ref: 723ca0d4b4da52cf0c52e84fa9b81ba11ae5ad31
dir: /pmp_main.c/
// XM replayer
#include "common.h"
#include "pmplay.h"
#include "pmp_mix.h"
#include "snd_masm.h"
#include "tables.h"
#define MAX_NOTES ((12 * 10 * 16) + 16)
static tonTyp nilPatternLine[32]; // 8bb: used for non-allocated (empty) patterns
typedef void (*volKolEfxRoutine)(stmTyp *ch);
typedef void (*volKolEfxRoutine2)(stmTyp *ch, uint8_t *volKol);
typedef void (*efxRoutine)(stmTyp *ch, uint8_t param);
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->instrSeg;
if (ins->envVTyp & 1)
{
ch->envVCnt = 65535;
ch->envVPos = 0;
}
if (ins->envPTyp & 1)
{
ch->envPCnt = 65535;
ch->envPPos = 0;
}
ch->fadeOutSpeed = ins->fadeOut; // 8bb: 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;
}
}
}
static void keyOff(stmTyp *ch)
{
ch->envSustainActive = false;
instrTyp *ins = ch->instrSeg;
if (!(ins->envPTyp & 1)) // 8bb: yes, FT2 does this (!)
{
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;
}
}
uint32_t getFrequenceValue(uint16_t period)
{
uint32_t delta;
if (period == 0)
return 0;
if (linearFrqTab)
{
const uint16_t invPeriod = (12 * 192 * 4) - period; // 8bb: this intentionally overflows uint16_t to be accurate to FT2
const int32_t octave = (14 - (invPeriod / 768)) & 0x1F;
delta = (uint32_t)(((int64_t)logTab[invPeriod % 768] * frequenceMulFactor) >> 24);
delta >>= octave;
}
else
{
delta = frequenceDivFactor / period;
}
return delta;
}
static void startTone(uint8_t ton, uint8_t effTyp, uint8_t eff, stmTyp *ch)
{
if (ton == 97)
{
keyOff(ch);
return;
}
// 8bb: if we came from Rxy (retrig), we didn't check note (Ton) yet
if (ton == 0)
{
ton = ch->tonNr;
if (ton == 0)
return; // 8bb: if still no note, return
}
ch->tonNr = ton;
instrTyp *ins = instr[ch->instrNr];
if (ins == NULL)
ins = instr[0];
ch->instrSeg = ins;
ch->mute = ins->mute;
uint8_t smp = ins->ta[ton-1] & 0xF; // 8bb: added safety-AND
ch->sampleNr = smp;
sampleTyp *s = &ins->samp[smp];
ch->relTonNr = s->relTon;
ton += ch->relTonNr;
if (ton >= 12*10)
return;
ch->oldVol = s->vol;
ch->oldPan = s->pan;
if (effTyp == 0x0E && (eff & 0xF0) == 0x50)
ch->fineTune = ((eff & 0x0F) << 4) - 128;
else
ch->fineTune = s->fine;
if (ton != 0)
{
const uint16_t tmpTon = ((ton - 1) << 4) + (((ch->fineTune >> 3) + 16) & 0xFF);
if (tmpTon < MAX_NOTES)
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;
}
P_StartTone(s, ch->smpStartPos);
}
static void volume(stmTyp *ch, uint8_t param); // 8bb: actually volume slide
static void vibrato2(stmTyp *ch);
static void tonePorta(stmTyp *ch, uint8_t param);
static void dummy(stmTyp *ch, uint8_t param)
{
USED(ch);
USED(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 > 32000-1)
ch->realPeriod = 32000-1;
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) // 8bb: 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;
USED(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)
{
EJumpTab_TickZero[param >> 4](ch, param & 0x0F);
}
static void posJump(stmTyp *ch, uint8_t param)
{
song.songPos = (int16_t)param - 1;
song.pBreakPos = 0;
song.posJumpFlag = true;
USED(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;
USED(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;
}
USED(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++) // 8bb: update all voice volumes
c->status |= IS_Vol;
USED(ch);
}
static void setEnvelopePos(stmTyp *ch, uint8_t param)
{
int8_t envPos;
