/* 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/scummsys.h" #include "common/endian.h" #include "common/stream.h" #include "common/util.h" #include "common/debug.h" #include "sound/mods/tfmx.h" #ifdef _MSC_VER #include "tfmx/tfmxdebug.h" #endif namespace Audio { const uint16 Tfmx::noteIntervalls[64] = { 1710, 1614, 1524, 1438, 1357, 1281, 1209, 1141, 1077, 1017, 960, 908, 856, 810, 764, 720, 680, 642, 606, 571, 539, 509, 480, 454, 428, 404, 381, 360, 340, 320, 303, 286, 270, 254, 240, 227, 214, 202, 191, 180, 170, 160, 151, 143, 135, 127, 120, 113, 214, 202, 191, 180, 170, 160, 151, 143, 135, 127, 120, 113, 214, 202, 191, 180 }; Tfmx::Tfmx(int rate, bool stereo) : Paula(stereo, rate), _resource(), _playerCtx() { _playerCtx.stopWithLastPattern = false; for (int i = 0; i < kNumVoices; ++i) _channelCtx[i].paulaChannel = (byte)i; _playerCtx.song = -1; _playerCtx.volume = 0x40; _playerCtx.patternSkip = 6; stopPatternChannels(); stopMacroChannels(); setTimerBaseValue(kPalCiaClock); setInterruptFreqUnscaled(kPalDefaultCiaVal); } Tfmx::~Tfmx() { } void Tfmx::interrupt() { assert(!_end); ++_playerCtx.tickCount; for (int i = 0; i < kNumVoices; ++i) { ChannelContext &channel = _channelCtx[i]; if (channel.dmaIntCount) { // wait for DMA Interupts to happen int doneDma = getChannelDmaCount(channel.paulaChannel); if (doneDma >= channel.dmaIntCount) { channel.dmaIntCount = 0; channel.macroRun = true; } } if (channel.sfxLockTime >= 0) --channel.sfxLockTime; else { channel.sfxLocked = false; channel.customMacroPrio = 0; } // externally queued macros if (channel.customMacro) { const byte *const noteCmd = (const byte *)&channel.customMacro; channel.sfxLocked = false; noteCommand(noteCmd[0], noteCmd[1], (noteCmd[2] & 0xF0) | (uint8)i, noteCmd[3]); channel.customMacro = 0; channel.sfxLocked = (channel.customMacroPrio != 0); } // apply timebased effects on Parameters if (channel.macroSfxRun > 0) effects(channel); // see if we have to run the macro-program if (channel.macroRun) { if (!channel.macroWait) { macroRun(channel); //assert( !channel.deferWait ); // we can remove this variable as it should be never true after macroRun? } else --channel.macroWait; } Paula::setChannelPeriod(channel.paulaChannel, channel.period); if (channel.macroSfxRun >= 0) channel.macroSfxRun = 1; // TODO: handling pending DMAOff? } // Patterns are only processed each _playerCtx.timerCount + 1 tick if (_playerCtx.song >= 0 && !_playerCtx.patternCount--) { _playerCtx.patternCount = _playerCtx.patternSkip; advancePatterns(); } } void Tfmx::effects(ChannelContext &channel) { // addBegin if (channel.addBeginLength) { channel.sampleStart += channel.addBeginDelta; Paula::setChannelSampleStart(channel.paulaChannel, _resource.getSamplePtr(channel.sampleStart)); if (!(--channel.addBeginCount)) { channel.addBeginCount = channel.addBeginLength; channel.addBeginDelta = -channel.addBeginDelta; } } // vibrato if (channel.vibLength) { channel.vibValue += channel.vibDelta; if (--channel.vibCount == 0) { channel.vibCount = channel.vibLength; channel.vibDelta = -channel.vibDelta; } if (!channel.portaDelta) { // 16x16 bit multiplication, casts needed for the right results channel.period = (uint16)(((uint32)channel.refPeriod * (uint16)((1 << 11) + channel.vibValue)) >> 11); } } // portamento if (channel.portaDelta && --channel.portaCount == 0) { channel.portaCount = channel.portaSkip; bool resetPorta = true; const uint16 period = channel.refPeriod; uint16 portaVal = channel.portaValue; if (period > portaVal) { portaVal = ((uint32)portaVal * (uint16)((1 << 8) + channel.portaDelta)) >> 8; resetPorta = (period <= portaVal); } else if (period < portaVal) { portaVal = ((uint32)portaVal * (uint16)((1 << 8) - channel.portaDelta)) >> 8; resetPorta = (period >= portaVal); } if (resetPorta) { channel.portaDelta = 0; channel.portaValue = period & 0x7FF; } else channel.period = channel.portaValue = portaVal & 0x7FF; } // envelope if (channel.envSkip && !channel.envCount--) { channel.envCount = channel.envSkip; const int8 endVol = channel.envEndVolume; int8 volume = channel.volume; bool resetEnv = true; if (endVol > volume) { volume += channel.envDelta; resetEnv = endVol <= volume; } else { volume -= channel.envDelta; resetEnv = volume <= 0 || endVol >= volume; } if (resetEnv) { channel.envSkip = 0; volume = endVol; } channel.volume = volume; } // Fade if (_playerCtx.fadeDelta && !(--_playerCtx.fadeCount)) { _playerCtx.fadeCount = _playerCtx.fadeSkip; _playerCtx.volume += _playerCtx.fadeDelta; if (_playerCtx.volume == _playerCtx.fadeEndVolume) _playerCtx.fadeDelta = 0; } // Volume const uint8 finVol = _playerCtx.volume * channel.volume >> 6; Paula::setChannelVolume(channel.paulaChannel, finVol); } static void warnMacroUnimplemented(const byte *macroPtr, int level) { if (level > 0) return; if (level == 0) debug("Warning - Macro not supported:"); else debug("Warning - Macro not completely supported:"); #ifdef _MSC_VER displayMacroStep(macroPtr); #endif } void Tfmx::macroRun(ChannelContext &channel) { bool deferWait = false; for (;;) { const byte *const macroPtr = (byte *)(_resource.getMacroPtr(channel.macroOffset) + channel.macroStep); ++channel.macroStep; switch (macroPtr[0]) { case 0x00: // Reset + DMA Off. Parameters: deferWait, addset, vol clearEffects(channel); // FT case 0x13: // DMA Off. Parameters: deferWait, addset, vol // TODO: implement PArameters Paula::disableChannel(channel.paulaChannel); channel.deferWait = deferWait = (macroPtr[1] != 0); if (deferWait) { // if set, then we expect a DMA On in the same tick. channel.period = 4; //Paula::setChannelPeriod(channel.paulaChannel, channel.period); Paula::setChannelSampleLen(channel.paulaChannel, 1); // in this state we then need to allow some commands that normally // would halt the macroprogamm to continue instead. // those commands are: Wait, WaitDMA, AddPrevNote, AddNote, SetNote, // DMA On is affected aswell // TODO remember time disabled, remember pending dmaoff?. } else { //TODO ? } if (macroPtr[2]) channel.volume = macroPtr[3]; else if (macroPtr[3]) channel.volume = channel.relVol * 3 + macroPtr[3]; else continue; Paula::setChannelVolume(channel.paulaChannel, channel.volume); continue; case 0x01: // DMA On // TODO: Parameter macroPtr[1] - en-/disable effects if (macroPtr[1]) debug("Tfmx: DMA On %i", (int8)macroPtr[1]); channel.dmaIntCount = 0; if (deferWait) { // TODO // there is actually a small delay in the player, but I think that // only allows to clear DMA-State on real Hardware } Paula::setChannelPeriod(channel.paulaChannel, channel.period); Paula::enableChannel(channel.paulaChannel); channel.deferWait = deferWait = false; continue; case 0x02: // SetBeginn. Parameters: SampleOffset(L) channel.addBeginLength = 0; channel.sampleStart = READ_BE_UINT32(macroPtr) & 0xFFFFFF; Paula::setChannelSampleStart(channel.paulaChannel, _resource.getSamplePtr(channel.sampleStart)); continue; case 0x03: // SetLength. Parameters: SampleLength(W) channel.sampleLen = READ_BE_UINT16(¯oPtr[2]); Paula::setChannelSampleLen(channel.paulaChannel, channel.sampleLen); continue; case 0x04: // Wait. Parameters: Ticks to wait(W). // TODO: some unkown Parameter? (macroPtr[1] & 1) channel.macroWait = READ_BE_UINT16(¯oPtr[2]); return; case 0x10: // Loop Key Up. Parameters: Loopcount, MacroStep(W) if (channel.keyUp) continue; // FT case 0x05: // Loop. Parameters: Loopcount, MacroStep(W) if (channel.macroLoopCount != 0) { if (channel.macroLoopCount == 0xFF) channel.macroLoopCount = macroPtr[1]; channel.macroStep = READ_BE_UINT16(¯oPtr[2]); } --channel.macroLoopCount; continue; case 0x06: // Jump. Parameters: MacroIndex, MacroStep(W) channel.macroIndex = macroPtr[1] & (kMaxMacroOffsets - 1); channel.macroOffset = _macroOffset[macroPtr[1] & (kMaxMacroOffsets - 1)]; channel.macroStep = READ_BE_UINT16(¯oPtr[2]); channel.macroLoopCount = 0xFF; continue; case 0x07: // Stop Macro channel.macroRun = false; --channel.macroStep; return; case 0x08: // AddNote. Parameters: Note, Finetune(W) setNoteMacro(channel, channel.note + macroPtr[1], READ_BE_UINT16(¯oPtr[2])); break; case 0x09: // SetNote. Parameters: Note, Finetune(W) setNoteMacro(channel, macroPtr[1], READ_BE_UINT16(¯oPtr[2])); break; case 0x0A: // Clear Effects clearEffects(channel); continue; case 0x0B: // Portamento. Parameters: count, speed channel.portaSkip = macroPtr[1]; channel.portaCount = 1; // if porta is already running, then keep using old value if (!channel.portaDelta) channel.portaValue = channel.refPeriod; channel.portaDelta = READ_BE_UINT16(¯oPtr[2]); continue; case 0x0C: // Vibrato. Parameters: Speed, intensity channel.vibLength = macroPtr[1]; channel.vibCount = macroPtr[1] / 2; channel.vibDelta = macroPtr[3]; if (!channel.portaDelta) { channel.period = channel.refPeriod; //Paula::setChannelPeriod(channel.paulaChannel, channel.period); channel.vibValue = 0; } continue; case 0x0D: // Add Volume. Parameters: note, addNoteFlag, volume if (macroPtr[2] == 0xFE) setNoteMacro(channel, channel.note + macroPtr[1], 0); channel.volume = channel.relVol * 3 + macroPtr[3]; continue; case 0x0E: // Set Volume. Parameters: note, addNoteFlag, volume if (macroPtr[2] == 0xFE) setNoteMacro(channel, channel.note + macroPtr[1], 0); channel.volume = macroPtr[3]; continue; case 0x0F: // Envelope. Parameters: speed, count, endvol channel.envDelta = macroPtr[1]; channel.envCount = channel.envSkip = macroPtr[2]; channel.envEndVolume = macroPtr[3]; continue; case 0x11: // AddBegin. Parameters: times, Offset(W) channel.addBeginLength = channel.addBeginCount = macroPtr[1]; channel.addBeginDelta = (int16)READ_BE_UINT16(¯oPtr[2]); channel.sampleStart += channel.addBeginDelta; Paula::setChannelSampleStart(channel.paulaChannel, _resource.getSamplePtr(channel.sampleStart)); warnMacroUnimplemented(macroPtr, 1); continue; case 0x12: // AddLen. Parameters: added Length(W) channel.sampleLen += (int16)READ_BE_UINT16(¯oPtr[2]); Paula::setChannelSampleLen(channel.paulaChannel, channel.sampleLen); continue; case 0x14: // Wait key up. Parameters: wait cycles if (channel.keyUp || channel.macroLoopCount == 0) { channel.macroLoopCount = 0xFF; continue; } else