int instrument, int volume); virtual void stopChannel(int channel); virtual void stopAll(); void initCard(); void onTimer(); void setupInstrument(const byte *data, int channel); void setupInstrument(const AdLibSoundInstrument *ins, int channel); void loadRegisterInstrument(const byte *data, AdLibRegisterSoundInstrument *reg); virtual void loadInstrument(const byte *data, AdLibSoundInstrument *asi) = 0; virtual void syncSounds(); void adjustVolume(int channel, int volume); protected: OPL::OPL *_opl; Audio::Mixer *_mixer; byte _vibrato; VolumeEntry _channelsVolumeTable[5]; AdLibSoundInstrument _instrumentsTable[5]; static const int _freqTable[]; static const int _freqTableCount; static const int _operatorsTable[]; static const int _operatorsTableCount; static const int _voiceOperatorsTable[]; static const int _voiceOperatorsTableCount; }; const int AdLibSoundDriver::_freqTable[] = { 0x157, 0x16C, 0x181, 0x198, 0x1B1, 0x1CB, 0x1E6, 0x203, 0x222, 0x243, 0x266, 0x28A }; const int AdLibSoundDriver::_freqTableCount = ARRAYSIZE(_freqTable); const int AdLibSoundDriver::_operatorsTable[] = { 0, 1, 2, 3, 4, 5, 8, 9, 10, 11, 12, 13, 16, 17, 18, 19, 20, 21 }; const int AdLibSoundDriver::_operatorsTableCount = ARRAYSIZE(_operatorsTable); const int AdLibSoundDriver::_voiceOperatorsTable[] = { 0, 3, 1, 4, 2, 5, 6, 9, 7, 10, 8, 11, 12, 15, 16, 16, 14, 14, 17, 17, 13, 13 }; const int AdLibSoundDriver::_voiceOperatorsTableCount = ARRAYSIZE(_voiceOperatorsTable); class AdLibSoundDriverADL : public AdLibSoundDriver { public: AdLibSoundDriverADL(Audio::Mixer *mixer) : AdLibSoundDriver(mixer) {} virtual const char *getInstrumentExtension() const { return ".ADL"; } virtual void loadInstrument(const byte *data, AdLibSoundInstrument *asi); virtual void setChannelFrequency(int channel, int frequency); virtual void playSample(const byte *data, int size, int channel, int volume); }; class PCSoundFxPlayer { private: enum { NUM_INSTRUMENTS = 15, NUM_CHANNELS = 4 }; void update(); void handleEvents(); void handlePattern(int channel, const byte *patternData); char _musicName[33]; bool _playing; bool _songPlayed; int _currentPos; int _currentOrder; int _numOrders; int _eventsDelay; bool _looping; int _fadeOutCounter; int _updateTicksCounter; int _instrumentsChannelTable[NUM_CHANNELS]; byte *_sfxData; byte *_instrumentsData[NUM_INSTRUMENTS]; PCSoundDriver *_driver; public: PCSoundFxPlayer(PCSoundDriver *driver); ~PCSoundFxPlayer(); bool load(const char *song); void play(); void stop(); void unload(); void fadeOut(); void doSync(Common::Serializer &s); static void updateCallback(void *ref); bool songLoaded() const { return _sfxData != NULL; } bool songPlayed() const { return _songPlayed; } bool playing() const { return _playing; } uint8 numOrders() const { assert(_sfxData); return _sfxData[470]; } void setNumOrders(uint8 v) { assert(_sfxData); _sfxData[470] = v; } void setPattern(int offset, uint8 value) { assert(_sfxData); _sfxData[472 + offset] = value; } const char *musicName() { return _musicName; } // Note: Original game never actually uses looping variable. Songs are hardcoded to loop bool looping() const { return _looping; } void setLooping(bool v) { _looping = v; } }; byte *readBundleSoundFile(const char *name) { // Load the correct file int fileIdx = findFileInDisks(name); if (fileIdx < 0) return NULL; int unpackedSize = volumePtrToFileDescriptor[fileIdx].extSize + 2; byte *data = (byte *)MemAlloc(unpackedSize); assert(data); if (volumePtrToFileDescriptor[fileIdx].size + 2 != unpackedSize) { uint8 *packedBuffer = (uint8 *)mallocAndZero(volumePtrToFileDescriptor[fileIdx].size + 2); loadPackedFileToMem(fileIdx, packedBuffer); //uint32 realUnpackedSize = READ_BE_UINT32(packedBuffer + volumePtrToFileDescriptor[fileIdx].size - 4); delphineUnpack(data, packedBuffer, volumePtrToFileDescriptor[fileIdx].size); MemFree(packedBuffer); } else { loadPackedFileToMem(fileIdx, data); } return data; } void PCSoundDriver::setUpdateCallback(UpdateCallback upCb, void *ref) { _upCb = upCb; _upRef = ref; } void PCSoundDriver::findNote(int freq, int *note, int *oct) const { *note = _noteTableCount - 1; for (int i = 0; i < _noteTableCount; ++i) { if (_noteTable[i] <= freq) { *note = i; break; } } *oct = *note / 12; *note %= 12; } void PCSoundDriver::resetChannel(int channel) { stopChannel(channel); stopAll(); } void PCSoundDriver::syncSounds() { bool mute = false; if (ConfMan.hasKey("mute")) mute = ConfMan.getBool("mute"); bool music_mute = mute; bool sfx_mute = mute; if (!mute) { music_mute = ConfMan.getBool("music_mute"); sfx_mute = ConfMan.getBool("sfx_mute"); } // Get the new music and sfx volumes _musicVolume = music_mute ? 0 : MIN(255, ConfMan.getInt("music_volume")); _sfxVolume = sfx_mute ? 0 : MIN(255, ConfMan.getInt("sfx_volume")); } AdLibSoundDriver::AdLibSoundDriver(Audio::Mixer *mixer) : _mixer(mixer) { _opl = OPL::Config::create(); if (!_opl || !_opl->init()) error("Failed to create OPL"); for (int i = 0; i < 5; ++i) { _channelsVolumeTable[i].original = 0; _channelsVolumeTable[i].adjusted = 0; } memset(_instrumentsTable, 0, sizeof(_instrumentsTable)); initCard(); _musicVolume = ConfMan.getBool("music_mute") ? 0 : MIN(255, ConfMan.getInt("music_volume")); _sfxVolume = ConfMan.getBool("sfx_mute") ? 0 : MIN(255, ConfMan.getInt("sfx_volume")); _opl->start(new Common::Functor0Mem(this, &AdLibSoundDriver::onTimer), 50); } AdLibSoundDriver::~AdLibSoundDriver() { delete _opl; } void AdLibSoundDriver::syncSounds() { PCSoundDriver::syncSounds(); // Force all instruments to reload on the next playing point for (int i = 0; i < 5; ++i) { adjustVolume(i, _channelsVolumeTable[i].original); AdLibSoundInstrument *ins = &_instrumentsTable[i]; setupInstrument(ins, i); } } void AdLibSoundDriver::adjustVolume(int channel, int volume) { _channelsVolumeTable[channel].original = volume; volume = CLIP(volume, 0, 80); volume += volume / 4; // The higher possible value for volume is 100 int volAdjust = (channel == 4) ? _sfxVolume : _musicVolume; volume = (volume * volAdjust) / 128; if (volume > 127) volume = 127; _channelsVolumeTable[channel].adjusted = volume; } void AdLibSoundDriver::setupChannel(int channel, const byte *data, int instrument, int volume) { assert(channel < 5); if (data) { adjustVolume(channel, volume); setupInstrument(data, channel); } } void AdLibSoundDriver::stopChannel(int channel) { assert(channel < 5); AdLibSoundInstrument *ins = &_instrumentsTable[channel]; if (ins->mode != 0 && ins->channel == 6) { channel = 6; } if (ins->mode == 0 || channel == 6) { _opl->writeReg(0xB0 | channel, 0); } if (ins->mode != 0) { _vibrato &= ~(1 << (10 - ins->channel)); _opl->writeReg(0xBD, _vibrato); } } void AdLibSoundDriver::stopAll() { for (int i = 0; i < 18; ++i) _opl->writeReg(0x40 | _operatorsTable[i], 63); for (int i = 0; i < 9; ++i) _opl->writeReg(0xB0 | i, 0); _opl->writeReg(0xBD, 0); } void AdLibSoundDriver::initCard() { _vibrato = 0x20; _opl->writeReg(0xBD, _vibrato); _opl->writeReg(0x08, 0x40); static const int oplRegs[] = { 0x40, 0x60, 0x80, 0x20, 0xE0 }; for (int i = 0; i < 9; ++i) { _opl->writeReg(0xB0 | i, 0); } for (int i = 0; i < 9; ++i) { _opl->writeReg(0xC0 | i, 0); } for (int j = 0; j < 5; j++) { for (int i = 0; i < 18; ++i) { _opl->writeReg(oplRegs[j] | _operatorsTable[i], 0); } } _opl->writeReg(1, 0x20); _opl->writeReg(1, 0); } void AdLibSoundDriver::onTimer() { if (_upCb) { (*_upCb)(_upRef); } } void AdLibSoundDriver::setupInstrument(const byte *data, int channel) { assert(channel < 5); AdLibSoundInstrument *ins = &_instrumentsTable[channel]; loadInstrument(data, ins); setupInstrument(ins, channel); } void AdLibSoundDriver::setupInstrument(const AdLibSoundInstrument *ins, int channel) { int mod, car, tmp; const AdLibRegisterSoundInstrument *reg; if (ins->mode != 0) { mod = _operatorsTable[_voiceOperatorsTable[2 * ins->channel + 0]]; car = _operatorsTable[_voiceOperatorsTable[2 * ins->channel + 1]]; } else { mod = _operatorsTable[_voiceOperatorsTable[2 * channel + 0]]; car = _operatorsTable[_voiceOperatorsTable[2 * channel + 1]]; } if (ins->mode == 0 || ins->channel == 6) { reg = &ins->regMod; _opl->writeReg(0x20 | mod, reg->vibrato); if (reg->freqMod) { tmp = reg->outputLevel & 0x3F; } else { tmp = (63 - (reg->outputLevel & 0x3F)) * _channelsVolumeTable[channel].adjusted; tmp = 63 - (2 * tmp + 127) / (2 * 127); } _opl->writeReg(0x40 | mod, tmp | (reg->keyScaling << 6)); _opl->writeReg(0x60 | mod, reg->attackDecay); _opl->writeReg(0x80 | mod, reg->sustainRelease); if (ins->mode != 0) { _opl->writeReg(0xC0 | ins->channel, reg->feedbackStrength); } else { _opl->writeReg(0xC0 | channel, reg->feedbackStrength); } _opl->writeReg(0xE0 | mod, ins->waveSelectMod); } reg = &ins->regCar; _opl->writeReg(0x20 | car, reg->vibrato); tmp = (63 - (reg->outputLevel & 0x3F)) * _channelsVolumeTable[channel].adjusted; tmp = 63 - (2 * tmp + 127) / (2 * 127); _opl->writeReg(0x40 | car, tmp | (reg->keyScaling << 6)); _opl->writeReg(0x60 | car, reg->attackDecay); _opl->writeReg(0x80 | car, reg->sustainRelease); _opl->writeReg(0xE0 | car, ins->waveSelectCar); } void AdLibSoundDriver::loadRegisterInstrument(const byte *data, AdLibRegisterSoundInstrument *reg) { reg->vibrato = 0; if (READ_LE_UINT16(data + 18)) { // amplitude vibrato reg->vibrato |= 0x80; } if (READ_LE_UINT16(data + 20)) { // frequency vibrato reg->vibrato |= 0x40; } if (READ_LE_UINT16(data + 10)) { // sustaining