bool envUpdate;
int16_t newEnvPos;
instrTyp *ins = ch->instrSeg;
// *** VOLUME ENVELOPE ***
if (ins->envVTyp & 1)
{
ch->envVCnt = param - 1;
envPos = 0;
envUpdate = true;
newEnvPos = param;
if (ins->envVPAnt > 1)
{
envPos++;
for (int32_t i = 0; i < ins->envVPAnt-1; i++)
{
if (newEnvPos < ins->envVP[envPos][0])
{
envPos--;
newEnvPos -= ins->envVP[envPos][0];
if (newEnvPos == 0)
{
envUpdate = false;
break;
}
if (ins->envVP[envPos+1][0] <= ins->envVP[envPos][0])
{
envUpdate = true;
break;
}
ch->envVIPValue = ((ins->envVP[envPos+1][1] - ins->envVP[envPos][1]) & 0xFF) << 8;
ch->envVIPValue /= (ins->envVP[envPos+1][0] - ins->envVP[envPos][0]);
ch->envVAmp = (ch->envVIPValue * (newEnvPos - 1)) + ((ins->envVP[envPos][1] & 0xFF) << 8);
envPos++;
envUpdate = false;
break;
}
envPos++;
}
if (envUpdate)
envPos--;
}
if (envUpdate)
{
ch->envVIPValue = 0;
ch->envVAmp = (ins->envVP[envPos][1] & 0xFF) << 8;
}
if (envPos >= ins->envVPAnt)
{
envPos = ins->envVPAnt - 1;
if (envPos < 0)
envPos = 0;
}
ch->envVPos = envPos;
}
// *** PANNING ENVELOPE ***
if (ins->envVTyp & 2) // 8bb: probably an FT2 bug
{
ch->envPCnt = param - 1;
envPos = 0;
envUpdate = true;
newEnvPos = param;
if (ins->envPPAnt > 1)
{
envPos++;
for (int32_t i = 0; i < ins->envPPAnt-1; i++)
{
if (newEnvPos < ins->envPP[envPos][0])
{
envPos--;
newEnvPos -= ins->envPP[envPos][0];
if (newEnvPos == 0)
{
envUpdate = false;
break;
}
if (ins->envPP[envPos + 1][0] <= ins->envPP[envPos][0])
{
envUpdate = true;
break;
}
ch->envPIPValue = ((ins->envPP[envPos+1][1] - ins->envPP[envPos][1]) & 0xFF) << 8;
ch->envPIPValue /= (ins->envPP[envPos+1][0] - ins->envPP[envPos][0]);
ch->envPAmp = (ch->envPIPValue * (newEnvPos - 1)) + ((ins->envPP[envPos][1] & 0xFF) << 8);
envPos++;
envUpdate = false;
break;
}
envPos++;
}
if (envUpdate)
envPos--;
}
if (envUpdate)
{
ch->envPIPValue = 0;
ch->envPAmp = (ins->envPP[envPos][1] & 0xFF) << 8;
}
if (envPos >= ins->envPPAnt)
{
envPos = ins->envPPAnt - 1;
if (envPos < 0)
envPos = 0;
}
ch->envPPos = envPos;
}
}
/* -- 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) // 8bb: 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) // 8bb: 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); // 8bb: the last parameter is actually not used in tonePorta()
}
static void v_dummy(stmTyp *ch)
{
USED(ch);
return;
}
static void v_dummy2(stmTyp *ch, uint8_t *volKol)
{
USED(ch);
USED(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 > 32000-1)
newPeriod = 32000-1;
ch->outPeriod = ch->realPeriod = newPeriod;
ch->status |= IS_Period;
}
}
static void doMultiRetrig(stmTyp *ch, uint8_t param) // 8bb: "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; // 8bb: 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); // 8bb: the second parameter is never used (needed for efx jumptable structure)
}
static const efxRoutine JumpTab_TickZero[36] =
{
dummy, // 0
dummy, // 1
dummy, // 2
dummy, // 3
dummy, // 4
dummy, // 5
dummy, // 6
dummy, // 7
setPan, // 8
dummy, // 9
dummy, // A
posJump, // B
setVol, // 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
xFinePorta, // X
dummy, // Y
dummy // Z
};
static void checkEffects(stmTyp *ch) // tick0 effect handling
{
// volume column effects
uint8_t newVolKol = ch->volKolVol; // 8bb: 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) || ch->effTyp > 35)
return; // no effect