if (channel.macroLoopCount == 0xFF) channel.macroLoopCount = macroPtr[3]; --channel.macroLoopCount; --channel.macroStep; return; case 0x15: // Subroutine. Parameters: MacroIndex, Macrostep(W) channel.macroReturnOffset = channel.macroOffset; channel.macroReturnStep = channel.macroStep; channel.macroOffset = _macroOffset[macroPtr[1] & (kMaxMacroOffsets - 1)]; channel.macroStep = READ_BE_UINT16(¯oPtr[2]); // TODO: MI does some weird stuff there. Figure out which varioables need to be set continue; case 0x16: // Return from Sub. channel.macroOffset = channel.macroReturnOffset; channel.macroStep = channel.macroReturnStep; continue; case 0x17: // set Period. Parameters: Period(W) channel.refPeriod = READ_BE_UINT16(¯oPtr[2]); if (!channel.portaDelta) { channel.period = channel.refPeriod; //Paula::setChannelPeriod(channel.paulaChannel, channel.period); } continue; case 0x18: { // Sampleloop. Parameters: Offset from Samplestart(W) // TODO: MI loads 24 bit, but thats useless? const uint16 temp = /* ((int8)macroPtr[1] << 16) | */ READ_BE_UINT16(¯oPtr[2]); if (macroPtr[1] || (temp & 1)) warning("Tfmx: Problematic value for sampleloop: %i", (macroPtr[1] << 16) | temp); channel.sampleStart += temp & 0xFFFE; channel.sampleLen -= (temp / 2) /* & 0x7FFF */; Paula::setChannelSampleStart(channel.paulaChannel, _resource.getSamplePtr(channel.sampleStart)); Paula::setChannelSampleLen(channel.paulaChannel, channel.sampleLen); continue; } case 0x19: // set one-shot Sample channel.addBeginLength = 0; channel.sampleStart = 0; channel.sampleLen = 1; Paula::setChannelSampleStart(channel.paulaChannel, _resource.getSamplePtr(0)); Paula::setChannelSampleLen(channel.paulaChannel, 1); continue; case 0x1A: // Wait on DMA. Parameters: Cycles-1(W) to wait channel.dmaIntCount = READ_BE_UINT16(¯oPtr[2]) + 1; channel.macroRun = false; Paula::setChannelDmaCount(channel.paulaChannel); break; case 0x1B: // Random play. Parameters: macro/speed/mode warnMacroUnimplemented(macroPtr, 0); continue; case 0x1C: // Branch on Note. Parameters: note/macrostep(W) if (channel.note > macroPtr[1]) channel.macroStep = READ_BE_UINT16(¯oPtr[2]); continue; case 0x1D: // Branch on Volume. Parameters: volume/macrostep(W) if (channel.volume > macroPtr[1]) channel.macroStep = READ_BE_UINT16(¯oPtr[2]); continue; case 0x1E: // Addvol+note. Parameters: note/CONST./volume warnMacroUnimplemented(macroPtr, 0); continue; case 0x1F: // AddPrevNote. Parameters: Note, Finetune(W) setNoteMacro(channel, channel.prevNote + macroPtr[1], READ_BE_UINT16(¯oPtr[2])); break; case 0x20: // Signal. Parameters: signalnumber/value if (_playerCtx.signal) _playerCtx.signal[macroPtr[1]] = READ_BE_UINT16(¯oPtr[2]); continue; case 0x21: // Play macro. Parameters: macro/chan/detune noteCommand(channel.note, (channel.relVol << 4) | macroPtr[1], macroPtr[2], macroPtr[3]); continue; #if defined(TFMX_NOT_IMPLEMENTED) // used by Gem`X according to the docs case 0x22: // SID setbeg. Parameters: sample-startadress return true; case 0x23: // SID setlen. Parameters: buflen/sourcelen return true; case 0x24: // SID op3 ofs. Parameters: offset return true; case 0x25: // SID op3 frq. Parameters: speed/amplitude return true; case 0x26: // SID op2 ofs. Parameters: offset return true; case 0x27: // SID op2 frq. Parameters: speed/amplitude return true; case 0x28: // ID op1. Parameters: speed/amplitude/TC return true; case 