/* 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/sci.h" #include "sound/fmopl.h" #include "sound/softsynth/emumidi.h" #include "sci/resource.h" #include "sci/sfx/softseq/mididriver.h" namespace Sci { #ifdef __DC__ #define STEREO false #else #define STEREO true #endif // FIXME: We don't seem to be sending the polyphony init data, so disable this for now #define ADLIB_DISABLE_VOICE_MAPPING class MidiDriver_Adlib : public MidiDriver_Emulated { public: enum { kVoices = 9, kRhythmKeys = 62 }; MidiDriver_Adlib(Audio::Mixer *mixer) : MidiDriver_Emulated(mixer), _playSwitch(true), _masterVolume(15), _rhythmKeyMap(0), _opl(0) { } virtual ~MidiDriver_Adlib() { } // MidiDriver int open(bool isSCI0); void close(); void send(uint32 b); MidiChannel *allocateChannel() { return NULL; } MidiChannel *getPercussionChannel() { return NULL; } // AudioStream bool isStereo() const { return _stereo; } int getRate() const { return _mixer->getOutputRate(); } // MidiDriver_Emulated void generateSamples(int16 *buf, int len); void setVolume(byte volume); void playSwitch(bool play); bool loadResource(const byte *data, uint size); virtual uint32 property(int prop, uint32 param); private: enum ChannelID { kLeftChannel = 1, kRightChannel = 2 }; struct AdlibOperator { bool amplitudeMod; bool vibrato; bool envelopeType; bool kbScaleRate; byte frequencyMult; // (0-15) byte kbScaleLevel; // (0-3) byte totalLevel; // (0-63, 0=max, 63=min) byte attackRate; // (0-15) byte decayRate; // (0-15) byte sustainLevel; // (0-15) byte releaseRate; // (0-15) byte waveForm; // (0-3) }; struct AdlibModulator { byte feedback; // (0-7) bool algorithm; }; struct AdlibPatch { AdlibOperator op[2]; AdlibModulator mod; }; struct Channel { uint8 patch; // Patch setting uint8 volume; // Channel volume (0-63) uint8 pan; // Pan setting (0-127, 64 is center) uint8 holdPedal; // Hold pedal setting (0 to 63 is off, 127 to 64 is on) uint8 extraVoices; // The number of additional voices this channel optimally needs uint16 pitchWheel; // Pitch wheel setting (0-16383, 8192 is center) uint8 lastVoice; // Last voice used for this MIDI channel bool enableVelocity; // Enable velocity control (SCI0) Channel() : patch(0), volume(63), pan(64), holdPedal(0), extraVoices(0), pitchWheel(8192), lastVoice(0), enableVelocity(false) { } }; struct AdlibVoice { int8 channel; // MIDI channel that this voice is assigned to or -1 int8 note; // Currently playing MIDI note or -1 int patch; // Currently playing patch or -1 uint8 velocity; // Note velocity bool isSustained; // Flag indicating a note that is being sustained by the hold pedal uint16 age; // Age of the current note AdlibVoice() : channel(-1), note(-1), patch(-1), velocity(0), isSustained(false), age(0) { } }; bool _stereo; bool _isSCI0; OPL::OPL *_opl; bool _playSwitch; int _masterVolume; Channel _channels[MIDI_CHANNELS]; AdlibVoice _voices[kVoices]; byte *_rhythmKeyMap; Common::Array _patches; void loadInstrument(const byte *ins); void voiceOn(int voice, int note, int velocity); void voiceOff(int voice); void setPatch(int voice, int patch); void setNote(int voice, int note, bool key); void setVelocity(int voice); void setOperator(int oper, AdlibOperator &op); void setRegister(int reg, int value, int channels = kLeftChannel | kRightChannel); void renewNotes(int channel, bool key); void noteOn(int channel, int note, int velocity); void noteOff(int channel, int note); int findVoice(int channel); void voiceMapping(int channel, int voices); void assignVoices(int channel, int voices); void releaseVoices(int channel, int voices); void donateVoices(); int findVoiceBasic(int channel); void setVelocityReg(int regOffset, int velocity, int kbScaleLevel, int pan); int calcVelocity(int voice, int op); }; class MidiPlayer_Adlib : public MidiPlayer { public: MidiPlayer_Adlib() { _driver = new MidiDriver_Adlib(g_system->getMixer()); } int open(ResourceManager *resMan); int getPlayMask(SciVersion soundVersion); int getPolyphony() const { return MidiDriver_Adlib::kVoices; } bool hasRhythmChannel() const { return false; } void setVolume(byte volume) { static_cast(_driver)->setVolume(volume); } void playSwitch(bool play) { static_cast(_driver)->playSwitch(play); } void loadInstrument(int idx, byte *data); }; static const byte registerOffset[MidiDriver_Adlib::kVoices] = { 0x00, 0x01, 0x02, 0x08, 0x09, 0x0A, 0x10, 0x11, 0x12 }; static const byte velocityMap1[64] = { 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 byte velocityMap2[64] = { 0x00, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, 0x29, 0x2a, 0x2b, 0x2c, 0x2d, 0x2e, 0x2f, 0x2f, 0x30, 0x31, 0x32, 0x32, 0x33, 0x34, 0x34, 0x35, 0x36, 0x36, 0x37, 0x38, 0x38, 0x39, 0x39, 0x3a, 0x3a, 0x3b, 0x3b, 0x3b, 0x3c, 0x3c, 0x3c, 0x3d, 0x3d, 0x3d, 0x3e, 0x3e, 0x3e, 0x3e, 0x3f, 0x3f, 0x3f }; static const int ym3812_note[13] = { 0x157, 0x16b, 0x181, 0x198, 0x1b0, 0x1ca, 0x1e5, 0x202, 0x220, 0x241, 0x263, 0x287, 0x2ae }; int MidiDriver_Adlib::open(bool isSCI0) { int rate = _mixer->getOutputRate(); _stereo = STEREO; debug(3, "ADLIB: Starting driver in %s mode", (isSCI0 ? "SCI0" : "SCI1")); _isSCI0 = isSCI0; _opl = OPL::Config::create(isStereo() ? OPL::Config::kDualOpl2 : OPL::Config::kOpl2); // Try falling back to mono, thus plain OPL2 emualtor, when no Dual OPL2 is available. if (!_opl && _stereo) { _stereo = false; _opl = OPL::Config::create(OPL::Config::kOpl2); } if (!_opl) return -1; _opl->init(rate); setRegister(0xBD, 0); setRegister(0x08, 0); setRegister(0x01, 0x20); MidiDriver_Emulated::open(); _mixer->playInputStream(Audio::Mixer::kMusicSoundType, &_mixerSoundHandle, this, -1, _mixer->kMaxChannelVolume, 0, false); return 0; } void MidiDriver_Adlib::close() { _mixer->stopHandle(_mixerSoundHandle); delete _opl; delete[] _rhythmKeyMap; } void MidiDriver_Adlib::setVolume(byte volume) { _masterVolume = volume; renewNotes(-1, true); } // MIDI messages can be found at http://www.midi.org/techspecs/midimessages.php void MidiDriver_Adlib::send(uint32 b) { byte command = b & 0xf0; byte channel = b & 0xf; byte op1 = (b >> 8) & 0xff; byte op2 = (b >> 16) & 0xff; switch (command) { case 0x80: noteOff(channel, op1); break; case 0x90: noteOn(channel, op1, op2); break; case 0xe0: _channels[channel].pitchWheel = (op1 & 0x7f) | ((op2 & 0x7f) << 7); renewNotes(channel, true); break; case 0xb0: switch (op1) { case 0x07: _channels[channel].volume = op2 >> 1; renewNotes(channel, true); break; case 0x0a: _channels[channel].pan = op2; renewNotes(channel, true); break; case 0x40: _channels[channel].holdPedal = op2; if (op2 == 0) { for (int i = 0; i < kVoices; i++) { if ((_voices[i].channel == channel) && _voices[i].isSustained) voiceOff(i); } } break; case 0x4b: #ifndef ADLIB_DISABLE_VOICE_MAPPING voiceMapping(channel, op2); #endif break; case 0x4e: // FIXME: this flag should be set to 0 when a new song is started debug(3, "ADLIB: Setting velocity control flag for channel %i to %i", channel, op2); _channels[channel].enableVelocity = op2; break; case SCI_MIDI_CHANNEL_NOTES_OFF: for (int i = 0; i < kVoices; i++) if ((_voices[i].channel == channel) && (_voices[i].note != -1)) voiceOff(i); break; default: //warning("ADLIB: ignoring MIDI command %02x %02x %02x", command | channel, op1, op2); break; } break; case 0xc0: _channels[channel].patch = op1; break; // The original adlib driver from sierra ignores aftertouch completely, so should we case 0xa0: // Polyphonic key pressure (aftertouch) case 0xd0: // Channel pressure (aftertouch) break; case 0xf0: // SysEx, ignore it break; default: warning("ADLIB: Unknown event %02x", command); } } void MidiDriver_Adlib::generateSamples(int16 *data, int len) { if (isStereo()) len <<= 1; _opl->readBuffer(data, len); // Increase the age of the notes for (int i = 0; i < kVoices; i++) { if (_voices[i].note != -1) _voices[i].age++; } } void MidiDriver_Adlib::loadInstrument(const byte *ins) { AdlibPatch patch; // Set data for the operators for (int i = 0; i < 2; i++) { const byte *op = ins + i * 13; patch.op[i].kbScaleLevel = op[0] & 0x3; patch.op[i].frequencyMult = op[1] & 0xf; patch.op[i].attackRate = op[3] & 0xf; patch.op[i].sustainLevel = op[4] & 0xf; patch.op[i].envelopeType = op[5]; patch.op[i].decayRate = op[6] & 0xf; patch.op[i].releaseRate = op[7] & 0xf; patch.op[i].totalLevel = op[8] & 0x3f; patch.op[i].amplitudeMod = op[9]; patch.op[i].vibrato = op[10]; patch.op[i].kbScaleRate = op[11]; } patch.op[0].waveForm = ins[26] & 0x3; patch.op[1].waveForm = ins[27] & 0x3; // Set data for the modulator patch.mod.feedback = ins[2] & 0x7; patch.mod.algorithm = !ins[12]; // Flag is inverted _patches.push_back(patch); } void MidiDriver_Adlib::voiceMapping(int channel, int voices) { int curVoices = 0; for (int i = 0; i < kVoices; i++) if (_voices[i].channel == channel) curVoices++; curVoices += _channels[channel].extraVoices; if (curVoices < voices) { debug(3, "ADLIB: assigning %i additional voices to channel %i", voices - curVoices, channel); assignVoices(channel, voices - curVoices); } else if (curVoices > voices) { debug(3, "ADLIB: releasing %i voices from channel %i", curVoices - voices, channel); releaseVoices(channel, curVoices - voices); donateVoices(); } } void MidiDriver_Adlib::assignVoices(int channel, int voices) { assert(voices > 0); for (int i = 0; i < kVoices; i++) if (_voices[i].channel == -1) { _voices[i].channel = channel; if (--voices == 0) return; } _channels[channel].extraVoices += voices; } void MidiDriver_Adlib::releaseVoices(int channel, int voices) { if (_channels[channel].extraVoices >= voices) { _channels[channel].extraVoices -= voices; return; } voices -= _channels[channel].extraVoices; _channels[channel].extraVoices = 0; for (int i = 0; i < kVoices; i++) { if ((_voices[i].channel == channel) && (_voices[i].note == -1)) { _voices[i].channel = -1; if (--voices == 0) return; } } for (int i = 0; i < kVoices; i++) { if (_voices[i].channel == channel) { voiceOff(i); _voices[i].channel = -1; if (--voices == 0) return; } } } void MidiDriver_Adlib::donateVoices() { int freeVoices = 0; for (int i = 0; i < kVoices; i++) if (_voices[i].channel == -1) freeVoices++; if (freeVoices == 0) return; for (int i = 0; i < MIDI_CHANNELS; i++) { if (_channels[i].extraVoices >= freeVoices) { assignVoices(i, freeVoices); _channels[i].extraVoices -= freeVoices; return; } else if (_channels[i].extraVoices > 0) { assignVoices(i, _channels[i].extraVoices); freeVoices -= _channels[i].extraVoices; _channels[i].extraVoices = 0; } } } void MidiDriver_Adlib::renewNotes(int channel, bool key) { for (int i = 0; i < kVoices; i++) { // Update all notes playing this channel if ((channel == -1) || (_voices[i].channel == channel)) { if (_voices[i].note != -1) setNote(i, _voices[i].note, key); } } } void MidiDriver_Adlib::noteOn(int channel, int note, int velocity) { if (velocity == 0) return noteOff(channel, note); velocity >>= 1; // Check for playable notes if ((note < 12) || (note > 107)) return; for (int i = 0; i < kVoices; i++) { if ((_voices[i].channel == channel) && (_voices[i].note == note)) { voiceOff(i); voiceOn(i, note, velocity); return; } } #ifdef ADLIB_DISABLE_VOICE_MAPPING int voice = findVoiceBasic(channel); #else int voice = findVoice(channel); #endif if (voice == -1) { debug(3, "ADLIB: failed to find free voice assigned to channel %i", channel); return; } voiceOn(voice, note, velocity); } // FIXME: Temporary, see comment at top of file regarding ADLIB_DISABLE_VOICE_MAPPING int MidiDriver_Adlib::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 < kVoices; i++) { int v = (_channels[channel].lastVoice + i + 1) % kVoices; if (_voices[v].note == -1) { voice = v; break; } // We also keep track of the oldest note in case