// 8bb: this one has to be done here instead of in the jumptable, as it needs the "newVolKol" parameter (FT2 quirk)
if (ch->effTyp == 27)
{
multiRetrig(ch, param, newVolKol);
return;
}
JumpTab_TickZero[ch->effTyp](ch, ch->eff);
}
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 portaTmp = ((((p->ton - 1) + ch->relTonNr) & 0xFF) * 16) + (((ch->fineTune >> 3) + 16) & 0xFF);
if (portaTmp < MAX_NOTES)
{
ch->wantPeriod = note2Period[portaTmp];
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) // 8bb: we have an arpeggio running, set period back
{
ch->outPeriod = ch->realPeriod;
ch->status |= IS_Period;
}
}
else
{
// 8bb: 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))
{
// 8bb: but it's ending at the next (this) row, so set period back
ch->outPeriod = ch->realPeriod;
ch->status |= IS_Period;
}
}
ch->effTyp = p->effTyp;
ch->eff = p->eff;
ch->tonTyp = (p->instr << 8) | p->ton;
// 8bb: 'inst' var is used for later if checks...
uint8_t inst = p->instr;
if (inst > 0)
{
if (inst <= 128)
ch->instrNr = inst;
else
inst = 0;
}
bool checkEfx = true;
if (p->effTyp == 0x0E)
{
if (p->eff >= 0xD1 && p->eff <= 0xDF)
return; // 8bb: 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);
checkEffects(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);
checkEffects(ch);
return;
}
if (p->effTyp == 0x14 && p->eff == 0) // K00 (KeyOff - only handle tick 0 here)
{
keyOff(ch);
if (inst)
retrigVolume(ch);
checkEffects(ch);
return;
}
if (p->ton == 0)
{
if (inst > 0)
{
retrigVolume(ch);
retrigEnvelopeVibrato(ch);
}
checkEffects(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);
}
checkEffects(ch);
}
static void fixaEnvelopeVibrato(stmTyp *ch)
{
bool envInterpolateFlag, envDidInterpolate;
uint8_t envPos;
int16_t autoVibVal;
uint16_t autoVibAmp, envVal;
uint32_t vol;
instrTyp *ins = ch->instrSeg;
// *** FADEOUT ***
if (!ch->envSustainActive)
{
ch->status |= IS_Vol;
// 8bb: 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] << 8;
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] << 8;
}
}
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]) << 8;
ch->envVIPValue /= (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*256)
{
if (envVal > 128*256)
envVal = 64*256;
else
envVal = 0;
ch->envVIPValue = 0;
}
}
envVal >>= 8;
vol = (envVal * ch->outVol * ch->fadeOutAmp) >> (16+2);
vol = (vol * song.globVol) >> 7;
ch->status |= IS_Vol; // 8bb: update vol every tick because vol envelope is enabled
}
else
{
vol = ((ch->outVol << 4) * ch->fadeOutAmp) >> 16;
vol = (vol * song.globVol) >> 7;
}
ch->finalVol = (uint16_t)vol; // 0..256
}
else
{
ch->finalVol = 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] << 8;
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] << 8;
}
}
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]) << 8;
ch->envPIPValue /= (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*256)
{
if (envVal > 128*256)
envVal = 64*256;
else
envVal = 0;
ch->envPIPValue = 0;
}
}
int16_t panTmp = ch->outPan - 128;
if (panTmp > 0)
panTmp = 0 - panTmp;
panTmp += 128;
panTmp <<= 3;
envVal -= 32*256;
ch->finalPan = ch->outPan + (uint8_t)(((int16_t)envVal * panTmp) >> 16);
ch->status |= IS_Pan;
}
else
{
ch->finalPan = ch->outPan;
}
// *** AUTO VIBRATO ***
if (ins->vibDepth > 0)
{
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;
}
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 >= 32000)
tmpPeriod = 0; // 8bb: yes, FT2 does this (!)
