ref: 8898df42f669d4140fa5404e615bf048356437f6
dir: /src/ft2_replayer.c/
// for finding memory leaks in debug mode with Visual Studio #if defined _DEBUG && defined _MSC_VER #include <crtdbg.h> #endif #include <stdint.h> #include <stdio.h> #include <math.h> #include "ft2_header.h" #include "ft2_config.h" #include "ft2_gui.h" #include "ft2_video.h" #include "ft2_pattern_ed.h" #include "ft2_sample_ed.h" #include "ft2_inst_ed.h" #include "ft2_diskop.h" #include "ft2_midi.h" #include "ft2_scopes.h" #include "ft2_mouse.h" #include "ft2_sample_loader.h" #include "ft2_tables.h" #include "ft2_structs.h" #include "mixer/ft2_windowed_sinc.h" /* This is a mess, directly ported from the original FT2 code (with some modifications). ** You will experience a lot of headaches if you dig into it... ** If something looks to be off, it probably isn't! */ // non-FT2 precalced stuff (these are kinda big...) static double dPeriod2HzTab[65536], dLogTab[768], dExp2MulTab[32], dHz2MixDeltaMul; static uint32_t revMixDeltaTab[65536]; static bool bxxOverflow; static tonTyp nilPatternLine[MAX_VOICES]; typedef void (*volKolEfxRoutine)(stmTyp *ch); typedef void (*volKolEfxRoutine2)(stmTyp *ch, uint8_t *volKol); typedef void (*efxRoutine)(stmTyp *ch, uint8_t param); // globally accessed int8_t playMode = 0; bool songPlaying = false, audioPaused = false, musicPaused = false; volatile bool replayerBusy = false; const uint16_t *note2Period = NULL; int16_t pattLens[MAX_PATTERNS]; stmTyp stm[MAX_VOICES]; songTyp song; instrTyp *instr[132]; tonTyp *patt[MAX_PATTERNS]; // ---------------------------------- void fixSongName(void) // removes spaces from right side of song name { for (int32_t i = 20; i >= 0; i--) { if (song.name[i] == ' ') song.name[i] = '\0'; else break; } } void fixSampleName(int16_t nr) // removes spaces from right side of ins/smp names { for (int32_t i = 21; i >= 0; i--) { if (song.instrName[nr][i] == ' ') song.instrName[nr][i] = '\0'; else break; } if (instr[nr] != NULL) { sampleTyp *s = instr[nr]->samp; for (int32_t i = 0; i < MAX_SMP_PER_INST; i++, s++) { for (int16_t j = 21; j >= 0; j--) { if (s->name[j] == ' ') s->name[j] = '\0'; else break; } s->name[22] = '\0'; // just in case (for tracker, not present in sample header when saving) } } } void resetChannels(void) { const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); memset(stm, 0, sizeof (stm)); stmTyp *ch = stm; for (int32_t i = 0; i < MAX_VOICES; i++, ch++) { ch->instrPtr = instr[0]; ch->status = IS_Vol; ch->oldPan = 128; ch->outPan = 128; ch->finalPan = 128; ch->stOff = !editor.chnMode[i]; // set channel mute flag from global mute flag } if (audioWasntLocked) unlockAudio(); } void setSongModifiedFlag(void) { song.isModified = true; editor.updateWindowTitle = true; } void removeSongModifiedFlag(void) { song.isModified = false; editor.updateWindowTitle = true; } void tuneSample(sampleTyp *s, const int32_t midCFreq) // used on external sample load (not when loading module) { #define NOTE_C4 (4*12) #define MIN_PERIOD (0) #define MAX_PERIOD (((10*12*16)-1)-1) /* -1 (because of bugged amigaPeriods table values) */ if (midCFreq <= 0 || note2Period == NULL) { s->fine = s->relTon = 0; return; } // handle frequency boundaries first... if (midCFreq <= (int32_t)dPeriod2HzTab[note2Period[MIN_PERIOD]]) { s->fine = -128; s->relTon = -48; return; } if (midCFreq >= (int32_t)dPeriod2HzTab[note2Period[MAX_PERIOD]]) { s->fine = 127; s->relTon = 71; return; } // check if midCFreq is matching any of the non-finetuned note frequencies (C-0..B-9) for (int8_t i = 0; i < 10*12; i++) { if (midCFreq == (int32_t)dPeriod2HzTab[note2Period[16 + (i<<4)]]) { s->fine = 0; s->relTon = i - NOTE_C4; return; } } // find closest frequency in period table int32_t period = MAX_PERIOD; for (; period >= MIN_PERIOD; period--) { const int32_t curr = (int32_t)dPeriod2HzTab[note2Period[period]]; if (midCFreq == curr) break; if (midCFreq > curr) { const int32_t next = (int32_t)dPeriod2HzTab[note2Period[period+1]]; const int32_t errorCurr = ABS(curr-midCFreq); const int32_t errorNext = ABS(next-midCFreq); if (errorCurr <= errorNext) break; // current is the closest period++; break; // current+1 is the closest } } s->fine = ((period & 31) - 16) << 3; s->relTon = (int8_t)(((period & ~31) >> 4) - NOTE_C4); } void setPatternLen(uint16_t nr, int16_t len) { assert(nr < MAX_PATTERNS); if ((len < 1 || len > MAX_PATT_LEN) || len == pattLens[nr]) return; const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); pattLens[nr] = len; if (patt[nr] != NULL) killPatternIfUnused(nr); song.pattLen = pattLens[nr]; if (song.pattPos >= song.pattLen) { song.pattPos = song.pattLen - 1; editor.pattPos = song.pattPos; } checkMarkLimits(); if (audioWasntLocked) unlockAudio(); ui.updatePatternEditor = true; ui.updatePosSections = true; } int16_t getUsedSamples(int16_t nr) { if (instr[nr] == NULL) return 0; instrTyp *ins = instr[nr]; int16_t i = 16 - 1; while (i >= 0 && ins->samp[i].pek == NULL && ins->samp[i].name[0] == '\0') i--; /* Yes, 'i' can be -1 here, and will be set to at least 0 ** because of ins->ta values. Possibly an FT2 bug... */ for (int16_t j = 0; j < 96; j++) { if (ins->ta[j] > i) i = ins->ta[j]; } return i+1; } int16_t getRealUsedSamples(int16_t nr) { if (instr[nr] == NULL) return 0; int8_t i = 16 - 1; while (i >= 0 && instr[nr]->samp[i].pek == NULL) i--; return i+1; } static void calcPeriod2HzTable(void) // called every time "linear/amiga frequency" mode is changed { dPeriod2HzTab[0] = 0.0; // in FT2, a period of 0 converts to 0Hz if (audio.linearFreqTable) { // linear periods for (int32_t i = 1; i < 65536; i++) { const uint16_t invPeriod = (12 * 192 * 4) - (uint16_t)i; // this intentionally 16-bit-underflows to be accurate to FT2 const int32_t octave = invPeriod / 768; const int32_t period = invPeriod % 768; dPeriod2HzTab[i] = dLogTab[period] * dExp2MulTab[(14-octave) & 31]; // x = y >> ((14-octave) & 31) } } else { // Amiga periods for (int32_t i = 1; i < 65536; i++) dPeriod2HzTab[i] = (8363.0 * 1712.0) / i; } } /* Called every time "linear/amiga frequency" mode or audio frequency is changed. ** ** Used to replace a DIV with a MUL in the outside audio mixer loop. This can actually ** be beneficial if you are playing VERY tightly looped samples, and/or if the CPU has ** no DIV instruction (certain ARM CPUs, for instance). ** ** A bit hackish and extreme considering it's 65536*4 bytes long, but why not. */ void calcRevMixDeltaTable(void) { for (int32_t i = 0; i < 65536; i++) { const uint16_t period = (uint16_t)i; const uint64_t delta = getMixerDelta(period); uint32_t revDelta = UINT32_MAX; if (delta != 0) revDelta = (uint32_t)((UINT64_MAX / delta) >> 16); // MUST be truncated, not rounded! revMixDeltaTab[i] = revDelta; } } // returns *exact* FT2 C-4 voice rate (depending on finetune, relative note and Amiga/linear mode) double getSampleC4Rate(sampleTyp *s) { int32_t note = (96/2) + s->relTon; if (note >= (10*12)-1) return -1; // B-9 (from relTon) = illegal! (won't play in replayer) const int32_t C4Period = (note << 4) + (((int8_t)s->fine >> 3) + 16); const uint16_t period = audio.linearFreqTable ? linearPeriods[C4Period] : amigaPeriods[C4Period]; return dPeriod2Hz(period); } void setFrqTab(bool linear) { pauseAudio(); audio.linearFreqTable = linear; if (audio.linearFreqTable) note2Period = linearPeriods; else note2Period = amigaPeriods; calcPeriod2HzTable(); calcRevMixDeltaTable(); resumeAudio(); // update "frequency table" radiobutton, if it's shown if (ui.configScreenShown && editor.currConfigScreen == CONFIG_SCREEN_IO_DEVICES) { setConfigIORadioButtonStates(); if (ui.instEditorShown) drawC4Rate(); } } static void retrigVolume(stmTyp *ch) { ch->realVol = ch->oldVol; ch->outVol = ch->oldVol; ch->outPan = ch->oldPan; ch->status |= IS_Vol + IS_Pan + IS_QuickVol; } static void retrigEnvelopeVibrato(stmTyp *ch) { if (!(ch->waveCtrl & 0x04)) ch->vibPos = 0; if (!