/* 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 "common/debug.h" #include "common/file.h" #include "common/endian.h" #include "common/textconsole.h" #include "gob/gob.h" #include "gob/sound/adlib.h" namespace Gob { const unsigned char AdLib::_operators[] = {0, 1, 2, 8, 9, 10, 16, 17, 18}; const unsigned char AdLib::_volRegNums[] = { 3, 4, 5, 11, 12, 13, 19, 20, 21 }; AdLib::AdLib(Audio::Mixer &mixer) : _mixer(&mixer) { init(); } AdLib::~AdLib() { Common::StackLock slock(_mutex); _mixer->stopHandle(_handle); OPLDestroy(_opl); if (_data && _freeData) delete[] _data; } void AdLib::init() { _index = -1; _data = 0; _playPos = 0; _dataSize = 0; _rate = _mixer->getOutputRate(); _opl = makeAdLibOPL(_rate); _first = true; _ended = false; _playing = false; _freeData = false; _repCount = -1; _samplesTillPoll = 0; for (int i = 0; i < 16; i ++) _pollNotes[i] = 0; setFreqs(); _mixer->playStream(Audio::Mixer::kMusicSoundType, &_handle, this, -1, Audio::Mixer::kMaxChannelVolume, 0, DisposeAfterUse::NO, true); } int AdLib::readBuffer(int16 *buffer, const int numSamples) { Common::StackLock slock(_mutex); int samples; int render; if (!_playing || (numSamples < 0)) { memset(buffer, 0, numSamples * sizeof(int16)); return numSamples; } if (_first) { memset(buffer, 0, numSamples * sizeof(int16)); pollMusic(); return numSamples; } samples = numSamples; while (samples && _playing) { if (_samplesTillPoll) { render = (samples > _samplesTillPoll) ? (_samplesTillPoll) : (samples); samples -= render; _samplesTillPoll -= render; YM3812UpdateOne(_opl, buffer, render); buffer += render; } else { pollMusic(); if (_ended) { memset(buffer, 0, samples * sizeof(int16)); samples = 0; } } } if (_ended) { _first = true; _ended = false; rewind(); _samplesTillPoll = 0; if (_repCount == -1) { reset(); setVoices(); } else if (_repCount > 0) { _repCount--; reset(); setVoices(); } else _playing = false; } return numSamples; } void AdLib::writeOPL(byte reg, byte val) { debugC(6, kDebugSound, "AdLib::writeOPL (%02X, %02X)", reg, val); OPLWriteReg(_opl, reg, val); } void AdLib::setFreqs() { byte lin; byte col; long val = 0; // Run through the 11 channels for (lin = 0; lin < 11; lin ++) { _notes[lin] = 0; _notCol[lin] = 0; _notLin[lin] = 0; _notOn[lin] = false; } // Run through the 25 lines for (lin = 0; lin < 25; lin ++) { // Run through the 12 columns for (col = 0; col < 12; col ++) { if (!col) val = (((0x2710L + lin * 0x18) * 0xCB78 / 0x3D090) << 0xE) * 9 / 0x1B503; _freqs[lin][col] = (short)((val + 4) >> 3); val = val * 0x6A / 0x64; } } } void AdLib::reset() { _first = true; OPLResetChip(_opl); _samplesTillPoll = 0; setFreqs(); // Set frequencies and octave to 0; notes off for (int i = 0; i < 9; i++) { writeOPL(0xA0 | i, 0); writeOPL(0xB0 | i, 0); writeOPL(0xE0 | _operators[i] , 0); writeOPL(0xE0 |(_operators[i] + 3), 0); } // Authorize the control of the waveformes writeOPL(0x01, 0x20); } void AdLib::setKey(byte voice, byte note, bool on, bool