the search fails if (_voices[v].age > oldestAge) { oldestAge = _voices[v].age; oldestVoice = v; } } if (voice == -1) { if (oldestVoice != -1) { voiceOff(oldestVoice); voice = oldestVoice; } else { return -1; } } _voices[voice].channel = channel; _channels[channel].lastVoice = voice; return voice; } int MidiDriver_Adlib::findVoice(int channel) { int voice = -1; int oldestVoice = -1; uint32 oldestAge = 0; // Try to find a voice assigned to this channel that is free (round-robin) for (int i = 0; i < kVoices; i++) { int v = (_channels[channel].lastVoice + i + 1) % kVoices; if (_voices[v].channel == channel) { if (_voices[v].note == -1) { voice = v; break; } // We also keep track of the oldest note in case the search fails // Notes started in the current time slice will not be selected if (_voices[v].age > oldestAge) { oldestAge = _voices[v].age; oldestVoice = v; } } } if (voice == -1) { if (oldestVoice != -1) { voiceOff(oldestVoice); voice = oldestVoice; } else { return -1; } } _channels[channel].lastVoice = voice; return voice; } void MidiDriver_Adlib::noteOff(int channel, int note) { for (int i = 0; i < kVoices; i++) { if ((_voices[i].channel == channel) && (_voices[i].note == note)) { if (_channels[channel].holdPedal) _voices[i].isSustained = true; else voiceOff(i); return; } } } void MidiDriver_Adlib::voiceOn(int voice, int note, int velocity) { int channel = _voices[voice].channel; int patch; _voices[voice].age = 0; if ((channel == 9) && _rhythmKeyMap) { patch = CLIP(note, 27, 88) + 101; } else { patch = _channels[channel].patch; } // Set patch if different from current patch if ((patch != _voices[voice].patch) && _playSwitch) setPatch(voice, patch); _voices[voice].velocity = velocity; setNote(voice, note, true); } void MidiDriver_Adlib::voiceOff(int voice) { _voices[voice].isSustained = false; setNote(voice, _voices[voice].note, 0); _voices[voice].note = -1; _voices[voice].age = 0; } void MidiDriver_Adlib::setNote(int voice, int note, bool key) { int channel = _voices[voice].channel; int n, fre, oct; float delta; int bend = _channels[channel].pitchWheel; if ((channel == 9) && _rhythmKeyMap) { note = _rhythmKeyMap[CLIP(note, 27, 88) - 27]; } _voices[voice].note = note; delta = 0; n = note % 12; if (bend < 8192) bend = 8192 - bend; delta = (float)pow(2.0, (bend % 8192) / 8192.0); if (bend > 8192) fre = (int)(ym3812_note[n] * delta); else fre = (int)(ym3812_note[n] / delta); oct = note / 12 - 1; if (oct < 0) oct = 0; if (oct > 7) oct = 7; setRegister(0xA0 + voice, fre & 0xff); setRegister(0xB0 + voice, (key << 5) | (oct << 2) | (fre >> 8)); setVelocity(voice); } void MidiDriver_Adlib::setVelocity(int voice) { AdlibPatch &patch = _patches[_voices[voice].patch]; int pan = _channels[_voices[voice].channel].pan; setVelocityReg(registerOffset[voice] + 3, calcVelocity(voice, 1), patch.op[1].kbScaleLevel, pan); // In AM mode we need to set the level for both operators if (_patches[_voices[voice].patch].mod.algorithm == 1) setVelocityReg(registerOffset[voice], calcVelocity(voice, 0), patch.op[0].kbScaleLevel, pan); } int MidiDriver_Adlib::calcVelocity(int voice, int op) { if (_isSCI0) { int velocity = _masterVolume; if (velocity > 0) velocity += 3; if (velocity > 15) velocity = 15; int insVelocity; if (_channels[_voices[voice].channel].enableVelocity) insVelocity = _voices[voice].velocity; else insVelocity = 63 - _patches[_voices[voice].patch].op[op].totalLevel; // Note: Later SCI0 has a static table that is close to this formula, but not exactly the same. // Early SCI0 does (velocity * (insVelocity / 15)) return velocity * insVelocity / 15; } else { AdlibOperator &oper = _patches[_voices[voice].patch].op[op]; int velocity = _channels[_voices[voice].channel].volume + 1; velocity = velocity * (velocityMap1[_voices[voice].velocity] + 1) / 64; velocity = velocity * (_masterVolume + 1) / 16; if (--velocity < 0) velocity = 0; return velocityMap2[velocity] * (63 - oper.totalLevel) / 63; } } void MidiDriver_Adlib::setVelocityReg(int regOffset, int velocity, int kbScaleLevel, int pan) { if (!