(ch->waveCtrl & 0x40)) ch->tremPos = 0; ch->retrigCnt = 0; ch->tremorPos = 0; ch->envSustainActive = true; instrTyp *ins = ch->instrPtr; assert(ins != NULL); if (ins->envVTyp & 1) { ch->envVCnt = 65535; ch->envVPos = 0; } if (ins->envPTyp & 1) { ch->envPCnt = 65535; ch->envPPos = 0; } ch->fadeOutSpeed = ins->fadeOut; // FT2 doesn't check if fadeout is more than 4095 ch->fadeOutAmp = 32768; if (ins->vibDepth > 0) { ch->eVibPos = 0; if (ins->vibSweep > 0) { ch->eVibAmp = 0; ch->eVibSweep = (ins->vibDepth << 8) / ins->vibSweep; } else { ch->eVibAmp = ins->vibDepth << 8; ch->eVibSweep = 0; } } } void keyOff(stmTyp *ch) { ch->envSustainActive = false; instrTyp *ins = ch->instrPtr; assert(ins != NULL); if (!(ins->envPTyp & 1)) // yes, FT2 does this (!). Most likely a bug? { if (ch->envPCnt >= (uint16_t)ins->envPP[ch->envPPos][0]) ch->envPCnt = ins->envPP[ch->envPPos][0] - 1; } if (ins->envVTyp & 1) { if (ch->envVCnt >= (uint16_t)ins->envVP[ch->envVPos][0]) ch->envVCnt = ins->envVP[ch->envVPos][0] - 1; } else { ch->realVol = 0; ch->outVol = 0; ch->status |= IS_Vol + IS_QuickVol; } } void calcReplayerLogTab(void) { for (int32_t i = 0; i < 32; i++) dExp2MulTab[i] = 1.0 / exp2(i); // 1/2^i for (int32_t i = 0; i < 768; i++) dLogTab[i] = 8363.0 * 256.0 * exp2(i * (1.0 / 768.0)); } void calcReplayerVars(int32_t audioFreq) { assert(audioFreq > 0); if (audioFreq <= 0) return; dHz2MixDeltaMul = (double)MIXER_FRAC_SCALE / audioFreq; audio.quickVolRampSamples = (int32_t)((audioFreq / 200.0) + 0.5); // rounded audio.dRampQuickVolMul = 1.0 / audio.quickVolRampSamples; audio.dSamplesPerTickTab[0] = 0.0; audio.tickTimeTab[0] = UINT64_MAX; audio.dRampTickMulTab[0] = 0.0; for (int32_t i = MIN_BPM; i <= MAX_BPM; i++) { const double dBpmHz = i * (1.0 / 2.5); // i / 2.5 const double dSamplesPerTick = audioFreq / dBpmHz; audio.dSamplesPerTickTab[i] = dSamplesPerTick; // BPM Hz -> tick length for performance counter (syncing visuals to audio) double dTimeInt; double dTimeFrac = modf(editor.dPerfFreq / dBpmHz, &dTimeInt); const int32_t timeInt = (int32_t)dTimeInt; dTimeFrac = floor((UINT32_MAX+1.0) * dTimeFrac); // fractional part (scaled to 0..2^32-1) audio.tickTimeTab[i] = ((uint64_t)timeInt << 32) | (uint32_t)dTimeFrac; // for calculating volume ramp length for tick-lenghted ramps const int32_t samplesPerTick = (int32_t)(dSamplesPerTick + 0.5); // this has to be rounded first audio.dRampTickMulTab[i] = 1.0 / samplesPerTick; } } double dPeriod2Hz(uint16_t period) { return dPeriod2HzTab[period]; } int64_t getMixerDelta(uint16_t period) { /* Precision has been tested for most extreme case (Amiga period 1, 44100Hz), ** and there is no precision loss using 64-bit double-precision here, even ** though we can get VERY big numbers. */ return (int64_t)((dPeriod2Hz(period) * dHz2MixDeltaMul) + 0.5); // Hz -> rounded 32.32 fixed-point mixer delta } // used for calculating the max safe amount of samples to mix before entering inner mix loop uint32_t getRevMixerDelta(uint16_t period) { return revMixDeltaTab[period]; } int32_t getPianoKey(uint16_t period, int8_t finetune, int8_t relativeNote) // for piano in Instr. Ed. { if (period > note2Period[0]) // don't show periods below C-0 (w/ lowest finetune) on piano return -1; finetune = ((int8_t)finetune >> 3) + 16; // this is not 100% accurate for all periods, but should be faster than using log2() and floating-point arithmetics int32_t hiPeriod = (10*12*16)+16; int32_t loPeriod = 0; for (int32_t i = 0; i < 7; i++) { const int32_t tmpPeriod = (((loPeriod + hiPeriod) >> 1) & ~15) + finetune; int32_t lookUp = tmpPeriod - 8; if (lookUp < 0) lookUp = 0; if (period >= note2Period[lookUp]) hiPeriod = (tmpPeriod - finetune) & ~15; else loPeriod = (tmpPeriod - finetune) & ~15; } int32_t note = loPeriod; note >>= 4; note -= relativeNote; return note; } static void startTone(uint8_t ton, uint8_t effTyp, uint8_t eff, stmTyp *ch) { if (ton == 97) { keyOff(ch); return; } // if we came from Rxy (retrig), we didn't check note (Ton) yet if (ton == 0) { ton = ch->tonNr; if (ton == 0) return; // if still no note, exit from routine } ch->tonNr = ton; assert(ch->instrNr <= 130); instrTyp *ins = instr[ch->instrNr]; if (ins == NULL) ins = instr[0]; // empty instruments use this placeholder instrument ch->instrPtr = ins; ch->mute = ins->mute; if (ton > 96) // non-FT2 security (should never happen because I clamp in the patt. loader now) ton = 96; const uint8_t smp = ins->ta[ton-1] & 0xF; ch->sampleNr = smp; sampleTyp *s = &ins->samp[smp]; ch->smpPtr = s; ch->relTonNr = s->relTon; ton += ch->relTonNr; if (ton >= 10*12) return; ch->oldVol = s->vol; ch->oldPan = s->pan; if (effTyp == 0x0E && (eff & 0xF0) == 0x50) ch->fineTune = ((eff & 0x0F) << 4) - 128; // result is now -128..127 else ch->fineTune = s->fine; if (ton != 0) { const uint16_t tmpTon = ((ton-1) << 4) + (((int8_t)ch->fineTune >> 3) + 16); if (tmpTon < MAX_NOTES) { assert(note2Period != NULL); ch->outPeriod = ch->realPeriod = note2Period[tmpTon]; } } ch->status |= IS_Period + IS_Vol + IS_Pan + IS_NyTon + IS_QuickVol; if (effTyp == 9) { if (eff) ch->smpOffset = ch->eff; ch->smpStartPos = ch->smpOffset << 8; } else { ch->smpStartPos = 0; } } static void volume(stmTyp *ch, uint8_t param); // volume slide static void vibrato2(stmTyp *ch); static void tonePorta(stmTyp *ch, uint8_t param); static void dummy(stmTyp *ch, uint8_t param) { (void)ch; (void)param; return; } static void finePortaUp(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->fPortaUpSpeed; ch->fPortaUpSpeed = param; ch->realPeriod -= param << 2; if ((int16_t)ch->realPeriod < 1) ch->realPeriod = 1; ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } static void finePortaDown(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->fPortaDownSpeed; ch->fPortaDownSpeed = param; ch->realPeriod += param << 2; if ((int16_t)ch->realPeriod > MAX_FRQ-1) // FT2 bug, should've been unsigned comparison ch->realPeriod = MAX_FRQ-1; ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } static void setGlissCtrl(stmTyp *ch, uint8_t param) { ch->glissFunk = param; } static void setVibratoCtrl(stmTyp *ch, uint8_t param) { ch->waveCtrl = (ch->waveCtrl & 0xF0) | param; } static void jumpLoop(stmTyp *ch, uint8_t param) { if (param == 0) { ch->pattPos = song.pattPos & 0xFF; } else if (ch->loopCnt == 0) { ch->loopCnt = param; song.pBreakPos = ch->pattPos; song.pBreakFlag = true; } else if (--ch->loopCnt > 0) { song.pBreakPos = ch->pattPos; song.pBreakFlag = true; } } static void setTremoloCtrl(stmTyp *ch, uint8_t param) { ch->waveCtrl = (param << 4) | (ch->waveCtrl & 0x0F); } static void volFineUp(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->fVolSlideUpSpeed; ch->fVolSlideUpSpeed = param; ch->realVol += param; if (ch->realVol > 64) ch->realVol = 64; ch->outVol = ch->realVol; ch->status |= IS_Vol; } static void volFineDown(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->fVolSlideDownSpeed; ch->fVolSlideDownSpeed = param; ch->realVol -= param; if ((int8_t)ch->realVol < 0) ch->realVol = 0; ch->outVol = ch->realVol; ch->status |= IS_Vol; } static void noteCut0(stmTyp *ch, uint8_t param) { if (param == 0) // only a parameter of zero is handled here { ch->realVol = 0; ch->outVol = 0; ch->status |= IS_Vol + IS_QuickVol; } } static void pattDelay(stmTyp *ch, uint8_t param) { if (song.pattDelTime2 == 0) song.pattDelTime = param + 1; (void)ch; } static const efxRoutine EJumpTab_TickZero[16] = { dummy, // 0 finePortaUp, // 1 finePortaDown, // 2 setGlissCtrl, // 3 setVibratoCtrl, // 4 dummy, // 5 jumpLoop, // 6 setTremoloCtrl, // 7 dummy, // 8 dummy, // 9 volFineUp, // A volFineDown, // B noteCut0, // C dummy, // D pattDelay, // E dummy // F }; static void E_Effects_TickZero(stmTyp *ch, uint8_t param) { const uint8_t efx = param >> 4; param &= 0x0F; if (ch->stOff) // channel is muted, only handle some E effects { if (efx == 0x6) jumpLoop(ch, param); else if (efx == 0xE) pattDelay(ch, param); return; } EJumpTab_TickZero[efx](ch, param); } static void posJump(stmTyp *ch, uint8_t param) { if (playMode != PLAYMODE_PATT && playMode != PLAYMODE_RECPATT) { const