sound reg->vibrato |= 0x20; } if (READ_LE_UINT16(data + 22)) { // envelope scaling reg->vibrato |= 0x10; } reg->vibrato |= READ_LE_UINT16(data + 2) & 0xF; // frequency multiplier reg->attackDecay = READ_LE_UINT16(data + 6) << 4; // attack rate reg->attackDecay |= READ_LE_UINT16(data + 12) & 0xF; // decay rate reg->sustainRelease = READ_LE_UINT16(data + 8) << 4; // sustain level reg->sustainRelease |= READ_LE_UINT16(data + 14) & 0xF; // release rate reg->feedbackStrength = READ_LE_UINT16(data + 4) << 1; // feedback if (READ_LE_UINT16(data + 24) == 0) { // frequency modulation reg->feedbackStrength |= 1; } reg->keyScaling = READ_LE_UINT16(data); reg->outputLevel = READ_LE_UINT16(data + 16); reg->freqMod = READ_LE_UINT16(data + 24); } void AdLibSoundDriverADL::loadInstrument(const byte *data, AdLibSoundInstrument *asi) { asi->mode = *data++; asi->channel = *data++; asi->waveSelectMod = *data++ & 3; asi->waveSelectCar = *data++ & 3; asi->amDepth = *data++; ++data; loadRegisterInstrument(data, &asi->regMod); data += 26; loadRegisterInstrument(data, &asi->regCar); data += 26; } void AdLibSoundDriverADL::setChannelFrequency(int channel, int frequency) { assert(channel < 5); AdLibSoundInstrument *ins = &_instrumentsTable[channel]; if (ins->mode != 0) { channel = ins->channel; if (channel == 9) { channel = 8; } else if (channel == 10) { channel = 7; } } int freq, note, oct; findNote(frequency, ¬e, &oct); note += oct * 12; if (ins->amDepth) { note = ins->amDepth; } if (note < 0) { note = 0; } freq = _freqTable[note % 12]; _opl->writeReg(0xA0 | channel, freq); freq = ((note / 12) << 2) | ((freq & 0x300) >> 8); if (ins->mode == 0) { freq |= 0x20; } _opl->writeReg(0xB0 | channel, freq); if (ins->mode != 0) { _vibrato |= 1 << (10 - channel); _opl->writeReg(0xBD, _vibrato); } } void AdLibSoundDriverADL::playSample(const byte *data, int size, int channel, int volume) { assert(channel < 5); adjustVolume(channel, 127); setupInstrument(data, channel); AdLibSoundInstrument *ins = &_instrumentsTable[channel]; if (ins->mode != 0 && ins->channel == 6) { _opl->writeReg(0xB0 | channel, 0); } if (ins->mode != 0) { _vibrato &= ~(1 << (10 - ins->channel)); _opl->writeReg(0xBD, _vibrato); } if (ins->mode != 0) { channel = ins->channel; if (channel == 9) { channel = 8; } else if (channel == 10) { channel = 7; } } uint16 note = 48; if (ins->amDepth) { note = ins->amDepth; } int freq = _freqTable[note % 12]; _opl->writeReg(0xA0 | channel, freq); freq = ((note / 12) << 2) | ((freq & 0x300) >> 8); if (ins->mode == 0) { freq |= 0x20; } _opl->writeReg(0xB0 | channel, freq); if (ins->mode != 0) { _vibrato |= 1 << (10 - channel); _opl->writeReg(0xBD, _vibrato); } } PCSoundFxPlayer::PCSoundFxPlayer(PCSoundDriver *driver) : _playing(false), _songPlayed(false), _driver(driver) { memset(_instrumentsData, 0, sizeof(_instrumentsData)); _sfxData = NULL; _fadeOutCounter = 0; _driver->setUpdateCallback(updateCallback, this); _currentPos = 0; _currentOrder = 0; _numOrders = 0; _eventsDelay = 0; _looping = false; _updateTicksCounter = 0; } PCSoundFxPlayer::~PCSoundFxPlayer() { _driver->setUpdateCallback(NULL, NULL); stop(); } bool PCSoundFxPlayer::load(const char *song) { debug(9, "PCSoundFxPlayer::load('%s')", song); /* stop (w/ fade out) the previous song */ while (_fadeOutCounter != 0 && _fadeOutCounter < 100) { g_system->delayMillis(50); } _fadeOutCounter = 0; if (_playing) { stop(); } Common::strlcpy(_musicName, song, sizeof(_musicName)); _songPlayed = false; _looping = false; _sfxData = readBundleSoundFile(song); if (!