spec) { short freq = 0; short octa = 0; // Instruction AX if (spec) { // 0x7F donne 0x16B; // 7F // << 7 = 3F80 // + E000 = 11F80 // & FFFF = 1F80 // * 19 = 31380 // / 2000 = 18 => Ligne 18h, colonne 0 => freq 16B // 0x3A donne 0x2AF; // 3A // << 7 = 1D00 // + E000 = FD00 negatif // * 19 = xB500 // / 2000 = -2 => Ligne 17h, colonne -1 // 2E // << 7 = 1700 // + E000 = F700 negatif // * 19 = x1F00 // / 2000 = short a; short lin; short col; a = (note << 7) + 0xE000; // Volontairement tronque a = (short)((long)a * 25 / 0x2000); if (a < 0) { col = - ((24 - a) / 25); lin = (-a % 25); if (lin) lin = 25 - lin; } else { col = a / 25; lin = a % 25; } _notCol[voice] = col; _notLin[voice] = lin; note = _notes[voice]; } // Instructions 0X 9X 8X else { note -= 12; _notOn[voice] = on; } _notes[voice] = note; note += _notCol[voice]; note = MIN((byte) 0x5F, note); octa = note / 12; freq = _freqs[_notLin[voice]][note - octa * 12]; writeOPL(0xA0 + voice, freq & 0xFF); writeOPL(0xB0 + voice, (freq >> 8) | (octa << 2) | (0x20 * (on ? 1 : 0))); if (!freq) warning("AdLib::setKey Voice %d, note %02X unknown", voice, note); } void AdLib::setVolume(byte voice, byte volume) { debugC(6, kDebugSound, "AdLib::setVolume(%d, %d)", voice, volume); //assert(voice >= 0 && voice <= 9); volume = 0x3F - ((volume * 0x7E) + 0x7F) / 0xFE; writeOPL(0x40 + _volRegNums[voice], volume); } void AdLib::pollMusic() { if ((_playPos > (_data + _dataSize)) && (_dataSize != 0xFFFFFFFF)) { _ended = true; return; } interpret(); } void AdLib::unload() { _playing = false; _index = -1; if (_data && _freeData) delete[] _data; _freeData = false; } bool AdLib::isPlaying() const { return _playing; } bool AdLib::getRepeating() const { return _repCount != 0; } void AdLib::setRepeating(int32 repCount) { _repCount = repCount; } int AdLib::getIndex() const { return _index; } void AdLib::startPlay() { if (_data) _playing = true; } void AdLib::stopPlay() { Common::StackLock slock(_mutex); _playing = false; } ADLPlayer::ADLPlayer(Audio::Mixer &mixer) : AdLib(mixer) { } ADLPlayer::~ADLPlayer() { } bool ADLPlayer::load(const char *fileName) { Common::File song; unload(); song.open(fileName); if (!song.isOpen()) return false; _freeData = true; _dataSize = song.size(); _data = new byte[_dataSize]; song.read(_data, _dataSize); song.close(); reset(); setVoices(); _playPos = _data + 3 + (_data[1] + 1) * 0x38; return true; } bool ADLPlayer::load(byte *data, uint32 size, int index) { unload(); _repCount = 0; _dataSize = size; _data = data; _index = index; reset(); setVoices(); _playPos = _data + 3 + (_data[1] + 1) * 0x38; return true; } void ADLPlayer::unload() { AdLib::unload(); } void ADLPlayer::interpret() { unsigned char instr; byte channel; byte note; byte volume; uint16 tempo; // First tempo, we'll ignore it... if (_first) { tempo = *(_playPos++); // Tempo on 2 bytes if (tempo & 0x80) tempo = ((tempo & 3) << 8) | *(_playPos++); } _first = false; // Instruction instr = *(_playPos++); channel = instr & 0x0F; switch (instr & 0xF0) { // Note on + Volume case 0x00: note = *(_playPos++); _pollNotes[channel] = note; setVolume(channel, *(_playPos++)); setKey(channel, note, true, false); break; // Note on case 0x90: note = *(_playPos++); _pollNotes[channel] = note; setKey(channel, note, true, false); break; // Last note off case 0x80: note = _pollNotes[channel]; setKey(channel, note, false, false); break; // Frequency on/off case 0xA0: note = *(_playPos++); setKey(channel, note, _notOn[channel], true); break; // Volume case 0xB0: volume = *(_playPos++); setVolume(channel, volume); break; // Program change case 0xC0: setVoice(channel, *(_playPos++), false); break; // Special case 0xF0: switch (instr & 0x0F) { case 0xF: // End instruction _ended = true; _samplesTillPoll = 0; return; default: warning("ADLPlayer: Unknown special command %X, stopping playback", instr & 0x0F); _repCount = 0; _ended = true; break; } break; default: warning("ADLPlayer: Unknown command %X, stopping playback", instr & 0xF0); _repCount = 0; _ended = true; break; } // Temporization tempo = *(_playPos++); // End tempo if (tempo == 0xFF) { _ended = true; return; } // Tempo on 2 bytes if (tempo & 0x80) tempo = ((tempo & 3) << 8) | *(_playPos++); if (!tempo) tempo ++; _samplesTillPoll = tempo * (_rate / 1000); } void ADLPlayer::reset() { AdLib::reset(); } void ADLPlayer::rewind() { _playPos = _data + 3 + (_data[1] + 1) * 0x38; } void ADLPlayer::setVoices() { // Definitions of the 9 instruments for (int i = 0; i < 9; i++) setVoice(i, i, true); } void ADLPlayer::setVoice(byte voice, byte instr, bool set) { uint16 strct[27]; byte channel; byte *dataPtr; // i = 0 : 0 1 2 3 4 5 6 7 8 9 10 11 12 26 // i = 1 : 13 14 15 16 17 18 19 20 21 22 23 24 25 27 for (int i = 0; i < 2; i++) { dataPtr = _data + 3 + instr * 0x38 + i * 0x1A; for (int j = 0; j < 27; j++) { strct[j] = READ_LE_UINT16(dataPtr); dataPtr += 2; } channel = _operators[voice] + i * 3; writeOPL(0xBD, 0x00); writeOPL(0x08, 0x00); writeOPL(0x40 | channel, ((strct[0] & 3) << 6) | (strct[8] & 0x3F)); if (!i) writeOPL(0xC0 | voice, ((strct[2] & 7) << 1) | (1 - (strct[12] & 1))); writeOPL(0x60 | channel, ((strct[3] & 0xF) << 4) | (strct[6] & 0xF)); writeOPL(0x80 | channel, ((strct[4] & 0xF) << 4) | (strct[7] & 0xF)); writeOPL(0x20 | channel, ((strct[9] & 1) << 7) | ((strct[10] & 1) << 6) | ((strct[5] & 1) << 5) | ((strct[11] & 1) << 4) | (strct[1] & 0xF)); if (!i) writeOPL(0xE0 | channel, (strct[26] & 3)); else writeOPL(0xE0 | channel, (strct[14] & 3)); if (i && set) writeOPL(0x40 | channel, 0); } } MDYPlayer::MDYPlayer(Audio::Mixer &mixer) : AdLib(mixer) { init(); } MDYPlayer::~MDYPlayer() { } void MDYPlayer::init() { _soundMode = 0; _timbres = 0; _tbrCount = 0; _tbrStart = 0; _timbresSize = 0; } bool MDYPlayer::loadMDY(Common::SeekableReadStream &stream) { unloadMDY(); _freeData = true; byte mdyHeader[70]; stream.read(mdyHeader, 70); _tickBeat = mdyHeader[36]; _beatMeasure = mdyHeader[37]; _totalTick = mdyHeader[38] + (mdyHeader[39] << 8) + (mdyHeader[40] << 16) + (mdyHeader[41] << 24); _dataSize = mdyHeader[42] + (mdyHeader[43] << 8) + (mdyHeader[44] << 16) + (mdyHeader[45] << 24); _nrCommand = mdyHeader[46] + (mdyHeader[47] << 8) + (mdyHeader[48] << 16) + (mdyHeader[49] << 24); // _soundMode is either 0 (melodic) or 1 (percussive) _soundMode = mdyHeader[58]; assert((_soundMode == 0) || (_soundMode == 1)); _pitchBendRangeStep = 25*mdyHeader[59]; _basicTempo = mdyHeader[60] + (mdyHeader[61] << 8); if (_pitchBendRangeStep < 25) _pitchBendRangeStep = 25; else if (_pitchBendRangeStep > 300) _pitchBendRangeStep = 300; _data = new byte[_dataSize]; stream.read(_data, _dataSize); reset(); _playPos = _data; return true; } bool MDYPlayer::loadMDY(const char *fileName) { Common::File song; song.open(fileName); if (!song.isOpen()) return false; bool loaded = loadMDY(song); song.close(); return loaded; } bool MDYPlayer::loadTBR(Common::SeekableReadStream &stream) { unloadTBR(); _timbresSize = stream.size(); _timbres = new byte[_timbresSize]; stream.read(_timbres, _timbresSize); reset(); setVoices(); return true; } bool MDYPlayer::loadTBR(const char *fileName) { Common::File timbres; timbres.open(fileName); if (!timbres.isOpen()) return false; bool loaded = loadTBR(timbres); timbres.close(); return loaded; } void MDYPlayer::unload() { unloadTBR(); unloadMDY(); } void MDYPlayer::unloadMDY() { AdLib::unload(); } void MDYPlayer::unloadTBR() { delete[] _timbres; _timbres = 0; _timbresSize = 0; } void MDYPlayer::interpret() { unsigned char instr; byte channel; byte note; byte volume; uint8 tempoMult, tempoFrac; uint8 ctrlByte1, ctrlByte2; uint8 timbre; // TODO : Verify the loop for percussive mode (11 ?) if (_first) { for (int i = 0; i < 9; i ++) setVolume(i, 0); // TODO : Set pitch range _tempo = _basicTempo; _wait = *(_playPos++); _first = false; } do { instr = *_playPos; debugC(6, kDebugSound, "MDYPlayer::interpret instr 0x%X", instr); switch (instr) { case 0xF8: _wait = *(_playPos++); break; case 0xFC: _ended = true; _samplesTillPoll = 0; return; case 0xF0: _playPos++; ctrlByte1 = *(_playPos++); ctrlByte2 = *(_playPos++); debugC(6, kDebugSound, "MDYPlayer::interpret ctrlBytes 0x%X 0x%X", ctrlByte1, ctrlByte2); if (ctrlByte1 != 0x7F || ctrlByte2 != 0) { _playPos -= 2; while (*(_playPos++) != 0xF7) ; } else { tempoMult = *(_playPos++); tempoFrac = *(_playPos++); _tempo = _basicTempo * tempoMult + (unsigned)(((long)_basicTempo * tempoFrac) >> 7); _playPos++; } _wait = *(_playPos++); break; default: if (instr >= 0x80) { _playPos++; } channel = (int)(instr & 0x0f); switch (instr & 0xf0) { case 0x90: note = *(_playPos++); volume = *(_playPos++); _pollNotes[channel] = note; setVolume(channel, volume); setKey(channel, note, true, false); break; case 0x80: _playPos += 2; note = _pollNotes[channel]; setKey(channel, note, false, false); break; case 0xA0: setVolume(channel, *(_playPos++)); break; case 