int16_t pos = (int16_t)param - 1; if (pos < 0 || pos >= song.len) bxxOverflow = true; // non-FT2 security fix... else song.songPos = pos; } song.pBreakPos = 0; song.posJumpFlag = true; (void)ch; } static void pattBreak(stmTyp *ch, uint8_t param) { song.posJumpFlag = true; param = ((param >> 4) * 10) + (param & 0x0F); if (param <= 63) song.pBreakPos = param; else song.pBreakPos = 0; (void)ch; } static void setSpeed(stmTyp *ch, uint8_t param) { if (param >= 32) { song.speed = param; P_SetSpeed(song.speed); } else { song.timer = song.tempo = param; } (void)ch; } static void setGlobaVol(stmTyp *ch, uint8_t param) { if (param > 64) param = 64; song.globVol = param; stmTyp *c = stm; for (int32_t i = 0; i < song.antChn; i++, c++) // update all voice volumes c->status |= IS_Vol; (void)ch; } static void setEnvelopePos(stmTyp *ch, uint8_t param) { bool envUpdate; int8_t point; int16_t tick; instrTyp *ins = ch->instrPtr; assert(ins != NULL); // *** VOLUME ENVELOPE *** if (ins->envVTyp & 1) { ch->envVCnt = param-1; point = 0; envUpdate = true; tick = param; if (ins->envVPAnt > 1) { point++; for (int32_t i = 0; i < ins->envVPAnt-1; i++) { if (tick < ins->envVP[point][0]) { point--; tick -= ins->envVP[point][0]; if (tick == 0) { envUpdate = false; break; } if (ins->envVP[point+1][0] <= ins->envVP[point][0]) { envUpdate = true; break; } ch->envVIPValue = ((ins->envVP[point+1][1] - ins->envVP[point][1]) << 16) / (ins->envVP[point+1][0] - ins->envVP[point][0]); ch->envVAmp = (ch->envVIPValue * (tick-1)) + (ins->envVP[point][1] << 16); point++; envUpdate = false; break; } point++; } if (envUpdate) point--; } if (envUpdate) { ch->envVIPValue = 0; ch->envVAmp = ins->envVP[point][1]; } if (point >= ins->envVPAnt) { point = ins->envVPAnt-1; if (point < 0) point = 0; } ch->envVPos = point; } // *** PANNING ENVELOPE *** if (ins->envVTyp & 2) // probably an FT2 bug { ch->envPCnt = param-1; point = 0; envUpdate = true; tick = param; if (ins->envPPAnt > 1) { point++; for (int32_t i = 0; i < ins->envPPAnt-1; i++) { if (tick < ins->envPP[point][0]) { point--; tick -= ins->envPP[point][0]; if (tick == 0) { envUpdate = false; break; } if (ins->envPP[point+1][0] <= ins->envPP[point][0]) { envUpdate = true; break; } ch->envPIPValue = ((ins->envPP[point+1][1] - ins->envPP[point][1]) << 16) / (ins->envPP[point+1][0] - ins->envPP[point][0]); ch->envPAmp = (ch->envPIPValue * (tick-1)) + (ins->envPP[point][1] << 16); point++; envUpdate = false; break; } point++; } if (envUpdate) point--; } if (envUpdate) { ch->envPIPValue = 0; ch->envPAmp = ins->envPP[point][1]; } if (point >= ins->envPPAnt) { point = ins->envPPAnt-1; if (point < 0) point = 0; } ch->envPPos = point; } } static const efxRoutine JumpTab_TickZero[36] = { dummy, // 0 dummy, // 1 dummy, // 2 dummy, // 3 dummy, // 4 dummy, // 5 dummy, // 6 dummy, // 7 dummy, // 8 dummy, // 9 dummy, // A posJump, // B dummy, // C pattBreak, // D E_Effects_TickZero, // E setSpeed, // F setGlobaVol, // G dummy, // H dummy, // I dummy, // J dummy, // K setEnvelopePos, // L dummy, // M dummy, // N dummy, // O dummy, // P dummy, // Q dummy, // R dummy, // S dummy, // T dummy, // U dummy, // V dummy, // W dummy, // X dummy, // Y dummy // Z }; static void handleMoreEffects_TickZero(stmTyp *ch) // called even if channel is muted { if (ch->effTyp > 35) return; JumpTab_TickZero[ch->effTyp](ch, ch->eff); } /* -- tick-zero volume column effects -- ** 2nd parameter is used for a volume column quirk with the Rxy command (multiretrig) */ static void v_SetVibSpeed(stmTyp *ch, uint8_t *volKol) { *volKol = (ch->volKolVol & 0x0F) << 2; if (*volKol != 0) ch->vibSpeed = *volKol; } static void v_Volume(stmTyp *ch, uint8_t *volKol) { *volKol -= 16; if (*volKol > 64) // no idea why FT2 has this check... *volKol = 64; ch->outVol = ch->realVol = *volKol; ch->status |= IS_Vol + IS_QuickVol; } static void v_FineSlideDown(stmTyp *ch, uint8_t *volKol) { *volKol = (uint8_t)(0 - (ch->volKolVol & 0x0F)) + ch->realVol; if ((int8_t)*volKol < 0) *volKol = 0; ch->outVol = ch->realVol = *volKol; ch->status |= IS_Vol; } static void v_FineSlideUp(stmTyp *ch, uint8_t *volKol) { *volKol = (ch->volKolVol & 0x0F) + ch->realVol; if (*volKol > 64) *volKol = 64; ch->outVol = ch->realVol = *volKol; ch->status |= IS_Vol; } static void v_SetPan(stmTyp *ch, uint8_t *volKol) { *volKol <<= 4; ch->outPan = *volKol; ch->status |= IS_Pan; } // -- non-tick-zero volume column effects -- static void v_SlideDown(stmTyp *ch) { uint8_t newVol = (uint8_t)(0 - (ch->volKolVol & 0x0F)) + ch->realVol; if ((int8_t)newVol < 0) newVol = 0; ch->outVol = ch->realVol = newVol; ch->status |= IS_Vol; } static void v_SlideUp(stmTyp *ch) { uint8_t newVol = (ch->volKolVol & 0x0F) + ch->realVol; if (newVol > 64) newVol = 64; ch->outVol = ch->realVol = newVol; ch->status |= IS_Vol; } static void v_Vibrato(stmTyp *ch) { const uint8_t param = ch->volKolVol & 0xF; if (param > 0) ch->vibDepth = param; vibrato2(ch); } static void v_PanSlideLeft(stmTyp *ch) { uint16_t tmp16 = (uint8_t)(0 - (ch->volKolVol & 0x0F)) + ch->outPan; if (tmp16 < 256) // includes an FT2 bug: pan-slide-left of 0 = set pan to 0 tmp16 = 0; ch->outPan = (uint8_t)tmp16; ch->status |= IS_Pan; } static void v_PanSlideRight(stmTyp *ch) { uint16_t tmp16 = (ch->volKolVol & 0x0F) + ch->outPan; if (tmp16 > 255) tmp16 = 255; ch->outPan = (uint8_t)tmp16; ch->status |= IS_Pan; } static void v_TonePorta(stmTyp *ch) { tonePorta(ch, 0); // the last parameter is actually not used in tonePorta() } static void v_dummy(stmTyp *ch) { (void)ch; return; } static void v_dummy2(stmTyp *ch, uint8_t *volKol) { (void)ch; (void)volKol; return; } static const volKolEfxRoutine VJumpTab_TickNonZero[16] = { v_dummy, v_dummy, v_dummy, v_dummy, v_dummy, v_dummy, v_SlideDown, v_SlideUp, v_dummy, v_dummy, v_dummy, v_Vibrato, v_dummy, v_PanSlideLeft, v_PanSlideRight, v_TonePorta }; static const volKolEfxRoutine2 VJumpTab_TickZero[16] = { v_dummy2, v_Volume, v_Volume, v_Volume, v_Volume, v_Volume, v_dummy2, v_dummy2, v_FineSlideDown, v_FineSlideUp, v_SetVibSpeed, v_dummy2, v_SetPan, v_dummy2, v_dummy2, v_dummy2 }; static void setPan(stmTyp *ch, uint8_t param) { ch->outPan = param; ch->status |= IS_Pan; } static void setVol(stmTyp *ch, uint8_t param) { if (param > 64) param = 64; ch->outVol = ch->realVol = param; ch->status |= IS_Vol + IS_QuickVol; } static void xFinePorta(stmTyp *ch, uint8_t param) { const uint8_t type = param >> 4; param &= 0x0F; if (type == 0x1) // extra fine porta up { if (param == 0) param = ch->ePortaUpSpeed; ch->ePortaUpSpeed = param; uint16_t newPeriod = ch->realPeriod; newPeriod -= param; if ((int16_t)newPeriod < 1) newPeriod = 1; ch->outPeriod = ch->realPeriod = newPeriod; ch->status |= IS_Period; } else if (type == 0x2) // extra fine porta down { if (param == 0) param = ch->ePortaDownSpeed; ch->ePortaDownSpeed = param; uint16_t newPeriod = ch->realPeriod; newPeriod += param; if ((int16_t)newPeriod > MAX_FRQ-1) // FT2 bug, should've been unsigned comparison newPeriod = MAX_FRQ-1; ch->outPeriod = ch->realPeriod = newPeriod; ch->status |= IS_Period; } } static void doMultiRetrig(stmTyp *ch, uint8_t param) // "param" is never used (needed for efx jumptable structure) { uint8_t cnt = ch->retrigCnt + 1; if (cnt < ch->retrigSpeed) { ch->retrigCnt = cnt; return; } ch->retrigCnt = 0; int16_t vol = ch->realVol; switch (ch->retrigVol) { case 0x1: vol -= 1; break; case 0x2: vol -= 2; break; case 0x3: vol -= 4; break; case 0x4: vol -= 8; break; case 0x5: vol -= 16; break; case 0x6: vol = (vol >> 1) + (vol >> 3) + (vol >> 4); break; case 0x7: vol >>= 1; break; case 0x8: break; // does not change the volume case 0x9: vol += 1; break; case 0xA: vol += 2; break; case 0xB: vol += 4; break; case 0xC: vol += 8; break; case 0xD: vol += 16; break; case 0xE: vol = (vol >> 1) + vol; break; case 0xF: vol += vol; break; default: break; } vol = CLAMP(vol, 0, 64); ch->realVol = (uint8_t)vol; ch->outVol = ch->realVol; if (ch->volKolVol >= 0x10 && ch->volKolVol <= 0x50) { ch->outVol = ch->volKolVol - 0x10; ch->realVol = ch->outVol; } else if (ch->volKolVol >= 0xC0 && ch->volKolVol <= 0xCF) { ch->outPan = (ch->volKolVol & 0x0F) << 4; } startTone(0, 0, 0, ch); (void)param; } static void multiRetrig(stmTyp *ch, uint8_t param, uint8_t volumeColumnData) { uint8_t tmpParam; tmpParam = param & 0x0F; if (tmpParam == 0) tmpParam = ch->retrigSpeed; ch->retrigSpeed = tmpParam; tmpParam = param >> 4; if (tmpParam == 0) tmpParam = ch->retrigVol; ch->retrigVol = tmpParam; if (volumeColumnData == 0) doMultiRetrig(ch, 0); // the second parameter is never used (needed for efx jumptable structure) } static void handleEffects_TickZero(stmTyp *ch) { // volume column effects uint8_t newVolKol = ch->volKolVol; // manipulated by vol. column effects, then used for multiretrig check (FT2 quirk) VJumpTab_TickZero[ch->volKolVol >> 4](ch, &newVolKol); // normal effects const uint8_t param = ch->eff; if (ch->effTyp == 0 && param == 0) return; // no effect if (ch->effTyp == 8) setPan(ch, param); else if (ch->effTyp == 12) setVol(ch, param); else if (ch->effTyp == 27) multiRetrig(ch, param, newVolKol); else if (ch->effTyp == 33) xFinePorta(ch, param); handleMoreEffects_TickZero(ch); } static void fixTonePorta(stmTyp *ch, const tonTyp *p, uint8_t inst) { if (p->ton > 0) { if (p->ton == 97) { keyOff(ch); } else { const uint16_t note = (((p->ton-1) + ch->relTonNr) << 4) + (((int8_t)ch->fineTune >> 3) + 16); if (note < MAX_NOTES) { assert(note2Period != NULL); ch->wantPeriod = note2Period[note]; if (ch->wantPeriod == ch->realPeriod) ch->portaDir = 0; else if (ch->wantPeriod > ch->realPeriod) ch->portaDir = 1; else ch->portaDir = 2; } } } if (inst > 0) { retrigVolume(ch); if (p->ton != 97) retrigEnvelopeVibrato(ch); } } static void getNewNote(stmTyp *ch, const tonTyp *p) { ch->volKolVol = p->vol; if (ch->effTyp == 0) { if (ch->eff > 0) // we have an arpeggio running, set period back { ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } } else { // if we have a vibrato on previous row (ch) that ends at current row (p), set period back if ((ch->effTyp == 4 || ch->effTyp == 6) && (p->effTyp != 4 && p->effTyp != 6)) { ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } } ch->effTyp = p->effTyp; ch->eff = p->eff; ch->tonTyp = (p->instr << 8) | p->ton; if (ch->stOff) // channel is muted, only handle some effects { handleMoreEffects_TickZero(ch); return; } // 'inst' var is used for later if checks... uint8_t inst = p->instr; if (inst > 0) { if (inst <= MAX_INST) ch->instrNr = inst; else inst = 0; } bool checkEfx = true; if (p->effTyp == 0x0E) { if (p->eff >= 0xD1 && p->eff <= 0xDF) return; // we have a note delay (ED1..EDF) else if (p->eff == 0x90) checkEfx = false; } if (checkEfx) { if ((ch->volKolVol & 0xF0) == 0xF0) // gxx { const uint8_t volKolParam = ch->volKolVol & 0x0F; if (volKolParam > 0) ch->portaSpeed = volKolParam << 6; fixTonePorta(ch, p, inst); handleEffects_TickZero(ch); return; } if (p->effTyp == 3 || p->effTyp == 5) // 3xx or 5xx { if (p->effTyp != 5 && p->eff != 0) ch->portaSpeed = p->eff << 2; fixTonePorta(ch, p, inst); handleEffects_TickZero(ch); return; } if (p->effTyp == 0x14 && p->eff == 0) // K00 (KeyOff - only handle tick 0 here) { keyOff(ch); if (inst) retrigVolume(ch); handleEffects_TickZero(ch); return; } if (p->ton == 0) { if (inst > 0) { retrigVolume(ch); retrigEnvelopeVibrato(ch); } handleEffects_TickZero(ch); return; } } if (p->ton == 97) keyOff(ch); else startTone(p->ton, p->effTyp, p->eff, ch); if (inst > 0) { retrigVolume(ch); if (p->ton != 97) retrigEnvelopeVibrato(ch); } handleEffects_TickZero(ch); } static void fixaEnvelopeVibrato(stmTyp *ch) { bool envInterpolateFlag, envDidInterpolate; uint8_t envPos; int16_t autoVibVal; uint16_t autoVibAmp; int32_t envVal; double dVol; instrTyp *ins = ch->instrPtr; assert(ins != NULL); // *** FADEOUT *** if (!ch->envSustainActive) { ch->status |= IS_Vol; // unsigned clamp + reset if (ch->fadeOutAmp >= ch->fadeOutSpeed) { ch->fadeOutAmp -= ch->fadeOutSpeed; } else { ch->fadeOutAmp = 0; ch->fadeOutSpeed = 0; } } if (!ch->mute) { // *** VOLUME ENVELOPE *** envVal = 0; if (ins->envVTyp & 1) { envDidInterpolate = false; envPos = ch->envVPos; if (++ch->envVCnt == ins->envVP[envPos][0]) { ch->envVAmp = ins->envVP[envPos][1] << 16; envPos++; if (ins->envVTyp & 4) { envPos--; if (envPos == ins->envVRepE) { if (!(ins->envVTyp & 2) || envPos != ins->envVSust || ch->envSustainActive) { envPos = ins->envVRepS; ch->envVCnt = ins->envVP[envPos][0]; ch->envVAmp = ins->envVP[envPos][1] << 16; } } envPos++; } if (envPos < ins->envVPAnt) { envInterpolateFlag = true; if ((ins->envVTyp & 2) && ch->envSustainActive) { if (envPos-1 == ins->envVSust) { envPos--; ch->envVIPValue = 0; envInterpolateFlag = false; } } if (envInterpolateFlag) { ch->envVPos = envPos; ch->envVIPValue = 0; if (ins->envVP[envPos][0] > ins->envVP[envPos-1][0]) { ch->envVIPValue = ((ins->envVP[envPos][1] - ins->envVP[envPos-1][1]) << 16) / (ins->envVP[envPos][0] - ins->envVP[envPos-1][0]); envVal = ch->envVAmp; envDidInterpolate = true; } } } else { ch->envVIPValue = 0; } } if (!envDidInterpolate) { ch->envVAmp += ch->envVIPValue; envVal = ch->envVAmp; if (envVal > 64<<16) { if (envVal > 128<<16) envVal = 64<<16; else envVal = 0; ch->envVIPValue = 0; } } const int32_t vol = song.globVol * ch->outVol * ch->fadeOutAmp; dVol = vol * (1.0 / (64.0 * 64.0 * 32768.0)); dVol *= (int32_t)envVal * (1.0 / (64.0 * (1 << 16))); ch->status |= IS_Vol; // update vol every tick because vol envelope is enabled } else { const int32_t vol = song.globVol * ch->outVol * ch->fadeOutAmp; dVol = vol * (1.0 / (64.0 * 64.0 * 32768.0)); } if (dVol > 1.0) // shouldn't happen, but just in case... dVol = 1.0; ch->dFinalVol = dVol; } else { ch->dFinalVol = 0.0; } // *** PANNING ENVELOPE *** envVal = 0; if (ins->envPTyp & 1) { envDidInterpolate = false; envPos = ch->envPPos; if (++ch->envPCnt == ins->envPP[envPos][0]) { ch->envPAmp = ins->envPP[envPos][1] << 16; envPos++; if (ins->envPTyp & 4) { envPos--; if (envPos == ins->envPRepE) { if (!(ins->envPTyp & 2) || envPos != ins->envPSust || ch->envSustainActive) { envPos = ins->envPRepS; ch->envPCnt = ins->envPP[envPos][0]; ch->envPAmp = ins->envPP[envPos][1] << 16; } } envPos++; } if (envPos < ins->envPPAnt) { envInterpolateFlag = true; if ((ins->envPTyp & 2) && ch->envSustainActive) { if (envPos-1 == ins->envPSust) { envPos--; ch->envPIPValue = 0; envInterpolateFlag = false; } } if (envInterpolateFlag) { ch->envPPos = envPos; ch->envPIPValue = 0; if (ins->envPP[envPos][0] > ins->envPP[envPos-1][0]) { ch->envPIPValue = ((ins->envPP[envPos][1] - ins->envPP[envPos-1][1]) << 16) / (ins->envPP[envPos][0] - ins->envPP[envPos-1][0]); envVal = ch->envPAmp; envDidInterpolate = true; } } } else { ch->envPIPValue = 0; } } if (!envDidInterpolate) { ch->envPAmp += ch->envPIPValue; envVal = ch->envPAmp; if (envVal > 64<<16) { if (envVal > 128<<16) envVal = 64<<16; else envVal = 0; ch->envPIPValue = 0; } } envVal -= 32<<16; // center panning envelope value const int32_t pan = 128 - ABS(ch->outPan-128); const int32_t panAdd = (pan * envVal) >> (16+5); ch->finalPan = (uint8_t)CLAMP(ch->outPan + panAdd, 0, 255); ch->status |= IS_Pan; // update pan every tick because pan envelope is enabled } else { ch->finalPan = ch->outPan; } // *** AUTO VIBRATO *** #ifdef HAS_MIDI if (ch->midiVibDepth > 0 || ins->vibDepth > 0) #else if (ins->vibDepth > 0) #endif { if (ch->eVibSweep > 0) { autoVibAmp = ch->eVibSweep; if (ch->envSustainActive) { autoVibAmp += ch->eVibAmp; if ((autoVibAmp >> 8) > ins->vibDepth) { autoVibAmp = ins->vibDepth << 8; ch->eVibSweep = 0; } ch->eVibAmp = autoVibAmp; } } else { autoVibAmp = ch->eVibAmp; } #ifdef HAS_MIDI // non-FT2 hack to make modulation wheel work when auto vibrato rate is zero if (ch->midiVibDepth > 0 && ins->vibRate == 0) ins->vibRate = 0x20; autoVibAmp += ch->midiVibDepth; #endif ch->eVibPos += ins->vibRate; if (ins->vibTyp == 1) autoVibVal = (ch->eVibPos > 127) ? 