_sfxData) { warning("Unable to load soundfx module '%s'", song); return 0; } for (int i = 0; i < NUM_INSTRUMENTS; ++i) { _instrumentsData[i] = NULL; char instrument[64]; memset(instrument, 0, 64); // Clear the data first memcpy(instrument, _sfxData + 20 + i * 30, 12); instrument[63] = '\0'; if (strlen(instrument) != 0) { char *dot = strrchr(instrument, '.'); if (dot) { *dot = '\0'; } Common::strlcat(instrument, _driver->getInstrumentExtension(), sizeof(instrument)); _instrumentsData[i] = readBundleSoundFile(instrument); if (!_instrumentsData[i]) { warning("Unable to load soundfx instrument '%s'", instrument); } } } return 1; } void PCSoundFxPlayer::play() { debug(9, "PCSoundFxPlayer::play()"); if (_sfxData) { for (int i = 0; i < NUM_CHANNELS; ++i) { _instrumentsChannelTable[i] = -1; } _currentPos = 0; _currentOrder = 0; _numOrders = _sfxData[470]; _eventsDelay = (244 - _sfxData[471]) * 100 / 1060; _updateTicksCounter = 0; _playing = true; } } void PCSoundFxPlayer::stop() { if (_playing || _fadeOutCounter != 0) { _fadeOutCounter = 0; _playing = false; for (int i = 0; i < NUM_CHANNELS; ++i) { _driver->stopChannel(i); } _driver->stopAll(); } unload(); } void PCSoundFxPlayer::fadeOut() { if (_playing) { _fadeOutCounter = 1; _playing = false; } } void PCSoundFxPlayer::updateCallback(void *ref) { ((PCSoundFxPlayer *)ref)->update(); } void PCSoundFxPlayer::update() { if (_playing || (_fadeOutCounter != 0 && _fadeOutCounter < 100)) { ++_updateTicksCounter; if (_updateTicksCounter > _eventsDelay) { handleEvents(); _updateTicksCounter = 0; } } } void PCSoundFxPlayer::handleEvents() { const byte *patternData = _sfxData + 600 + 1800; const byte *orderTable = _sfxData + 472; uint16 patternNum = orderTable[_currentOrder] * 1024; for (int i = 0; i < 4; ++i) { handlePattern(i, patternData + patternNum + _currentPos); patternData += 4; } if (_fadeOutCounter != 0 && _fadeOutCounter < 100) { _fadeOutCounter += 2; } if (_fadeOutCounter >= 100) { stop(); return; } _currentPos += 16; if (_currentPos >= 1024) { _currentPos = 0; ++_currentOrder; if (_currentOrder == _numOrders) { _currentOrder = 0; } } debug(7, "_currentOrder=%d/%d _currentPos=%d", _currentOrder, _numOrders, _currentPos); } void PCSoundFxPlayer::handlePattern(int channel, const byte *patternData) { int instrument = patternData[2] >> 4; if (instrument != 0) { --instrument; if (_instrumentsChannelTable[channel] != instrument || _fadeOutCounter != 0) { _instrumentsChannelTable[channel] = instrument; const int volume = _sfxData[instrument] - _fadeOutCounter; _driver->setupChannel(channel, _instrumentsData[instrument], instrument, volume); } } int16 freq = (int16)READ_BE_UINT16(patternData); if (freq > 