_playSwitch) velocity = 0; if (isStereo()) { int velLeft = velocity; int velRight = velocity; if (pan > 0x40) velLeft = velLeft * (0x7f - pan) / 0x3f; else if (pan < 0x40) velRight = velRight * pan / 0x40; setRegister(0x40 + regOffset, (kbScaleLevel << 6) | (63 - velLeft), kLeftChannel); setRegister(0x40 + regOffset, (kbScaleLevel << 6) | (63 - velRight), kRightChannel); } else { setRegister(0x40 + regOffset, (kbScaleLevel << 6) | (63 - velocity)); } } void MidiDriver_Adlib::setPatch(int voice, int patch) { if ((patch < 0) || ((uint)patch >= _patches.size())) { warning("ADLIB: Invalid patch %i requested", patch); patch = 0; } _voices[voice].patch = patch; AdlibModulator &mod = _patches[patch].mod; // Set the common settings for both operators setOperator(registerOffset[voice], _patches[patch].op[0]); setOperator(registerOffset[voice] + 3, _patches[patch].op[1]); // Set the additional settings for the modulator byte algorithm = mod.algorithm ? 1 : 0; setRegister(0xC0 + voice, (mod.feedback << 1) | algorithm); } void MidiDriver_Adlib::setOperator(int reg, AdlibOperator &op) { setRegister(0x40 + reg, (op.kbScaleLevel << 6) | op.totalLevel); setRegister(0x60 + reg, (op.attackRate << 4) | op.decayRate); setRegister(0x80 + reg, (op.sustainLevel << 4) | op.releaseRate); setRegister(0x20 + reg, (op.amplitudeMod << 7) | (op.vibrato << 6) | (op.envelopeType << 5) | (op.kbScaleRate << 4) | op.frequencyMult); setRegister(0xE0 + reg, op.waveForm); } void MidiDriver_Adlib::setRegister(int reg, int value, int channels) { if (channels & kLeftChannel) { _opl->write(0x220, reg); _opl->write(0x221, value); } if (isStereo()) { if (channels & kRightChannel) { _opl->write(0x222, reg); _opl->write(0x223, value); } } } void MidiDriver_Adlib::playSwitch(bool play) { _playSwitch = play; renewNotes(-1, play); } bool MidiDriver_Adlib::loadResource(const byte *data, uint size) { if ((size != 1344) && (size != 2690) && (size != 5382)) { warning("ADLIB: Unsupported patch format (%i bytes)", size); return false; } for (int i = 0; i < 48; i++) loadInstrument(data + (28 * i)); if (size == 2690) { for (int i = 48; i < 96; i++) loadInstrument(data + 2 + (28 * i)); } else if (size == 5382) { for (int i = 48; i < 190; i++) loadInstrument(data + (28 * i)); _rhythmKeyMap = new byte[kRhythmKeys]; memcpy(_rhythmKeyMap, data + 5320, kRhythmKeys); } return true; } uint32 MidiDriver_Adlib::property(int prop, uint32 param) { switch(prop) { case MIDI_PROP_MASTER_VOLUME: if (param != 0xffff) _masterVolume = param; return _masterVolume; default: break; } return 0; } int MidiPlayer_Adlib::open(ResourceManager *resMan) { assert(resMan != NULL); // Load up the patch.003 file, parse out the instruments Resource *res = resMan->findResource(ResourceId(kResourceTypePatch, 3), 0); bool ok = false; if (res) { ok = static_cast(_driver)->loadResource(res->data, res->size); } else { // Early SCI0 games have the sound bank embedded in the adlib driver Common::File f; if (f.open("ADL.DRV")) { int size = f.size(); const uint patchSize = 1344; if ((size == 5684) || (size == 5720) || (size == 5727)) { byte *buf = new byte[patchSize]; if (f.seek(0x45a) && (f.read(buf, patchSize) == patchSize)) ok = static_cast(_driver)->loadResource(buf, patchSize); delete[] buf; } } } if (!ok) { warning("ADLIB: Failed to load patch.003"); return -1; } return static_cast(_driver)->open(getSciVersion() <= SCI_VERSION_0_LATE); } int MidiPlayer_Adlib::getPlayMask(SciVersion soundVersion) { return (soundVersion == SCI_VERSION_0_EARLY) ? 0x01 : 0x04; } MidiPlayer *MidiPlayer_Adlib_create() { return new MidiPlayer_Adlib(); } MidiDriver *MidiDriver_Adlib_create() { return new MidiDriver_Adlib(g_system->getMixer()); } } // End of namespace Sci