static STREAM_UPDATE( s14001a_pcm_update )
{
INT32 mix[48000];
//INT32 *mixp;
S14001AChip *chip = (S14001AChip *)param;
int i;
memset(mix, 0, sizeof(mix));
//mixp = &mix[0];
for (i = 0; i < samples; i++)
{
s14001a_clock(chip);
#ifdef ACCURATE_SQUEAL
if (chip->audioout == ALTFLAG) // input from test pins -> output
{
shiftIntoFilter(chip, audiofilter(chip)); // shift over the previous outputs and stick in audioout.
outputs[0][i] = audiofilter(chip)*chip->VSU1000_amp;
}
else // normal, dac-driven output
{
shiftIntoFilter(chip, ((((INT16)chip->audioout)-8)<<9)); // shift over the previous outputs and stick in audioout 4 times. note <<9 instead of <<10, to prevent clipping, and to simulate that the filtered output normally has a somewhat lower amplitude than the driven one.
#endif
outputs[0][i] = ((((INT16)chip->audioout)-8)<<10)*chip->VSU1000_amp;
#ifdef ACCURATE_SQUEAL
}
#endif
}
}
void s14001a_device::sound_stream_update(sound_stream &stream, stream_sample_t **inputs, stream_sample_t **outputs, int samples)
{
int i;
for (i = 0; i < samples; i++)
{
s14001a_clock();
#ifdef ACCURATE_SQUEAL
if (m_audioout == ALTFLAG) // input from test pins -> output
{
shiftIntoFilter(chip, audiofilter(chip)); // shift over the previous outputs and stick in audioout.
outputs[0][i] = audiofilter(chip)*m_VSU1000_amp;
}
else // normal, dac-driven output
{
shiftIntoFilter(chip, ((((INT16)m_audioout)-8)<<9)); // shift over the previous outputs and stick in audioout 4 times. note <<9 instead of <<10, to prevent clipping, and to simulate that the filtered output normally has a somewhat lower amplitude than the driven one.
#endif
outputs[0][i] = ((((INT16)m_audioout)-8)<<10)*m_VSU1000_amp;
#ifdef ACCURATE_SQUEAL
}
#endif
}
}
void s14001a_clock(void) /* called once per clock */
{
UINT8 CurDelta; // Current delta
/* on even clocks, audio output is floating, /romen is low so rom data bus is driven, input is latched?
* on odd clocks, audio output is driven, /romen is high, state machine 2 is clocked */
oddeven = !(oddeven); // invert the clock
if (oddeven == 0) // even clock
{
audioout = audiofilter(); // function to handle output filtering by internal capacitance based on clock speed and such
#ifdef PINMAME
if (!machineState) audioout = SILENCE;
#endif
shiftIntoFilter(audioout); // shift over all the filter outputs and stick in audioout
}
else // odd clock
{
// fix dac output between samples. theoretically this might be unnecessary but it would require some messy logic in state 5 on the first sample load.
if (GlobalSilenceState || LOCALSILENCESTATE)
{
DACOutput = SILENCE;
OldDelta = 2;
}
audioout = (GlobalSilenceState || LOCALSILENCESTATE) ? SILENCE : DACOutput; // when either silence state is 1, output silence.
#ifdef PINMAME
if (!machineState) audioout = SILENCE;
#endif
shiftIntoFilter(audioout); // shift over all the filter outputs and stick in audioout
switch(machineState)
{
case 0: // idle state
nextstate = 0;
break;
case 1: // read starting syllable high byte from word table
SyllableAddress = 0; // clear syllable address
SyllableAddress |= s14001a_readmem(LatchedWord<<1)<<4;
nextstate = resetState ? 1 : 2;
break;
case 2: // read starting syllable low byte from word table
SyllableAddress |= s14001a_readmem((LatchedWord<<1)+1)>>4;
nextstate = 3;
break;
case 3: // read starting phone address
PhoneAddress = s14001a_readmem(SyllableAddress)<<4;
nextstate = 4;
break;
case 4: // read playback parameters and prepare for play
PlayParams = s14001a_readmem(SyllableAddress+1);
GlobalSilenceState = SILENCEFLAG; // load phone silence flag
LengthCounter = LENGTHCOUNT; // load length counter
RepeatCounter = REPEATCOUNT; // load repeat counter
OutputCounter = 0; // clear output counter and disable mirrored phoneme silence indirectly via LOCALSILENCESTATE
PhoneOffset = 0; // set offset within phone to zero
OldDelta = 0x2; // set old delta to 2 <- is this right?