0) { _driver->stopChannel(channel); _driver->setChannelFrequency(channel, freq); } } void PCSoundFxPlayer::unload() { for (int i = 0; i < NUM_INSTRUMENTS; ++i) { MemFree(_instrumentsData[i]); _instrumentsData[i] = NULL; } MemFree(_sfxData); _sfxData = NULL; _songPlayed = true; } void PCSoundFxPlayer::doSync(Common::Serializer &s) { s.syncBytes((byte *)_musicName, 33); uint16 v = (uint16)songLoaded(); s.syncAsSint16LE(v); if (s.isLoading() && v) { load(_musicName); for (int i = 0; i < NUM_CHANNELS; ++i) { _instrumentsChannelTable[i] = -1; } _numOrders = _sfxData[470]; _eventsDelay = (244 - _sfxData[471]) * 100 / 1060; _updateTicksCounter = 0; } s.syncAsSint16LE(_songPlayed); s.syncAsSint16LE(_looping); s.syncAsSint16LE(_currentPos); s.syncAsSint16LE(_currentOrder); s.syncAsSint16LE(_playing); } PCSound::PCSound(Audio::Mixer *mixer, CruiseEngine *vm) { _vm = vm; _mixer = mixer; _soundDriver = new AdLibSoundDriverADL(_mixer); _player = new PCSoundFxPlayer(_soundDriver); _genVolume = 0; } PCSound::~PCSound() { delete _player; delete _soundDriver; } void PCSound::loadMusic(const char *name) { debugC(5, kCruiseDebugSound, "PCSound::loadMusic('%s')", name); _player->load(name); } void PCSound::playMusic() { debugC(5, kCruiseDebugSound, "PCSound::playMusic()"); _player->play(); } void PCSound::stopMusic() { debugC(5, kCruiseDebugSound, "PCSound::stopMusic()"); _player->stop(); } void PCSound::removeMusic() { debugC(5, kCruiseDebugSound, "PCSound::removeMusic()"); _player->unload(); } void PCSound::fadeOutMusic() { debugC(5, kCruiseDebugSound, "PCSound::fadeOutMusic()"); _player->fadeOut(); } void PCSound::playSound(const uint8 *data, int size, int volume) { debugC(5, kCruiseDebugSound, "PCSound::playSound() channel %d size %d", 4, size); _soundDriver->playSample(data, size, 4, volume); } void PCSound::stopSound(int channel) { debugC(5, kCruiseDebugSound, "PCSound::stopSound() channel %d", channel); _soundDriver->resetChannel(channel); } void PCSound::stopChannel(int channel) { debugC(5, kCruiseDebugSound, "PCSound::stopChannel() channel %d", channel); _soundDriver->stopChannel(channel); } bool PCSound::isPlaying() const { return _player->playing(); } bool PCSound::songLoaded() const { return _player->songLoaded(); } bool PCSound::songPlayed() const { return _player->songPlayed(); } void PCSound::fadeSong() { _player->fadeOut(); } uint8 PCSound::numOrders() const { return _player->numOrders(); } void PCSound::setNumOrders(uint8 v) { _player->setNumOrders(v); } void PCSound::setPattern(int offset, uint8 value) { _player->setPattern(offset, value); } bool PCSound::musicLooping() const { return _player->looping(); } void PCSound::musicLoop(bool v) { _player->setLooping(v); } void PCSound::startNote(int channel, int volume, int freq) { warning("TODO: startNote"); // _soundDriver->setVolume(channel, volume); _soundDriver->setChannelFrequency(channel, freq); } void PCSound::doSync(Common::Serializer &s) { _player->doSync(s); s.syncAsSint16LE(_genVolume); } const char *PCSound::musicName() { return _player->musicName(); } void PCSound::syncSounds() { _soundDriver->syncSounds(); } } // End of namespace Cruise