0x29: // SID stop. Parameters: flag (1=clear all) return true; // 30-34 used by Carribean Disaster #endif default: warnMacroUnimplemented(macroPtr, 0); } if (!deferWait) return; } } void Tfmx::advancePatterns() { startPatterns: int runningPatterns = 0; for (int i = 0; i < kNumChannels; ++i) { const uint8 pattCmd = _patternCtx[i].command; if (pattCmd < 0x90) { // execute Patternstep ++runningPatterns; if (_patternCtx[i].wait == 0) { // issue all Steps for this tick const bool pendingTrackstep = patternRun(_patternCtx[i]); if (pendingTrackstep) { // we load the next Trackstep Command and then process all Channels again trackRun(true); goto startPatterns; } } else --_patternCtx[i].wait; } else if (pattCmd == 0xFE) { // Stop voice in pattern.expose _patternCtx[i].command = 0xFF; ChannelContext &channel = _channelCtx[_patternCtx[i].expose & (kNumVoices - 1)]; if (!channel.sfxLocked) { clearMacroProgramm(channel); Paula::disableChannel(channel.paulaChannel); } } // else this pattern-Channel is stopped } if (_playerCtx.stopWithLastPattern && !runningPatterns) { stopPaula(); } } static void warnPatternUnimplemented(const byte *patternPtr, int level) { if (level > 0) return; if (level == 0) debug("Warning - Pattern not supported:"); else debug("Warning - Pattern not completely supported:"); #ifdef _MSC_VER displayPatternstep(patternPtr); #endif } bool Tfmx::patternRun(PatternContext &pattern) { for (;;) { const byte *const patternPtr = (byte *)(_resource.getPatternPtr(pattern.offset) + pattern.step); ++pattern.step; const byte pattCmd = patternPtr[0]; if (pattCmd < 0xF0) { // Playnote bool doWait = false; byte noteCmd = pattCmd + pattern.expose; byte param3 = patternPtr[3]; if (pattCmd < 0xC0) { // Note if (pattCmd >= 0x80) { // Wait pattern.wait = param3; param3 = 0; doWait = true; } noteCmd &= 0x3F; } // else Portamento noteCommand(noteCmd, patternPtr[1], patternPtr[2], param3); if (doWait) return false; } else { // Patterncommand switch (pattCmd & 0xF) { case 0: // End Pattern + Next Trackstep pattern.command = 0xFF; --pattern.step; return true; case 1: // Loop Pattern. Parameters: Loopcount, PatternStep(W) if (pattern.loopCount != 0) { if (pattern.loopCount == 0xFF) pattern.loopCount = patternPtr[1]; pattern.step = READ_BE_UINT16(&patternPtr[2]); } --pattern.loopCount; continue; case 2: // Jump. Parameters: PatternIndex, PatternStep(W) pattern.offset = _patternOffset[patternPtr[1]]; pattern.step = READ_BE_UINT16(&patternPtr[2]); continue; case 3: // Wait. Paramters: ticks to wait pattern.wait = patternPtr[1]; return false; case 14: // Stop custompattern // TODO ? warnPatternUnimplemented(patternPtr, 1); // FT case 4: // Stop this pattern pattern.command = 0xFF; --pattern.step; // TODO: try figuring out if this was the last Channel? return false; case 5: // Key Up Signal if (!_channelCtx[patternPtr[2] & (kNumVoices - 1)].sfxLocked) _channelCtx[patternPtr[2] & (kNumVoices - 1)].keyUp = true; continue; case 6: // Vibrato case 7: // Envelope noteCommand(pattCmd, patternPtr[1], patternPtr[2], patternPtr[3]); continue; case 8: // Subroutine warnPatternUnimplemented(patternPtr, 0); continue; case 9: // Return from Subroutine warnPatternUnimplemented(patternPtr, 0); continue; case 10: // fade master volume _playerCtx.fadeCount = _playerCtx.fadeSkip = patternPtr[1]; _playerCtx.fadeEndVolume = (int8)patternPtr[3]; if (_playerCtx.fadeSkip) { const int diff = _playerCtx.fadeEndVolume - _playerCtx.volume; _playerCtx.fadeDelta = (diff != 0) ? ((diff > 0) ? 