DACOutput = 0x88; // set DAC output to center/silence position (0x88)
nextstate = 5;
break;
case 5: // Play phone forward, shift = 0 (also load)
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0xc0)>>6; // grab current delta from high 2 bits of high nybble
DACOutput += DeltaTable[CurDelta][OldDelta]; // send data to forward delta table and add result to accumulator
OldDelta = CurDelta; // Move current delta to old
nextstate = 6;
break;
case 6: // Play phone forward, shift = 2
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0x30)>>4; // grab current delta from low 2 bits of high nybble
DACOutput += DeltaTable[CurDelta][OldDelta]; // send data to forward delta table and add result to accumulator
OldDelta = CurDelta; // Move current delta to old
nextstate = 7;
break;
case 7: // Play phone forward, shift = 4
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0xc)>>2; // grab current delta from high 2 bits of low nybble
DACOutput += DeltaTable[CurDelta][OldDelta]; // send data to forward delta table and add result to accumulator
OldDelta = CurDelta; // Move current delta to old
nextstate = 8;
break;
case 8: // Play phone forward, shift = 6 (increment address if needed)
CurDelta = s14001a_readmem((PhoneAddress)+PhoneOffset)&0x3; // grab current delta from low 2 bits of low nybble
DACOutput += DeltaTable[CurDelta][OldDelta]; // send data to forward delta table and add result to accumulator
OldDelta = CurDelta; // Move current delta to old
PhoneOffset++; // increment phone offset
if (PhoneOffset == 0x8) // if we're now done this phone
{
/* call the PostPhoneme Function */
PostPhoneme();
}
else
{
nextstate = 5;
}
break;
case 9: // Play phone backward, shift = 6 (also load)
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0x3); // grab current delta from low 2 bits of low nybble
if (laststate != 8) // ignore first (bogus) dac change in mirrored backwards mode. observations and the patent show this.
{
DACOutput -= DeltaTable[OldDelta][CurDelta]; // send data to forward delta table and subtract result from accumulator
}
OldDelta = CurDelta; // Move current delta to old
nextstate = 10;
break;
case 10: // Play phone backward, shift = 4
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0xc)>>2; // grab current delta from high 2 bits of low nybble
DACOutput -= DeltaTable[OldDelta][CurDelta]; // send data to forward delta table and subtract result from accumulator
OldDelta = CurDelta; // Move current delta to old
nextstate = 11;
break;
case 11: // Play phone backward, shift = 2
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0x30)>>4; // grab current delta from low 2 bits of high nybble
DACOutput -= DeltaTable[OldDelta][CurDelta]; // send data to forward delta table and subtract result from accumulator
OldDelta = CurDelta; // Move current delta to old
nextstate = 12;
break;
case 12: // Play phone backward, shift = 0 (increment address if needed)
CurDelta = (s14001a_readmem((PhoneAddress)+PhoneOffset)&0xc0)>>6; // grab current delta from high 2 bits of high nybble
DACOutput -= DeltaTable[OldDelta][CurDelta]; // send data to forward delta table and subtract result from accumulator
OldDelta = CurDelta; // Move current delta to old
PhoneOffset--; // decrement phone offset
if (PhoneOffset == 0xFF) // if we're now done this phone
{
/* call the PostPhoneme() function */
PostPhoneme();
}
else
{
nextstate = 9;
}
break;
case 13: // For those pedantic among us, consume an extra two clocks like the real chip does.
nextstate = 0;
break;
}
#ifdef DEBUGSTATE
fprintf(stderr, "Machine state is now %d, was %d, PhoneOffset is %d\n", nextstate, machineState, PhoneOffset);
#endif
laststate = machineState;
machineState = nextstate;
}
}
