/* 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. * * $URL$ * $Id$ * */ #include "sci/sound/drivers/mididriver.h" #include "sound/softsynth/emumidi.h" #include "sound/softsynth/cms.h" #include "sound/mixer.h" #include "sci/resource.h" namespace Sci { class MidiDriver_CMS : public MidiDriver_Emulated { public: MidiDriver_CMS(Audio::Mixer *mixer, ResourceManager *resMan) : MidiDriver_Emulated(mixer), _resMan(resMan), _cms(0), _rate(0), _playSwitch(true), _masterVolume(0) { } int open(); void close(); void send(uint32 b); uint32 property(int prop, uint32 param); MidiChannel *allocateChannel() { return 0; } MidiChannel *getPercussionChannel() { return 0; } bool isStereo() const { return true; } int getRate() const { return _rate; } void playSwitch(bool play); private: void generateSamples(int16 *buffer, int len); ResourceManager *_resMan; CMSEmulator *_cms; void writeToChip1(int address, int data); void writeToChip2(int address, int data); int32 _samplesPerCallback; int32 _samplesPerCallbackRemainder; int32 _samplesTillCallback; int32 _samplesTillCallbackRemainder; int _rate; bool _playSwitch; uint16 _masterVolume; uint8 *_patchData; struct Channel { Channel() : patch(0), volume(0), pan(0x40), hold(0), extraVoices(0), pitchWheel(0x2000), pitchModifier(0), pitchAdditive(false), lastVoiceUsed(0) { } uint8 patch; uint8 volume; uint8 pan; uint8 hold; uint8 extraVoices; uint16 pitchWheel; uint8 pitchModifier; bool pitchAdditive; uint8 lastVoiceUsed; }; Channel _channel[16]; struct Voice { Voice() : channel(0xFF), note(0xFF), sustained(0xFF), ticks(0), turnOffTicks(0), patchDataPtr(0), patchDataIndex(0), amplitudeTimer(0), amplitudeModifier(0), turnOff(false), velocity(0) { } uint8 channel; uint8 note; uint8 sustained; uint16 ticks; uint16 turnOffTicks; const uint8 *patchDataPtr; uint8 patchDataIndex; uint8 amplitudeTimer; uint8 amplitudeModifier; bool turnOff; uint8 velocity; }; Voice _voice[12]; void voiceOn(int voice, int note, int velocity); void voiceOff(int voice); void noteSend(int voice); void noteOn(int channel, int note, int velocity); void noteOff(int channel, int note); void controlChange(int channel, int control, int value); void pitchWheel(int channel, int value); int findVoiceBasic(int channel); void updateVoiceAmplitude(int voice); void setupVoiceAmplitude(int voice); uint8 _octaveRegs[2][3]; static const int _timerFreq = 60; static const int _frequencyTable[]; static const int _velocityTable[]; }; const int MidiDriver_CMS::_frequencyTable[] = { 3, 10, 17, 24, 31, 38, 46, 51, 58, 64, 71, 77, 83, 89, 95, 101, 107, 113, 119, 124, 130, 135, 141, 146, 151, 156, 162, 167, 172, 177, 182, 186, 191, 196, 200, 205, 209, 213, 217, 222, 226, 230, 234, 238, 242, 246, 250, 253 }; const int MidiDriver_CMS::_velocityTable[] = { 1, 3, 6, 8, 9, 10, 11, 12, 12, 13, 13, 14, 14, 14, 15, 15, 0, 1, 2, 2, 3, 4, 4, 5, 6, 6, 7, 8, 8, 9, 10, 10 }; int MidiDriver_CMS::open() { if (_cms) return MERR_ALREADY_OPEN; assert(_resMan); Resource *res = _resMan->findResource(ResourceId(kResourceTypePatch, 101), 0); if (!res) return -1; _patchData = new uint8[res->size]; memcpy(_patchData, res->data, res->size); for (uint i = 0; i < ARRAYSIZE(_channel); ++i) _channel[i] = Channel(); for (uint i = 0; i < ARRAYSIZE(_voice); ++i) _voice[i] = Voice(); _rate = _mixer->getOutputRate(); _cms = new CMSEmulator(_rate); assert(_cms); _playSwitch = true; _masterVolume = 0; for (int i = 0; i < 31; ++i) { writeToChip1(i, 0); writeToChip2(i, 0); } writeToChip1(0x14, 0xFF); writeToChip2(0x14, 0xFF); writeToChip1(0x1C, 1); writeToChip2(0x1C, 1); _samplesPerCallback = getRate() / _timerFreq; _samplesPerCallbackRemainder = getRate() % _timerFreq; _samplesTillCallback = 0; _samplesTillCallbackRemainder = 0; int retVal = MidiDriver_Emulated::open(); if (retVal != 0) return retVal; _mixer->playStream(Audio::Mixer::kPlainSoundType, &_mixerSoundHandle, this, -1, _mixer->kMaxChannelVolume, 0, DisposeAfterUse::NO); return 0; } void MidiDriver_CMS::close() { _mixer->stopHandle(_mixerSoundHandle); delete[] _patchData; delete _cms; _cms = 0; } void MidiDriver_CMS::send(uint32 b) { const uint8 command = b & 0xf0; const uint8 channel = b & 0xf; const uint8 op1 = (b >> 8) & 0xff; const uint8 op2 = (b >> 16) & 0xff; switch (command) { case 0x80: noteOff(channel, op1); break; case 0x90: noteOn(channel, op1, op2); break; case 0xB0: controlChange(channel, op1, op2); break; case 0xC0: _channel[channel].patch = op1; break; case 0xE0: pitchWheel(channel, (op1 & 0x7f) | ((op2 & 0x7f) << 7)); break; default: break; } } uint32 MidiDriver_CMS::property(int prop, uint32 param) { switch (prop) { case MIDI_PROP_MASTER_VOLUME: if (param != 0xffff) _masterVolume = param; return _masterVolume; default: return MidiDriver_Emulated::property(prop, param); } } void MidiDriver_CMS::playSwitch(bool play) { _playSwitch = play; } void MidiDriver_CMS::writeToChip1(int address, int data) { _cms->portWrite(0x221, address); _cms->portWrite(0x220, data); if (address >= 16 && address <= 18) _octaveRegs[0][address - 16] = data; } void MidiDriver_CMS::writeToChip2(int address, int data) { _cms->portWrite(0x223, address); _cms->portWrite(0x222, data); if (address >= 16 && address <= 18) _octaveRegs[1][address - 16] = data; } void MidiDriver_CMS::voiceOn(int voiceNr, int note, int velocity) { Voice &voice = _voice[voiceNr]; voice.note = note; voice.turnOff = false; voice.patchDataIndex = 0; voice.amplitudeTimer = 0; voice.ticks = 0; voice.turnOffTicks = 0; voice.patchDataPtr = _patchData + READ_LE_UINT16(&_patchData[_channel[voice.channel].patch * 2]); if (velocity) velocity = _velocityTable[(velocity >> 3)]; voice.velocity = velocity; noteSend(voiceNr); } void MidiDriver_CMS::voiceOff(int voiceNr) { Voice &voice = _voice[voiceNr]; voice.velocity = 0; voice.note = 0xFF; voice.sustained = 0; voice.turnOff = false; voice.patchDataIndex = 0; voice.amplitudeTimer = 0; voice.amplitudeModifier = 0; voice.ticks = 0; voice.turnOffTicks = 0; setupVoiceAmplitude(voiceNr); } void MidiDriver_CMS::noteSend(int voiceNr) { Voice &voice = _voice[voiceNr]; int frequency = (CLIP(voice.note, 21, 116) - 21) * 4; if (_channel[voice.channel].pitchModifier) { int modifier = _channel[voice.channel].pitchModifier; if (!_channel[voice.channel].pitchAdditive) { if (frequency > modifier) frequency -= modifier; else frequency = 0; } else { int tempFrequency = 384 - frequency; if (modifier < tempFrequency) frequency += modifier; else frequency = 383; } } int chipNumber = 0; if (voiceNr >= 6) { voiceNr -= 6; chipNumber = 1; } int octave = 0; while (frequency >= 48) { frequency -= 48; ++octave; } frequency = _frequencyTable[frequency]; if (chipNumber == 1) writeToChip2(8 + voiceNr, frequency); else writeToChip1(8 + voiceNr, frequency); uint8 octaveData = _octaveRegs[chipNumber][voiceNr >> 1]; if (voiceNr & 1) { octaveData &= 0x0F; octaveData |= (octave << 4); } else { octaveData &= 0xF0; octaveData |= octave; } if (chipNumber == 1) writeToChip2(0x10 + (voiceNr >> 1), octaveData); else writeToChip1(0x10 + (voiceNr >> 1), octaveData); } void MidiDriver_CMS::noteOn(int channel, int note, int velocity) { if (note < 21 || note > 116) return; if (velocity == 0) { noteOff(channel, note); return; } for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].channel == channel && _voice[i].note == note) { _voice[i].sustained = 0; voiceOff(i); voiceOn(i, note, velocity); return; } } int voice = findVoiceBasic(channel); if (voice != -1) voiceOn(voice, note, velocity); } int MidiDriver_CMS::findVoiceBasic(int channel) { int voice = -1; int oldestVoice = -1; int oldestAge = -1; // Try to find a voice assigned to this channel that is free (round-robin) for (int i = 0; i < ARRAYSIZE(_voice); i++) { int v = (_channel[channel].lastVoiceUsed + i + 1) % ARRAYSIZE(_voice); if (_voice[v].note == 0xFF) { voice = v; break; } // We also keep track of the oldest note in case the search fails if (_voice[v].ticks > oldestAge) { oldestAge = _voice[v].ticks; oldestVoice = v; } } if (voice == -1) { if (oldestVoice != -1) { voiceOff(oldestVoice); voice = oldestVoice; } else { return -1; } } _voice[voice].channel = channel; _channel[channel].lastVoiceUsed = voice; return voice; } void MidiDriver_CMS::noteOff(int channel, int note) { for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].channel == channel && _voice[i].note == note) { if (_channel[channel].hold != 0) _voice[i].sustained = true; else _voice[i].turnOff = true; } } } void MidiDriver_CMS::controlChange(int channel, int control, int value) { switch (control) { case 7: if (value) { value >>= 3; if (!value) ++value; } _channel[channel].volume = value; break; case 10: _channel[channel].pan = value; break; case 64: _channel[channel].hold = value; if (!value) { for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].channel == channel && _voice[i].sustained) { _voice[i].sustained = 0; _voice[i].turnOff = true; } } } break; case 75: //ChannelMapping break; case 123: for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].channel == channel && _voice[i].note != 0xFF) voiceOff(i); } break; default: return; } } void MidiDriver_CMS::pitchWheel(int channelNr, int value) { Channel &channel = _channel[channelNr]; channel.pitchWheel = value; channel.pitchAdditive = false; channel.pitchModifier = 0; if (value < 0x2000) { channel.pitchModifier = (0x2000 - value) / 170; } else if (value > 0x2000) { channel.pitchModifier = (value - 0x2000) / 170; channel.pitchAdditive = true; } for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].channel == channelNr && _voice[i].note != 0xFF) noteSend(i); } } void MidiDriver_CMS::updateVoiceAmplitude(int voiceNr) { Voice &voice = _voice[voiceNr]; if (voice.amplitudeTimer != 0 && voice.amplitudeTimer != 254) { --voice.amplitudeTimer; return; } else if (voice.amplitudeTimer == 254) { if (!voice.turnOff) return; voice.amplitudeTimer = 0; } int nextDataIndex = voice.patchDataIndex; uint8 timerData = 0; uint8 amplitudeData = voice.patchDataPtr[nextDataIndex]; if (amplitudeData == 255) { timerData = amplitudeData = 0; voiceOff(voiceNr); } else { timerData = voice.patchDataPtr[nextDataIndex + 1]; nextDataIndex += 2; } voice.patchDataIndex = nextDataIndex; voice.amplitudeTimer = timerData; voice.amplitudeModifier = amplitudeData; } void MidiDriver_CMS::setupVoiceAmplitude(int voiceNr) { Voice &voice = _voice[voiceNr]; uint amplitude = 0; if (_channel[voice.channel].volume && voice.velocity && voice.amplitudeModifier && _masterVolume) { amplitude = _channel[voice.channel].volume * voice.velocity; amplitude /= 0x0F; amplitude *= voice.amplitudeModifier; amplitude /= 0x0F; amplitude *= _masterVolume; amplitude /= 0x0F; if (!amplitude) ++amplitude; } uint8 amplitudeData = 0; int pan = _channel[voice.channel].pan >> 2; if (pan >= 16) { amplitudeData = (amplitude * (31 - pan) / 0x0F) & 0x0F; amplitudeData |= (amplitude << 4); } else { amplitudeData = (amplitude * pan / 0x0F) & 0x0F; amplitudeData <<= 4; amplitudeData |= amplitude; } if (!_playSwitch) amplitudeData = 0; if (voiceNr >= 6) writeToChip2(voiceNr - 6, amplitudeData); else writeToChip1(voiceNr, amplitudeData); } void MidiDriver_CMS::generateSamples(int16 *buffer, int len) { while (len) { if (!_samplesTillCallback) { for (uint i = 0; i < ARRAYSIZE(_voice); ++i) { if (_voice[i].note == 0xFF) continue; ++_voice[i].ticks; if (_voice[i].turnOff) ++_voice[i].turnOffTicks; updateVoiceAmplitude(i); setupVoiceAmplitude(i); } _samplesTillCallback = _samplesPerCallback; _samplesTillCallbackRemainder += _samplesPerCallbackRemainder; if (_samplesTillCallbackRemainder >= _timerFreq) { _samplesTillCallback++; _samplesTillCallbackRemainder -= _timerFreq; } } int32 render = MIN(len, _samplesTillCallback); len -= render; _samplesTillCallback -= render; _cms->readBuffer(buffer, render); buffer += render * 2; } } class MidiPlayer_CMS : public MidiPlayer { public: MidiPlayer_CMS(SciVersion version) : MidiPlayer(version) { } int open(ResourceManager *resMan) { if (_driver) return MERR_ALREADY_OPEN; _driver = new MidiDriver_CMS(g_system->getMixer(), resMan); int driverRetVal = _driver->open(); if (driverRetVal != 0) return driverRetVal; return 0; } void close() { _driver->setTimerCallback(0, 0); _driver->close(); delete _driver; _driver = 0; } bool hasRhythmChannel() const { return false; } byte getPlayId() const { return 9; } int getPolyphony() const { return 12; } void playSwitch(bool play) { static_cast(_driver)->playSwitch(play); } }; MidiPlayer *MidiPlayer_CMS_create(SciVersion version) { return new MidiPlayer_CMS(version); } } // End of namespace SCI