1 : -1) : 0; } else { _playerCtx.volume = _playerCtx.fadeEndVolume; _playerCtx.fadeDelta = 0; } ++_trackCtx.posInd; continue; case 11: { // play pattern. Parameters: patternCmd, channel, expose PatternContext &target = _patternCtx[patternPtr[2] & (kNumChannels - 1)]; target.command = patternPtr[1]; target.offset = _patternOffset[patternPtr[1] & (kMaxPatternOffsets - 1)]; target.expose = patternPtr[3]; target.step = 0; target.wait = 0; target.loopCount = 0xFF; } continue; case 12: // Lock _channelCtx[patternPtr[2] & (kNumVoices - 1)].sfxLocked = (patternPtr[1] != 0); _channelCtx[patternPtr[2] & (kNumVoices - 1)].sfxLockTime = patternPtr[3]; continue; case 13: // Cue if (_playerCtx.signal) _playerCtx.signal[patternPtr[1]] = READ_BE_UINT16(&patternPtr[2]); continue; case 15: // NOP continue; } } } } bool Tfmx::trackRun(const bool incStep) { assert(_playerCtx.song >= 0); if (incStep) { // TODO Optionally disable looping if (_trackCtx.posInd == _trackCtx.stopInd) _trackCtx.posInd = _trackCtx.startInd; else ++_trackCtx.posInd; } for (;;) { const uint16 *const trackData = _resource.getTrackPtr(_trackCtx.posInd); if (trackData[0] != FROM_BE_16(0xEFFE)) { // 8 commands for Patterns for (int i = 0; i < 8; ++i) { const uint patCmd = READ_BE_UINT16(&trackData[i]); // First byte is pattern number const uint patNum = (patCmd >> 8); // if highest bit is set then keep previous pattern if (patNum < 0x80) { _patternCtx[i].step = 0; _patternCtx[i].wait = 0; _patternCtx[i].loopCount = 0xFF; _patternCtx[i].offset = _patternOffset[patNum]; } _patternCtx[i].command = (uint8)patNum; _patternCtx[i].expose = patCmd & 0xFF; } return true; } else { // 16 byte Trackstep Command switch (READ_BE_UINT16(&trackData[1])) { case 0: // Stop Player. No Parameters stopPaula(); return false; case 1: // Branch/Loop section of tracksteps. Parameters: branch target, loopcount if (_trackCtx.loopCount != 0) { if (_trackCtx.loopCount < 0) _trackCtx.loopCount = READ_BE_UINT16(&trackData[3]); _trackCtx.posInd = READ_BE_UINT16(&trackData[2]); continue; } --_trackCtx.loopCount; break; case 2: { // Set Tempo. Parameters: tempo, divisor _playerCtx.patternCount = _playerCtx.patternSkip = READ_BE_UINT16(&trackData[2]); // tempo const uint16 temp = READ_BE_UINT16(&trackData[3]); // divisor if (!(temp & 0x8000) && (temp & 0x1FF)) setInterruptFreqUnscaled(temp & 0x1FF); break; } case 4: // Fade _playerCtx.fadeCount = _playerCtx.fadeSkip = (uint8)READ_BE_UINT16(&trackData[2]); _playerCtx.fadeEndVolume = (int8)READ_BE_UINT16(&trackData[3]); if (_playerCtx.fadeSkip) { const int diff = _playerCtx.fadeEndVolume - _playerCtx.volume; _playerCtx.fadeDelta = (diff != 0) ? ((diff > 0) ? 1 : -1) : 0; } else { _playerCtx.volume = _playerCtx.fadeEndVolume; _playerCtx.fadeDelta = 0; } break; case 3: // Unknown, stops player aswell default: debug("Unknown Command: %02X", READ_BE_UINT16(&trackData[1])); // MI-Player handles this by stopping the player, we just continue } } if (_trackCtx.posInd == _trackCtx.stopInd) { warning("Tfmx: Reached invalid Song-Position"); return false; } ++_trackCtx.posInd; } } void Tfmx::noteCommand(const uint8 note, const uint8 param1, const uint8 param2, const uint8 param3) { ChannelContext &channel = _channelCtx[param2 & (kNumVoices - 