64 : -64; // square else if (ins->vibTyp == 2) autoVibVal = (((ch->eVibPos >> 1) + 64) & 127) - 64; // ramp up else if (ins->vibTyp == 3) autoVibVal = ((-(ch->eVibPos >> 1) + 64) & 127) - 64; // ramp down else autoVibVal = vibSineTab[ch->eVibPos]; // sine autoVibVal <<= 2; uint16_t tmpPeriod = (autoVibVal * (int16_t)autoVibAmp) >> 16; tmpPeriod += ch->outPeriod; if (tmpPeriod > MAX_FRQ-1) tmpPeriod = 0; // yes, FT2 does this (!) #ifdef HAS_MIDI if (midi.enable) tmpPeriod -= ch->midiPitch; #endif ch->finalPeriod = tmpPeriod; ch->status |= IS_Period; } else { ch->finalPeriod = ch->outPeriod; #ifdef HAS_MIDI if (midi.enable) { ch->finalPeriod -= ch->midiPitch; ch->status |= IS_Period; } #endif } } // for arpeggio and portamento (semitone-slide mode) static uint16_t relocateTon(uint16_t period, uint8_t arpNote, stmTyp *ch) { int32_t tmpPeriod; const int32_t fineTune = ((int8_t)ch->fineTune >> 3) + 16; /* FT2 bug, should've been 10*12*16. Notes above B-7 (95) will have issues. ** You can only achieve such high notes by having a high relative note setting. */ int32_t hiPeriod = 8*12*16; int32_t loPeriod = 0; for (int32_t i = 0; i < 8; i++) { tmpPeriod = (((loPeriod + hiPeriod) >> 1) & ~15) + fineTune; int32_t lookUp = tmpPeriod - 8; if (lookUp < 0) lookUp = 0; // safety fix (C-0 w/ finetune <= -65). This buggy read seems to return 0 in FT2 (TODO: Verify...) if (period >= note2Period[lookUp]) hiPeriod = (tmpPeriod - fineTune) & ~15; else loPeriod = (tmpPeriod - fineTune) & ~15; } tmpPeriod = loPeriod + fineTune + (arpNote << 4); if (tmpPeriod >= (8*12*16+15)-1) // FT2 bug, should've been 10*12*16+16 (also notice the +2 difference) tmpPeriod = (8*12*16+16)-1; return note2Period[tmpPeriod]; } static void vibrato2(stmTyp *ch) { uint8_t tmpVib = (ch->vibPos >> 2) & 0x1F; switch (ch->waveCtrl & 3) { // 0: sine case 0: tmpVib = vibTab[tmpVib]; break; // 1: ramp case 1: { tmpVib <<= 3; if ((int8_t)ch->vibPos < 0) tmpVib = ~tmpVib; } break; // 2/3: square default: tmpVib = 255; break; } tmpVib = (tmpVib * ch->vibDepth) >> 5; // logical shift (unsigned calc.), not arithmetic shift if ((int8_t)ch->vibPos < 0) ch->outPeriod = ch->realPeriod - tmpVib; else ch->outPeriod = ch->realPeriod + tmpVib; ch->status |= IS_Period; ch->vibPos += ch->vibSpeed; } static void arp(stmTyp *ch, uint8_t param) { uint8_t note; const uint8_t tick = arpTab[song.timer & 0xFF]; // non-FT2 protection (we have 248 extra overflow bytes in LUT, but not more!) if (tick == 0) { ch->outPeriod = ch->realPeriod; } else { if (tick == 1) note = param >> 4; else note = param & 0x0F; // tick 2 ch->outPeriod = relocateTon(ch->realPeriod, note, ch); } ch->status |= IS_Period; } static void portaUp(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->portaUpSpeed; ch->portaUpSpeed = param; ch->realPeriod -= param << 2; if ((int16_t)ch->realPeriod < 1) ch->realPeriod = 1; ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } static void portaDown(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->portaDownSpeed; ch->portaDownSpeed = param; ch->realPeriod += param << 2; if ((int16_t)ch->realPeriod > MAX_FRQ-1) // FT2 bug, should've been unsigned comparison ch->realPeriod = MAX_FRQ-1; ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; } static void tonePorta(stmTyp *ch, uint8_t param) { if (ch->portaDir == 0) return; if (ch->portaDir > 1) { ch->realPeriod -= ch->portaSpeed; if ((int16_t)ch->realPeriod <= (int16_t)ch->wantPeriod) { ch->portaDir = 1; ch->realPeriod = ch->wantPeriod; } } else { ch->realPeriod += ch->portaSpeed; if (ch->realPeriod >= ch->wantPeriod) { ch->portaDir = 1; ch->realPeriod = ch->wantPeriod; } } if (ch->glissFunk) // semitone-slide flag ch->outPeriod = relocateTon(ch->realPeriod, 0, ch); else ch->outPeriod = ch->realPeriod; ch->status |= IS_Period; (void)param; } static void vibrato(stmTyp *ch, uint8_t param) { uint8_t tmp8; if (ch->eff > 0) { tmp8 = param & 0x0F; if (tmp8 > 0) ch->vibDepth = tmp8; tmp8 = (param & 0xF0) >> 2; if (tmp8 > 0) ch->vibSpeed = tmp8; } vibrato2(ch); } static void tonePlusVol(stmTyp *ch, uint8_t param) { tonePorta(ch, 0); // the last parameter is actually not used in tonePorta() volume(ch, param); (void)param; } static void vibratoPlusVol(stmTyp *ch, uint8_t param) { vibrato2(ch); volume(ch, param); (void)param; } static void tremolo(stmTyp *ch, uint8_t param) { uint8_t tmp8; int16_t tremVol; const uint8_t tmpEff = param; if (tmpEff > 0) { tmp8 = tmpEff & 0x0F; if (tmp8 > 0) ch->tremDepth = tmp8; tmp8 = (tmpEff & 0xF0) >> 2; if (tmp8 > 0) ch->tremSpeed = tmp8; } uint8_t tmpTrem = (ch->tremPos >> 2) & 0x1F; switch ((ch->waveCtrl >> 4) & 3) { // 0: sine case 0: tmpTrem = vibTab[tmpTrem]; break; // 1: ramp case 1: { tmpTrem <<= 3; if ((int8_t)ch->vibPos < 0) // FT2 bug, should've been ch->tremPos tmpTrem = ~tmpTrem; } break; // 2/3: square default: tmpTrem = 255; break; } tmpTrem = (tmpTrem * ch->tremDepth) >> 6; // logical shift (unsigned calc.), not arithmetic shift if ((int8_t)ch->tremPos < 0) { tremVol = ch->realVol - tmpTrem; if (tremVol < 0) tremVol = 0; } else { tremVol = ch->realVol + tmpTrem; if (tremVol > 64) tremVol = 64; } ch->outVol = (uint8_t)tremVol; ch->status |= IS_Vol; ch->tremPos += ch->tremSpeed; } static void volume(stmTyp *ch, uint8_t param) // volume slide { if (param == 0) param = ch->volSlideSpeed; ch->volSlideSpeed = param; uint8_t newVol = ch->realVol; if ((param & 0xF0) == 0) { newVol -= param; if ((int8_t)newVol < 0) newVol = 0; } else { param >>= 4; newVol += param; if (newVol > 64) newVol = 64; } ch->outVol = ch->realVol = newVol; ch->status |= IS_Vol; } static void globalVolSlide(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->globVolSlideSpeed; ch->globVolSlideSpeed = param; uint8_t newVol = (uint8_t)song.globVol; if ((param & 0xF0) == 0) { newVol -= param; if ((int8_t)newVol < 0) newVol = 0; } else { param >>= 4; newVol += param; if (newVol > 64) newVol = 64; } song.globVol = newVol; stmTyp *c = stm; for (int32_t i = 0; i < song.antChn; i++, c++) // update all voice volumes c->status |= IS_Vol; } static void keyOffCmd(stmTyp *ch, uint8_t param) { if ((uint8_t)(song.tempo-song.timer) == (param & 31)) keyOff(ch); } static void panningSlide(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->panningSlideSpeed; ch->panningSlideSpeed = param; int16_t newPan = (int16_t)ch->outPan; if ((param & 0xF0) == 0) { newPan -= param; if (newPan < 0) newPan = 0; } else { param >>= 4; newPan += param; if (newPan > 255) newPan = 255; } ch->outPan = (uint8_t)newPan; ch->status |= IS_Pan; } static void tremor(stmTyp *ch, uint8_t param) { if (param == 0) param = ch->tremorSave; ch->tremorSave = param; uint8_t tremorSign = ch->tremorPos & 0x80; uint8_t tremorData = ch->tremorPos & 0x7F; tremorData--; if ((int8_t)tremorData < 0) { if (tremorSign == 0x80) { tremorSign = 0x00; tremorData = param & 0x0F; } else { tremorSign = 0x80; tremorData = param >> 4; } } ch->tremorPos = tremorSign | tremorData; ch->outVol = (tremorSign == 0x80) ? ch->realVol : 0; ch->status |= IS_Vol + IS_QuickVol; } static void retrigNote(stmTyp *ch, uint8_t param) { if (param == 0) // E9x with a param of zero is handled in getNewNote() return; if ((song.tempo-song.timer) % param == 0) { startTone(0, 0, 0, ch); retrigEnvelopeVibrato(ch); } } static void noteCut(stmTyp *ch, uint8_t param) { if ((uint8_t)(song.tempo-song.timer) == param) { ch->outVol = ch->realVol = 0; ch->status |= IS_Vol + IS_QuickVol; } } static void noteDelay(stmTyp *ch, uint8_t param) { if ((uint8_t)(song.tempo-song.timer) == param) { startTone(ch->tonTyp & 0xFF, 0, 0, ch); if ((ch->tonTyp & 0xFF00) > 0) retrigVolume(ch); retrigEnvelopeVibrato(ch); if (ch->volKolVol >= 0x10 && ch->volKolVol <= 0x50) { ch->outVol = ch->volKolVol - 16; ch->realVol = ch->outVol; } else if (ch->volKolVol >= 0xC0 && ch->volKolVol <= 0xCF) { ch->outPan = (ch->volKolVol & 0x0F) << 4; } } } static const efxRoutine EJumpTab_TickNonZero[16] = { dummy, // 0 dummy, // 1 dummy, // 2 dummy, // 3 dummy, // 4 dummy, // 5 dummy, // 6 dummy, // 7 dummy, // 