ch->finalPeriod = tmpPeriod;
ch->status |= IS_Period;
}
else
{
ch->finalPeriod = ch->outPeriod;
}
}
// 8bb: 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 = ((ch->fineTune >> 3) + 16) << 1;
int32_t hiPeriod = (8 * 12 * 16) * 2;
int32_t loPeriod = 0;
for (int32_t i = 0; i < 8; i++)
{
tmpPeriod = (((loPeriod + hiPeriod) >> 1) & 0xFFFFFFE0) + fineTune;
int32_t tableIndex = (uint32_t)(tmpPeriod - 16) >> 1;
tableIndex = CLAMP(tableIndex, 0, 1935); // 8bb: added security check
if (period >= note2Period[tableIndex])
hiPeriod = (tmpPeriod - fineTune) & 0xFFFFFFE0;
else
loPeriod = (tmpPeriod - fineTune) & 0xFFFFFFE0;
}
tmpPeriod = loPeriod + fineTune + (arpNote << 5);
if (tmpPeriod < 0) // 8bb: added security check
tmpPeriod = 0;
if (tmpPeriod >= (8*12*16+15)*2-1) // 8bb: FT2 bug, off-by-one edge case
tmpPeriod = (8*12*16+15)*2;
return note2Period[(uint32_t)tmpPeriod>>1];
}
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;
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)
{
const uint8_t tick = arpTab[song.timer & 0xFF]; // 8bb: non-FT2 protection (we have 248 extra overflow bytes in LUT, but not more!)
if (tick == 0)
{
ch->outPeriod = ch->realPeriod;
}
else
{
const uint8_t note = (tick == 1) ? (param >> 4) : (param & 0x0F);
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 > 32000-1) // 8bb: FT2 bug, should've been unsigned comparison!
ch->realPeriod = 32000-1;
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) // 8bb: 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); // 8bb: 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) // 8bb: FT2 bug, should've been ch->tremPos
tmpTrem = ~tmpTrem;
}
break;
// 2/3: square
default: tmpTrem = 255; break;
}
tmpTrem = (tmpTrem * ch->tremDepth) >> 6;
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) // 8bb: actually 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++) // 8bb: 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) // 8bb: 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 doEffects(stmTyp *ch) // tick>0 effect handling
{
const uint8_t volKolEfx = ch->volKolVol >> 4;
if (volKolEfx > 0)
VJumpTab_TickNonZero[volKolEfx](ch);
if ((ch->eff == 0 && ch->effTyp == 0) || ch->effTyp > 35) return;
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;
song.songPos++;
if (song.songPos >= song.len)
song.songPos = song.repS;
song.pattNr = song.songTab[(uint8_t)song.songPos];
song.pattLen = pattLens[(uint8_t)song.pattNr];
}
}
void mainPlayer(void)
{
if (musicPaused)
return;
bool tickZero = false;
song.timer--;
if (song.timer == 0)
{
song.timer = song.tempo;
tickZero = true;
}
const bool readNewNote = tickZero && (song.pattDelTime2 == 0);
if (readNewNote)
{
const tonTyp *pattPtr = nilPatternLine;
if (patt[song.pattNr] != NULL)
pattPtr = &patt[song.pattNr][song.pattPos * song.antChn];
stmTyp *c = stm;
for (uint8_t i = 0; i < song.antChn; i++, c++, pattPtr++)
{
PMPTmpActiveChannel = i; // 8bb: for P_StartTone()
getNewNote(c, pattPtr);
fixaEnvelopeVibrato(c);
}
}
else
{
stmTyp *c = stm;
for (uint8_t i = 0; i < song.antChn; i++, c++)
{
PMPTmpActiveChannel = i; // 8bb: for P_StartTone()
doEffects(c);
fixaEnvelopeVibrato(c);
}
}
getNextPos();
}