1)]; if (note == 0xFC) { // Lock channel.sfxLocked = (param1 != 0); channel.sfxLockTime = param3; // only 1 byte read! return; } if (channel.sfxLocked) return; if (note < 0xC0) { // Play Note channel.prevNote = channel.note; channel.note = note; channel.macroIndex = param1 & (kMaxMacroOffsets - 1); channel.macroOffset = _macroOffset[param1 & (kMaxMacroOffsets - 1)]; channel.relVol = (param2 >> 4) & 0xF; channel.fineTune = (int8)param3; initMacroProgramm(channel); channel.keyUp = false; // key down = playing a Note } else if (note < 0xF0) { // Portamento channel.portaSkip = param1; channel.portaCount = 1; if (!channel.portaDelta) channel.portaValue = channel.refPeriod; channel.portaDelta = param3; channel.note = note & 0x3F; channel.refPeriod = noteIntervalls[channel.note]; } else switch (note & 0xF) { // Command case 5: // Key Up Signal channel.keyUp = true; break; case 6: // Vibratio channel.vibLength = param1 & 0xFE; channel.vibCount = param1 / 2; channel.vibValue = 0; break; case 7: // Envelope channel.envDelta = param1; channel.envSkip = channel.envCount = (param2 >> 4) + 1; channel.envEndVolume = param3; break; } } bool Tfmx::load(Common::SeekableReadStream &musicData, Common::SeekableReadStream &sampleData) { bool res; assert(0 == _resource._mdatData); assert(0 == _resource._sampleData); // TODO: Sanity checks if we have a valid TFMX-Module // TODO: check for Stream-Errors (other than using asserts) // 0x0000: 10 Bytes Header "TFMX-SONG " // 0x000A: int16 ? // 0x000C: int32 ? musicData.read(_resource.header, 10); _resource.headerFlags = musicData.readUint16BE(); _resource.headerUnknown = musicData.readUint32BE(); // This might affect timing // bool isPalModule = (_resource.headerFlags & 2) != 0; // 0x0010: 6*40 Textfield musicData.read(_resource.textField, 6 * 40); /* 0x0100: Songstart x 32*/ for (int i = 0; i < kNumSubsongs; ++i) _subsong[i].songstart = musicData.readUint16BE(); /* 0x0140: Songend x 32*/ for (int i = 0; i < kNumSubsongs; ++i) _subsong[i].songend = musicData.readUint16BE(); /* 0x0180: Tempo x 32*/ for (int i = 0; i < kNumSubsongs; ++i) _subsong[i].tempo = musicData.readUint16BE(); /* 0x01c0: unused ? */ musicData.skip(16); /* 0x01d0: trackstep, pattern data p, macro data p */ uint32 offTrackstep = musicData.readUint32BE(); uint32 offPatternP = musicData.readUint32BE(); uint32 offMacroP = musicData.readUint32BE(); _resource._sfxTableOffset = 0x200; bool getSfxIndex = false; // This is how MI`s TFMX-Player tests for unpacked Modules. if (offTrackstep == 0) { offTrackstep = 0x600 + 0x200; offPatternP = 0x200 + 0x200; offMacroP = 0x400 + 0x200; getSfxIndex = true; _resource._sfxTableOffset = 0x5FC; } _resource._trackstepOffset = offTrackstep; // Read in pattern starting offsets musicData.seek(offPatternP); for (int i = 0; i < kMaxPatternOffsets; ++i) _patternOffset[i] = musicData.readUint32BE(); res = musicData.err(); assert(!res); if (getSfxIndex) _resource._sfxTableOffset = _patternOffset[127]; // Read in macro starting offsets musicData.seek(offMacroP); for (int i = 0; i < kMaxMacroOffsets; ++i) _macroOffset[i] = musicData.readUint32BE(); res = musicData.err(); assert(!res); // Read in whole mdat-file int32 size = musicData.size(); assert(size != -1); // TODO: special routine if size = -1? _resource._mdatData = new byte[size]; assert(_resource._mdatData); _resource._mdatLen = size; musicData.seek(0); musicData.read(_resource._mdatData, size); res = musicData.err(); assert(!res); musicData.readByte(); res = musicData.eos(); assert(res); // TODO: It would be possible to analyze the pointers and be able to // seperate the file in trackstep, patterns and macro blocks // Modules could do weird stuff like having those blocks mixed though. // TODO: Analyze pointers if they are correct offsets, // so that accesses can be unchecked later // Read in whole sample-file size = sampleData.size(); assert(size >= 4); assert(size != -1); // TODO: special routine if size = -1? _resource._sampleData = new byte[size]; assert(_resource._sampleData); _resource._sampleLen = size; sampleData.seek(0); sampleData.read(_resource._sampleData, size); for (int i = 0; i < 4; ++i) _resource._sampleData[i] = 0; res = sampleData.err(); assert(!res); sampleData.readByte(); res = sampleData.eos(); assert(res); return true; } void Tfmx::doMacro(int note, int macro, int relVol, int finetune, int channelNo) { assert(0 <= macro && macro < kMaxMacroOffsets); assert(0 <= note && note < 0xC0); Common::StackLock lock(_mutex); channelNo &= (kNumVoices - 1); ChannelContext &channel = _channelCtx[channelNo]; unlockMacroChannel(channel); noteCommand((uint8)note, (uint8)macro, (uint8)(relVol << 4) | channelNo, (uint8)finetune); startPaula(); } void Tfmx::stopSong(bool stopAudio) { Common::StackLock lock(_mutex); _playerCtx.song = -1; if (stopAudio) { stopMacroChannels(); stopPaula(); } } void Tfmx::doSong(int songPos, bool stopAudio) { assert(0 <= songPos && songPos < kNumSubsongs); Common::StackLock lock(_mutex); stopPatternChannels(); if (stopAudio) { stopMacroChannels(); stopPaula(); } _playerCtx.song = (int8)songPos; _trackCtx.loopCount = -1; _trackCtx.startInd = _trackCtx.posInd = _subsong[songPos].songstart; _trackCtx.stopInd = _subsong[songPos].songend; const bool palFlag = (_resource.headerFlags & 2) != 0; const uint16 tempo = _subsong[songPos].tempo; uint16 ciaIntervall; if (tempo >= 0x10) { ciaIntervall = (uint16)(kCiaBaseInterval / tempo); _playerCtx.patternSkip = 0; } else { ciaIntervall = palFlag ? (uint16)kPalDefaultCiaVal : (uint16)kNtscDefaultCiaVal; _playerCtx.patternSkip = tempo; } setInterruptFreqUnscaled(ciaIntervall); _playerCtx.patternCount = 0; if (trackRun()) startPaula(); } int Tfmx::doSfx(uint16 sfxIndex, bool unlockChannel) { assert(0 <= sfxIndex && sfxIndex < 128); Common::StackLock lock(_mutex); const byte *sfxEntry = _resource.getSfxPtr(sfxIndex); if (sfxEntry[0] == 0xFB) { // custompattern const uint8 patCmd = sfxEntry[2]; const int8 patExp = (int8)sfxEntry[3]; } else { // custommacro const byte channelNo = ((_playerCtx.song >= 0) ? sfxEntry[2] : sfxEntry[4]) & (kNumVoices - 1); const byte priority = sfxEntry[5] & 0x7F; ChannelContext &channel = _channelCtx[channelNo]; if (unlockChannel) unlockMacroChannel(channel); const int16 sfxLocktime = channel.sfxLockTime; if (priority >= channel.customMacroPrio || sfxLocktime < 0) { if (sfxIndex != channel.customMacroIndex || sfxLocktime < 0 || (sfxEntry[5] < 0x80)) { channel.customMacro = READ_UINT32(sfxEntry); // intentionally not "endian-correct" channel.customMacroPrio = priority; channel.customMacroIndex = (uint8)sfxIndex; debug(3, "Tfmx: running Macro %08X on channel %i - priority: %02X", TO_BE_32(channel.customMacro), channelNo, priority); return channelNo; } } } return -1; } }