8 retrigNote, // 9 dummy, // A dummy, // B noteCut, // C noteDelay, // D dummy, // E dummy // F }; static void E_Effects_TickNonZero(stmTyp *ch, uint8_t param) { EJumpTab_TickNonZero[param >> 4](ch, param & 0xF); } static const efxRoutine JumpTab_TickNonZero[36] = { arp, // 0 portaUp, // 1 portaDown, // 2 tonePorta, // 3 vibrato, // 4 tonePlusVol, // 5 vibratoPlusVol, // 6 tremolo, // 7 dummy, // 8 dummy, // 9 volume, // A dummy, // B dummy, // C dummy, // D E_Effects_TickNonZero, // E dummy, // F dummy, // G globalVolSlide, // H dummy, // I dummy, // J keyOffCmd, // K dummy, // L dummy, // M dummy, // N dummy, // O panningSlide, // P dummy, // Q doMultiRetrig, // R dummy, // S tremor, // T dummy, // U dummy, // V dummy, // W dummy, // X dummy, // Y dummy // Z }; static void handleEffects_TickNonZero(stmTyp *ch) { if (ch->stOff) return; // muted // volume column effects VJumpTab_TickNonZero[ch->volKolVol >> 4](ch); // normal effects if ((ch->eff == 0 && ch->effTyp == 0) || ch->effTyp > 35) return; // no effect JumpTab_TickNonZero[ch->effTyp](ch, ch->eff); } static void getNextPos(void) { if (song.timer != 1) return; song.pattPos++; if (song.pattDelTime > 0) { song.pattDelTime2 = song.pattDelTime; song.pattDelTime = 0; } if (song.pattDelTime2 > 0) { song.pattDelTime2--; if (song.pattDelTime2 > 0) song.pattPos--; } if (song.pBreakFlag) { song.pBreakFlag = false; song.pattPos = song.pBreakPos; } if (song.pattPos >= song.pattLen || song.posJumpFlag) { song.pattPos = song.pBreakPos; song.pBreakPos = 0; song.posJumpFlag = false; if (playMode != PLAYMODE_PATT && playMode != PLAYMODE_RECPATT) { if (bxxOverflow) { song.songPos = 0; bxxOverflow = false; } else if (++song.songPos >= song.len) { editor.wavReachedEndFlag = true; song.songPos = song.repS; } assert(song.songPos <= 255); song.pattNr = song.songTab[song.songPos & 0xFF]; song.pattLen = pattLens[song.pattNr & 0xFF]; } } } void pauseMusic(void) // stops reading pattern data { musicPaused = true; while (replayerBusy); } void resumeMusic(void) // starts reading pattern data { musicPaused = false; } void tickReplayer(void) // periodically called from audio callback { int32_t i; stmTyp *c; if (musicPaused || !songPlaying) { c = stm; for (i = 0; i < song.antChn; i++, c++) fixaEnvelopeVibrato(c); return; } // for song playback counter (hh:mm:ss) if (song.speed >= MIN_BPM && song.speed <= MAX_BPM) song.musicTime64 += musicTimeTab64[song.speed]; bool tickZero = false; if (--song.timer == 0) { song.timer = song.tempo; tickZero = true; } song.curReplayerTimer = (uint8_t)song.timer; // for audio/video syncing (and recording) const bool readNewNote = tickZero && (song.pattDelTime2 == 0); if (readNewNote) { // set audio/video syncing variables song.curReplayerPattPos = (uint8_t)song.pattPos; song.curReplayerPattNr = (uint8_t)song.pattNr; song.curReplayerSongPos = (uint8_t)song.songPos; // ---------------------------------------------- const tonTyp *pattPtr = nilPatternLine; if (patt[song.pattNr] != NULL) { assert(song.pattNr >= 0 && song.pattNr < MAX_PATTERNS && song.pattPos >= 0 && song.pattPos < MAX_PATT_LEN); pattPtr = &patt[song.pattNr][song.pattPos * MAX_VOICES]; } c = stm; for (i = 0; i < song.antChn; i++, c++, pattPtr++) { getNewNote(c, pattPtr); fixaEnvelopeVibrato(c); } } else { c = stm; for (i = 0; i < song.antChn; i++, c++) { handleEffects_TickNonZero(c); fixaEnvelopeVibrato(c); } } getNextPos(); } void resetMusic(void) { const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); song.timer = 1; stopVoices(); if (audioWasntLocked) unlockAudio(); setPos(0, 0, false); if (!songPlaying) { setScrollBarEnd(SB_POS_ED, (song.len - 1) + 5); setScrollBarPos(SB_POS_ED, 0, false); } } void setPos(int16_t songPos, int16_t pattPos, bool resetTimer) { const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); if (songPos > -1) { song.songPos = songPos; if (song.len > 0 && song.songPos >= song.len) song.songPos = song.len - 1; song.pattNr = song.songTab[song.songPos]; assert(song.pattNr < MAX_PATTERNS); song.pattLen = pattLens[song.pattNr]; checkMarkLimits(); // non-FT2 safety } if (pattPos > -1) { song.pattPos = pattPos; if (song.pattPos >= song.pattLen) song.pattPos = song.pattLen-1; } // if not playing, update local position variables if (!songPlaying) { if (pattPos > -1) { editor.pattPos = (uint8_t)pattPos; ui.updatePatternEditor = true; } if (songPos > -1) { editor.editPattern = (uint8_t)song.pattNr; editor.songPos = song.songPos; ui.updatePosSections = true; } } if (resetTimer) song.timer = 1; if (audioWasntLocked) unlockAudio(); } void delta2Samp(int8_t *p, int32_t len, uint8_t typ) { if (typ & 16) len >>= 1; // 16-bit if (typ & 32) len >>= 1; // stereo if (typ & 32) { if (typ & 16) { int16_t *p16 = (int16_t *)p; int16_t olds16L = 0; int16_t olds16R = 0; for (int32_t i = 0; i < len; i++) { const int16_t news16L = p16[i] + olds16L; p16[i] = news16L; olds16L = news16L; const int16_t news16R = p16[len+i] + olds16R; p16[len+i] = news16R; olds16R = news16R; const int32_t tmp32 = olds16L + olds16R; p16[i] = (int16_t)(tmp32 >> 1); } } else { int8_t *p8 = (int8_t *)p; int8_t olds8L = 0; int8_t olds8R = 0; for (int32_t i = 0; i < len; i++) { const int8_t news8L = p8[i] + olds8L; p8[i] = news8L; olds8L = news8L; const int8_t news8R = p8[len+i] + olds8R; p8[len+i] = news8R; olds8R = news8R; const int16_t tmp16 = olds8L + olds8R; p8[i] = (int8_t)(tmp16 >> 1); } } } else { if (typ & 16) { int16_t *p16 = (int16_t *)p; int16_t olds16L = 0; for (int32_t i = 0; i < len; i++) { const int16_t news16 = p16[i] + olds16L; p16[i] = news16; olds16L = news16; } } else { int8_t *p8 = (int8_t *)p; int8_t olds8L = 0; for (int32_t i = 0; i < len; i++) { const int8_t news8 = p8[i] + olds8L; p8[i] = news8; olds8L = news8; } } } } void samp2Delta(int8_t *p, int32_t len, uint8_t typ) { if (typ & 16) len >>= 1; // 16-bit if (typ & 16) { int16_t *p16 = (int16_t *)p; int16_t news16 = 0; for (int32_t i = 0; i < len; i++) { const int16_t olds16 = p16[i]; p16[i] -= news16; news16 = olds16; } } else { int8_t *p8 = (int8_t *)p; int8_t news8 = 0; for (int32_t i = 0; i < len; i++) { const int8_t olds8 = p8[i]; p8[i] -= news8; news8 = olds8; } } } bool allocateInstr(int16_t nr) { if (instr[nr] != NULL) return false; // already allocated instrTyp *p = (instrTyp *)malloc(sizeof (instrTyp)); if (p == NULL) return false; memset(p, 0, sizeof (instrTyp)); for (int32_t i = 0; i < MAX_SMP_PER_INST; i++) { p->samp[i].pan = 128; p->samp[i].vol = 64; } setStdEnvelope(p, 0, 3); const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); instr[nr] = p; if (audioWasntLocked) unlockAudio(); return true; } void freeInstr(int32_t nr) { if (instr[nr] == NULL) return; // not allocated pauseAudio(); // channel instrument pointers are now cleared sampleTyp *s = instr[nr]->samp; for (int32_t i = 0; i < MAX_SMP_PER_INST; i++, s++) // free sample data { if (s->origPek != NULL) free(s->origPek); } free(instr[nr]); instr[nr] = NULL; resumeAudio(); } void freeAllInstr(void) { pauseAudio(); // channel instrument pointers are now cleared for (int32_t i = 1; i <= MAX_INST; i++) { if (instr[i] != NULL) { sampleTyp *s = instr[i]->samp; for (int32_t j = 0; j < MAX_SMP_PER_INST; j++, s++) // free sample data { if (s->origPek != NULL) free(s->origPek); } free(instr[i]); instr[i] = NULL; } } resumeAudio(); } void freeSample(int16_t nr, int16_t nr2) { if (instr[nr] == NULL) return; // instrument not allocated pauseAudio(); // voice sample pointers are now cleared sampleTyp *s = &instr[nr]->samp[nr2]; if (s->origPek != NULL) free(s->origPek); memset(s, 0, sizeof (sampleTyp)); s->pan = 128; s->vol = 64; resumeAudio(); } void freeAllPatterns(void) { pauseAudio(); for (int32_t i = 0; i < MAX_PATTERNS; i++) { if (patt[i] != NULL) { free(patt[i]); patt[i] = NULL; } } resumeAudio(); } void setStdEnvelope(instrTyp *ins, int16_t i, uint8_t typ) { if (ins == NULL) return; pauseMusic(); if (typ & 1) { memcpy(ins->envVP, config.stdEnvP[i][0], 2*2*12); ins->envVPAnt = (uint8_t)config.stdVolEnvAnt[i]; ins->envVSust = (uint8_t)config.stdVolEnvSust[i]; ins->envVRepS = (uint8_t)config.stdVolEnvRepS[i]; ins->envVRepE = (uint8_t)config.stdVolEnvRepE[i]; ins->fadeOut = config.stdFadeOut[i]; ins->vibRate = (uint8_t)config.stdVibRate[i]; ins->vibDepth = (uint8_t)config.stdVibDepth[i]; ins->vibSweep = (uint8_t)config.stdVibSweep[i]; ins->vibTyp = (uint8_t)config.stdVibTyp[i]; ins->envVTyp = (uint8_t)config.stdVolEnvTyp[i]; } if (typ & 2) { memcpy(ins->envPP, config.stdEnvP[i][1], 2*2*12); ins->envPPAnt = (uint8_t)config.stdPanEnvAnt[0]; ins->envPSust = (uint8_t)config.stdPanEnvSust[0]; ins->envPRepS = (uint8_t)config.stdPanEnvRepS[0]; ins->envPRepE = (uint8_t)config.stdPanEnvRepE[0]; ins->envPTyp = (uint8_t)config.stdPanEnvTyp[0]; } resumeMusic(); } void setNoEnvelope(instrTyp *ins) { if (ins == NULL) return; pauseMusic(); memcpy(ins->envVP, config.stdEnvP[0][0], 2*2*12); ins->envVPAnt = (uint8_t)config.stdVolEnvAnt[0]; ins->envVSust = (uint8_t)config.stdVolEnvSust[0]; ins->envVRepS = (uint8_t)config.stdVolEnvRepS[0]; ins->envVRepE = (uint8_t)config.stdVolEnvRepE[0]; ins->envVTyp = 0; memcpy(ins->envPP, config.stdEnvP[0][1], 2*2*12); ins->envPPAnt = (uint8_t)config.stdPanEnvAnt[0]; ins->envPSust = (uint8_t)config.stdPanEnvSust[0]; ins->envPRepS = (uint8_t)config.stdPanEnvRepS[0]; ins->envPRepE = (uint8_t)config.stdPanEnvRepE[0]; ins->envPTyp = 0; ins->fadeOut = 0; ins->vibRate = 0; ins->vibDepth = 0; ins->vibSweep = 0; ins->vibTyp = 0; resumeMusic(); } bool patternEmpty(uint16_t nr) { if (patt[nr] == NULL) return true; const uint8_t *scanPtr = (const uint8_t *)patt[nr]; const uint32_t scanLen = pattLens[nr] * TRACK_WIDTH; for (uint32_t i = 0; i < scanLen; i++) { if (scanPtr[i] != 0) return false; } return true; } void updateChanNums(void) { assert(!(song.antChn & 1)); const int32_t maxChannelsShown = getMaxVisibleChannels(); int32_t channelsShown = song.antChn; if (channelsShown > maxChannelsShown) channelsShown = maxChannelsShown; ui.numChannelsShown = (uint8_t)channelsShown; ui.pattChanScrollShown = (song.antChn > maxChannelsShown); if (ui.patternEditorShown) { if (ui.channelOffset > song.antChn-ui.numChannelsShown) setScrollBarPos(SB_CHAN_SCROLL, song.antChn - ui.numChannelsShown, true); } if (ui.pattChanScrollShown) { if (ui.patternEditorShown) { showScrollBar(SB_CHAN_SCROLL); showPushButton(PB_CHAN_SCROLL_LEFT); showPushButton(PB_CHAN_SCROLL_RIGHT); } setScrollBarEnd(SB_CHAN_SCROLL, song.antChn); setScrollBarPageLength(SB_CHAN_SCROLL, ui.numChannelsShown); } else { hideScrollBar(SB_CHAN_SCROLL); hidePushButton(PB_CHAN_SCROLL_LEFT); hidePushButton(PB_CHAN_SCROLL_RIGHT); setScrollBarPos(SB_CHAN_SCROLL, 0, false); ui.channelOffset = 0; } if (cursor.ch >= ui.channelOffset+ui.numChannelsShown) cursor.ch = ui.channelOffset+ui.numChannelsShown - 1; } void conv8BitSample(int8_t *p, int32_t len, bool stereo) { if (stereo) { len /= 2; int8_t *p2 = &p[len]; for (int32_t i = 0; i < len; i++) { const int8_t l = p[i] ^ 0x80; const int8_t r = p2[i] ^ 0x80; int16_t tmp16 = l + r; p[i] = (int8_t)(tmp16 >> 1); } } else { for (int32_t i = 0; i < len; i++) p[i] ^= 0x80; } } void conv16BitSample(int8_t *p, int32_t len, bool stereo) { int16_t *p16_1 = (int16_t *)p; len /= 2; if (stereo) { len /= 2; int16_t *p16_2 = (int16_t *)&p[len * 2]; for (int32_t i = 0; i < len; i++) { const int16_t l = p16_1[i] ^ 0x8000; const int16_t r = p16_2[i] ^ 0x8000; int32_t tmp32 = l + r; p16_1[i] = (int16_t)(tmp32 >> 1); } } else { for (int32_t i = 0; i < len; i++) p16_1[i] ^= 0x8000; } } void closeReplayer(void) { freeAllInstr(); freeAllPatterns(); // free reserved instruments if (instr[0] != NULL) { free(instr[0]); instr[0] = NULL; } if (instr[130] != NULL) { free(instr[130]); instr[130] = NULL; } if (instr[131] != NULL) { free(instr[131]); instr[131] = NULL; } freeWindowedSincTables(); } bool setupReplayer(void) { for (int32_t i = 0; i < MAX_PATTERNS; i++) pattLens[i] = 64; playMode = PLAYMODE_IDLE; songPlaying = false; // unmute all channels (must be done before resetChannels() call) for (int32_t i = 0; i < MAX_VOICES; i++) editor.chnMode[i] = 1; resetChannels(); song.len = 1; song.antChn = 8; editor.speed = song.speed = 125; editor.tempo = song.tempo = 6; editor.globalVol = song.globVol = 64; song.initialTempo = song.tempo; audio.linearFreqTable = true; note2Period = linearPeriods; if (!calcWindowedSincTables()) { showErrorMsgBox("Not enough memory!"); return false; } calcPeriod2HzTable(); calcRevMixDeltaTable(); calcPanningTable(); setPos(0, 0, true); if (!allocateInstr(0)) { showErrorMsgBox("Not enough memory!"); return false; } instr[0]->samp[0].vol = 0; if (!allocateInstr(130)) { showErrorMsgBox("Not enough memory!"); return false; } memset(instr[130], 0, sizeof (instrTyp)); if (!allocateInstr(131)) // Instr. Ed. display instrument for unallocated/empty instruments { showErrorMsgBox("Not enough memory!"); return false; } memset(instr[131], 0, sizeof (instrTyp)); for (int32_t i = 0; i < 16; i++) instr[131]->samp[i].pan = 128; editor.tmpPattern = 65535; // pattern editor update/redraw kludge return true; } void startPlaying(int8_t mode, int16_t row) { lockMixerCallback(); assert(mode != PLAYMODE_IDLE && mode != PLAYMODE_EDIT); if (mode == PLAYMODE_PATT || mode == PLAYMODE_RECPATT) setPos(-1, row, true); else setPos(editor.songPos, row, true); playMode = mode; songPlaying = true; resetReplayerState(); resetPlaybackTime(); // non-FT2 fix: If song speed was 0, set it back to initial speed on play if (song.tempo == 0) song.tempo = song.initialTempo; audio.dTickSampleCounter = 0.0; // zero tick sample counter so that it will instantly initiate a tick unlockMixerCallback(); ui.updatePosSections = true; ui.updatePatternEditor = true; } void stopPlaying(void) { bool songWasPlaying = songPlaying; playMode = PLAYMODE_IDLE; songPlaying = false; if (config.killNotesOnStopPlay) { // safely kills all voices lockMixerCallback(); unlockMixerCallback(); } else { for (uint8_t i = 0; i < MAX_VOICES; i++) playTone(i, 0, 97, -1, 0, 0); } // if song was playing, update local pattPos (fixes certain glitches) if (songWasPlaying) editor.pattPos = song.pattPos; #ifdef HAS_MIDI midi.currMIDIVibDepth = 0; midi.currMIDIPitch = 0; #endif memset(editor.keyOnTab, 0, sizeof (editor.keyOnTab)); ui.updatePosSections = true; ui.updatePatternEditor = true; // certain non-FT2 fixes song.timer = editor.timer = 1; song.globVol = editor.globalVol = 64; ui.drawGlobVolFlag = true; } // from keyboard/smp. ed. void playTone(uint8_t stmm, uint8_t inst, uint8_t ton, int8_t vol, uint16_t midiVibDepth, uint16_t midiPitch) { instrTyp *ins = instr[inst]; if (ins == NULL) return; assert(stmm < MAX_VOICES && inst <= MAX_INST && ton <= 97); stmTyp *ch = &stm[stmm]; // FT2 bugfix: Don't play tone if certain requirements are not met if (ton != 97) { if (ton == 0 || ton > 96) return; sampleTyp *s = &ins->samp[ins->ta[ton-1] & 0xF]; int16_t newTon = (int16_t)ton + s->relTon; if (s->pek == NULL || s->len == 0 || newTon <= 0 || newTon >= 12*10) return; } // ------------------- lockAudio(); if (inst != 0 && ton != 97) { ch->tonTyp = (inst << 8) | (ch->tonTyp & 0xFF); ch->instrNr = inst; } ch->tonTyp = (ch->tonTyp & 0xFF00) | ton; ch->effTyp = 0; ch->eff = 0; startTone(ton, 0, 0, ch); if (ton != 97) { retrigVolume(ch); retrigEnvelopeVibrato(ch); if (vol != -1) // if jamming note keys, vol -1 = use sample's volume { ch->realVol = vol; ch->outVol = vol; ch->oldVol = vol; } } ch->midiVibDepth = midiVibDepth; ch->midiPitch = midiPitch; fixaEnvelopeVibrato(ch); unlockAudio(); } // smp. ed. void playSample(uint8_t stmm, uint8_t inst, uint8_t smpNr, uint8_t ton, uint16_t midiVibDepth, uint16_t midiPitch) { if (instr[inst] == NULL) return; // for sampling playback line in Smp. Ed. lastChInstr[stmm].instrNr = 255; lastChInstr[stmm].sampleNr = 255; editor.curPlayInstr = 255; editor.curPlaySmp = 255; assert(stmm < MAX_VOICES && inst <= MAX_INST && smpNr < MAX_SMP_PER_INST && ton <= 97); stmTyp *ch = &stm[stmm]; memcpy(&instr[130]->samp[0], &instr[inst]->samp[smpNr], sizeof (sampleTyp)); uint8_t vol = instr[inst]->samp[smpNr].vol; lockAudio(); ch->instrNr = 130; ch->tonTyp = (ch->instrNr << 8) | ton; ch->effTyp = 0; startTone(ton, 0, 0, ch); if (ton != 97) { retrigVolume(ch); retrigEnvelopeVibrato(ch); ch->realVol = vol; ch->outVol = vol; ch->oldVol = vol; } ch->midiVibDepth = midiVibDepth; ch->midiPitch = midiPitch; fixaEnvelopeVibrato(ch); unlockAudio(); while (ch->status & IS_NyTon); // wait for sample to latch in mixer // for sampling playback line in Smp. Ed. editor.curPlayInstr = editor.curInstr; editor.curPlaySmp = editor.curSmp; } // smp. ed. void playRange(uint8_t stmm, uint8_t inst, uint8_t smpNr, uint8_t ton, uint16_t midiVibDepth, uint16_t midiPitch, int32_t offs, int32_t len) { if (instr[inst] == NULL) return; // for sampling playback line in Smp. Ed. lastChInstr[stmm].instrNr = 255; lastChInstr[stmm].sampleNr = 255; editor.curPlayInstr = 255; editor.curPlaySmp = 255; assert(stmm < MAX_VOICES && inst <= MAX_INST && smpNr < MAX_SMP_PER_INST && ton <= 97); stmTyp *ch = &stm[stmm]; sampleTyp *s = &instr[130]->samp[0]; memcpy(s, &instr[inst]->samp[smpNr], sizeof (sampleTyp)); uint8_t vol = instr[inst]->samp[smpNr].vol; if (s->typ & 16) { offs &= 0xFFFFFFFE; len &= 0xFFFFFFFE; } lockAudio(); s->len = offs + len; s->repS = 0; s->repL = 0; s->typ &= 16; // only keep 8-bit/16-bit flag (disable loop) int32_t samplePlayOffset = offs; if (s->typ & 16) samplePlayOffset >>= 1; ch->instrNr = 130; ch->tonTyp = (ch->instrNr << 8) | ton; ch->effTyp = 0; startTone(ton, 0, 0, ch); ch->smpStartPos = samplePlayOffset; if (ton != 97) { retrigVolume(ch); retrigEnvelopeVibrato(ch); ch->realVol = vol; ch->outVol = vol; ch->oldVol = vol; } ch->midiVibDepth = midiVibDepth; ch->midiPitch = midiPitch; fixaEnvelopeVibrato(ch); unlockAudio(); while (ch->status & IS_NyTon); // wait for sample to latch in mixer // for sampling playback line in Smp. Ed. editor.curPlayInstr = editor.curInstr; editor.curPlaySmp = editor.curSmp; } void stopVoices(void) { const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); stmTyp *ch = stm; for (int32_t i = 0; i < MAX_VOICES; i++, ch++) { lastChInstr[i].sampleNr = 255; lastChInstr[i].instrNr = 255; ch->tonTyp = 0; ch->relTonNr = 0; ch->instrNr = 0; ch->instrPtr = instr[0]; // important: set instrument pointer to instr 0 (placeholder instrument) ch->status = IS_Vol; ch->realVol = 0; ch->outVol = 0; ch->oldVol = 0; ch->dFinalVol = 0.0; ch->oldPan = 128; ch->outPan = 128; ch->finalPan = 128; ch->vibDepth = 0; ch->midiVibDepth = 0; ch->midiPitch = 0; ch->smpPtr = NULL; ch->portaDir = 0; // FT2 bugfix: weird 3xx behavior if not used with note stopVoice(i); } // for sampling playback line in Smp. Ed. editor.curPlayInstr = 255; editor.curPlaySmp = 255; stopAllScopes(); resetAudioDither(); resetCachedMixerVars(); resetCachedScopeVars(); // wait for scope thread to finish, so that we know pointers aren't deprecated while (editor.scopeThreadMutex); if (audioWasntLocked) unlockAudio(); } void resetReplayerState(void) { song.pattDelTime = song.pattDelTime2 = 0; song.posJumpFlag = false; song.pBreakPos = 0; song.pBreakFlag = false; if (songPlaying) { song.globVol = 64; stmTyp *ch = stm; for (int32_t i = 0; i < song.antChn; i++, ch++) ch->status |= IS_Vol; } } void setNewSongPos(int32_t pos) { resetReplayerState(); // FT2 bugfix setPos((int16_t)pos, 0, true); // non-FT2 fix: If song speed was 0, set it back to initial speed if (song.tempo == 0) song.tempo = song.initialTempo; } void decSongPos(void) { if (song.songPos == 0) return; const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); if (song.songPos > 0) setNewSongPos(song.songPos - 1); if (audioWasntLocked) unlockAudio(); } void incSongPos(void) { if (song.songPos == song.len-1) return; const bool audioWasntLocked = !audio.locked; if (audioWasntLocked) lockAudio(); if (song.songPos < song.len-1) setNewSongPos(song.songPos + 1); if (audioWasntLocked) unlockAudio(); } void decCurIns(void) { if (editor.curInstr <= 1) return; editor.curInstr--; if ((editor.curInstr > 0x40 && !editor.instrBankSwapped) || (editor.curInstr <= 0x40 && editor.instrBankSwapped)) pbSwapInstrBank(); editor.instrBankOffset = ((editor.curInstr - 1) / 8) * 8; updateTextBoxPointers(); updateNewInstrument(); if (ui.advEditShown) updateAdvEdit(); } void incCurIns(void) { if (editor.curInstr >= MAX_INST) return; editor.curInstr++; if ((editor.curInstr > 0x40 && !editor.instrBankSwapped) || (editor.curInstr <= 0x40 && editor.instrBankSwapped)) pbSwapInstrBank(); editor.instrBankOffset = ((editor.curInstr - 1) / 8) * 8; if (editor.instrBankOffset > MAX_INST-8) editor.instrBankOffset = MAX_INST-8; updateTextBoxPointers(); updateNewInstrument(); if (ui.advEditShown) updateAdvEdit(); } void decCurSmp(void) { if (editor.curSmp == 0) return; editor.curSmp--; editor.sampleBankOffset = (editor.curSmp / 5) * 5; setScrollBarPos(SB_SAMPLE_LIST, editor.sampleBankOffset, true); updateTextBoxPointers(); updateNewSample(); } void incCurSmp(void) { if (editor.curSmp >= MAX_SMP_PER_INST-1) return; editor.curSmp++; editor.sampleBankOffset = (editor.curSmp / 5) * 5; if (editor.sampleBankOffset > MAX_SMP_PER_INST-5) editor.sampleBankOffset = MAX_SMP_PER_INST-5; setScrollBarPos(SB_SAMPLE_LIST, editor.sampleBankOffset, true); updateTextBoxPointers(); updateNewSample(); } void pbPlaySong(void) { startPlaying(PLAYMODE_SONG, 0); } void pbPlayPtn(void) { startPlaying(PLAYMODE_PATT, 0); } void pbRecSng(void) { startPlaying(PLAYMODE_RECSONG, 0); } void pbRecPtn(void) { startPlaying(PLAYMODE_RECPATT, 0); } void setSyncedReplayerVars(void) { uint8_t scopeUpdateStatus[MAX_VOICES]; pattSyncEntry = NULL; chSyncEntry = NULL; memset(scopeUpdateStatus, 0, sizeof (scopeUpdateStatus)); // this is needed uint64_t frameTime64 = SDL_GetPerformanceCounter(); // handle channel sync queue while (chQueueClearing); while (chQueueReadSize() > 0) { if (frameTime64 < getChQueueTimestamp()) break; // we have no more stuff to render for now chSyncEntry = chQueuePeek(); if (chSyncEntry == NULL) break; for (int32_t i = 0; i < song.antChn; i++) scopeUpdateStatus[i] |= chSyncEntry->channels[i].status; // yes, OR the status if (!chQueuePop()) break; } /* Extra validation because of possible issues when the buffer is full ** and positions are being reset, which is not entirely thread safe. */ if (chSyncEntry != NULL && chSyncEntry->timestamp == 0) chSyncEntry = NULL; // handle pattern sync queue while (pattQueueClearing); while (pattQueueReadSize() > 0) { if (frameTime64 < getPattQueueTimestamp()) break; // we have no more stuff to render for now pattSyncEntry = pattQueuePeek(); if (pattSyncEntry == NULL) break; if (!pattQueuePop()) break; } /* Extra validation because of possible issues when the buffer is full ** and positions are being reset, which is not entirely thread safe. */ if (pattSyncEntry != NULL && pattSyncEntry->timestamp == 0) pattSyncEntry = NULL; // do actual updates if (chSyncEntry != NULL) { handleScopesFromChQueue(chSyncEntry, scopeUpdateStatus); ui.drawReplayerPianoFlag = true; } if (!songPlaying || pattSyncEntry == NULL) return; // we have a new tick editor.timer = pattSyncEntry->timer; if (editor.speed != pattSyncEntry->speed) { editor.speed = pattSyncEntry->speed; ui.drawBPMFlag = true; } if (editor.tempo != pattSyncEntry->tempo) { editor.tempo = pattSyncEntry->tempo; ui.drawSpeedFlag = true; } if (editor.globalVol != pattSyncEntry->globalVol) { editor.globalVol = pattSyncEntry->globalVol; ui.drawGlobVolFlag = true; } if (editor.songPos != pattSyncEntry->songPos) { editor.songPos = pattSyncEntry->songPos; ui.drawPosEdFlag = true; } // somewhat of a kludge... if (editor.tmpPattern != pattSyncEntry->pattern || editor.pattPos != pattSyncEntry->patternPos) { // set pattern number editor.editPattern = editor.tmpPattern = pattSyncEntry->pattern; checkMarkLimits(); ui.drawPattNumLenFlag = true; // set row editor.pattPos = (uint8_t)pattSyncEntry->patternPos; ui.updatePatternEditor = true; } }