0xC0: timbre = *(_playPos++); setVoice(channel, timbre, false); break; case 0xE0: warning("MDYPlayer: Pitch bend not yet implemented"); note = *(_playPos)++; note += (unsigned)(*(_playPos++)) << 7; setKey(channel, note, _notOn[channel], true); break; case 0xB0: _playPos += 2; break; case 0xD0: _playPos++; break; default: warning("MDYPlayer: Bad MIDI instr byte: 0%X", instr); while ((*_playPos) < 0x80) _playPos++; if (*_playPos != 0xF8) _playPos--; break; } //switch instr & 0xF0 _wait = *(_playPos++); break; } //switch instr } while (_wait == 0); if (_wait == 0xF8) { _wait = 0xF0; if (*_playPos != 0xF8) _wait += *(_playPos++) & 0x0F; } // _playPos++; _samplesTillPoll = _wait * (_rate / 1000); } void MDYPlayer::reset() { AdLib::reset(); // _soundMode 1 : Percussive mode. if (_soundMode == 1) { writeOPL(0xA6, 0); writeOPL(0xB6, 0); writeOPL(0xA7, 0); writeOPL(0xB7, 0); writeOPL(0xA8, 0); writeOPL(0xB8, 0); // TODO set the correct frequency for the last 4 percussive voices } } void MDYPlayer::rewind() { _playPos = _data; } void MDYPlayer::setVoices() { byte *timbrePtr; timbrePtr = _timbres; debugC(6, kDebugSound, "MDYPlayer::setVoices TBR version: %X.%X", timbrePtr[0], timbrePtr[1]); timbrePtr += 2; _tbrCount = READ_LE_UINT16(timbrePtr); debugC(6, kDebugSound, "MDYPlayer::setVoices Timbres counter: %d", _tbrCount); timbrePtr += 2; _tbrStart = READ_LE_UINT16(timbrePtr); timbrePtr += 2; for (int i = 0; i < _tbrCount; i++) setVoice(i, i, true); } void MDYPlayer::setVoice(byte voice, byte instr, bool set) { // uint16 strct[27]; uint8 strct[27]; byte channel; byte *timbrePtr; char timbreName[10]; timbreName[9] = '\0'; for (int j = 0; j < 9; j++) timbreName[j] = _timbres[6 + j + (instr * 9)]; debugC(6, kDebugSound, "MDYPlayer::setVoice Loading timbre %s", timbreName); // i = 0 : 0 1 2 3 4 5 6 7 8 9 10 11 12 26 // i = 1 : 13 14 15 16 17 18 19 20 21 22 23 24 25 27 for (int i = 0; i < 2; i++) { timbrePtr = _timbres + _tbrStart + instr * 0x38 + i * 0x1A; for (int j = 0; j < 27; j++) { if (timbrePtr >= (_timbres + _timbresSize)) { warning("MDYPlayer: Instrument %d out of range (%d, %d)", instr, (uint32) (timbrePtr - _timbres), _timbresSize); strct[j] = 0; } else //strct[j] = READ_LE_UINT16(timbrePtr); strct[j] = timbrePtr[0]; //timbrePtr += 2; timbrePtr++; } channel = _operators[voice] + i * 3; writeOPL(0xBD, 0x00); writeOPL(0x08, 0x00); writeOPL(0x40 | channel, ((strct[0] & 3) << 6) | (strct[8] & 0x3F)); if (!i) writeOPL(0xC0 | voice, ((strct[2] & 7) << 1) | (1 - (strct[12] & 1))); writeOPL(0x60 | channel, ((strct[3] & 0xF) << 4) | (strct[6] & 0xF)); writeOPL(0x80 | channel, ((strct[4] & 0xF) << 4) | (strct[7] & 0xF)); writeOPL(0x20 | channel, ((strct[9] & 1) << 7) | ((strct[10] & 1) << 6) | ((strct[5] & 1) << 5) | ((strct[11] & 1) << 4) | (strct[1] & 0xF)); if (!i) writeOPL(0xE0 | channel, (strct[26] & 3)); else { writeOPL(0xE0 | channel, (strct[14] & 3)); writeOPL(0x40 | channel, 0); } } } } // End of namespace Gob