// The gate bit is handled by the EnvelopeGenerator.
public WaveformGenerator()
{
sync_source = this;
set_chip_model(SIDDefs.chip_model.MOS6581);
reset();
}
public Voice()
{
wave = new WaveformGenerator();
envelope = new EnvelopeGenerator();
muted = false;
set_chip_model(SIDDefs.chip_model.MOS6581);
}
// deserializing
protected void LoadFromReader(BinaryReader reader)
{
wave = new WaveformGenerator(reader);
envelope = new EnvelopeGenerator(reader);
muted = reader.ReadBoolean();
wave_zero = reader.ReadInt32();
voice_DC = reader.ReadInt32();
}
public void UpdateAfterLoad(Voice v0, Voice v1, Voice v2)
{
switch (sync_source_id)
{
case 0:
sync_source = v0.wave;
break;
case 1:
sync_source = v1.wave;
break;
case 2:
sync_source = v2.wave;
break;
default:
#if DEBUG
throw new Exception("unknown Source_WaveID: " + sync_source_id.ToString());
#endif
case -1:
sync_source = null;
break;
}
switch (sync_dest_id)
{
case 0:
sync_dest = v0.wave;
break;
case 1:
sync_dest = v1.wave;
break;
case 2:
sync_dest = v2.wave;
break;
default:
#if DEBUG
throw new Exception("unknown Dest_WaveID: " + sync_dest_id.ToString());
#endif
case -1:
sync_dest = null;
break;
}
}
/// <summary>
/// SID clocking - delta_t cycles
/// </summary>
/// <param name="delta_t"></param>
public void clock(int delta_t)
{
if (delta_t <= 0)
{
return;
}
// Age bus value.
bus_value_ttl -= delta_t;
if (bus_value_ttl <= 0)
{
bus_value = 0;
bus_value_ttl = 0;
}
// Clock amplitude modulators.
voice0.envelope.clock(delta_t);
voice1.envelope.clock(delta_t);
voice2.envelope.clock(delta_t);
// Clock and synchronize oscillators.
// Loop until we reach the current cycle.
int delta_t_osc = delta_t;
while (delta_t_osc != 0)
{
int delta_t_min = delta_t_osc;
// Find minimum number of cycles to an oscillator accumulator MSB toggle.
// We have to clock on each MSB on / MSB off for hard sync to operate correctly.
WaveformGenerator wave = voice0.wave;
// It is only necessary to clock on the MSB of an oscillator
// that is a sync source and has freq != 0.
if ((wave.sync_dest.sync != 0) && (wave.freq != 0))
{
int freq = wave.freq;
int accumulator = wave.accumulator;
// Clock on MSB off if MSB is on, clock on MSB on if MSB is off.
int delta_accumulator = ((accumulator & 0x800000) != 0 ? 0x1000000 : 0x800000) - accumulator;
int delta_t_next = (delta_accumulator / freq);
if ((delta_accumulator % freq) != 0)
{
++delta_t_next;
}
if (delta_t_next < delta_t_min)
{
delta_t_min = delta_t_next;
}
}
wave = voice1.wave;
// It is only necessary to clock on the MSB of an oscillator
// that is a sync source and has freq != 0.
if ((wave.sync_dest.sync != 0) && (wave.freq != 0))
{
int freq = wave.freq;
int accumulator = wave.accumulator;
// Clock on MSB off if MSB is on, clock on MSB on if MSB is off.
int delta_accumulator = ((accumulator & 0x800000) != 0 ? 0x1000000 : 0x800000) - accumulator;
int delta_t_next = (delta_accumulator / freq);
if ((delta_accumulator % freq) != 0)
{
++delta_t_next;
}
if (delta_t_next < delta_t_min)
{
delta_t_min = delta_t_next;
}
}
wave = voice2.wave;
// It is only necessary to clock on the MSB of an oscillator
// that is a sync source and has freq != 0.
if ((wave.sync_dest.sync != 0) && (wave.freq != 0))
{
int freq = wave.freq;
int accumulator = wave.accumulator;
// Clock on MSB off if MSB is on, clock on MSB on if MSB is off.
int delta_accumulator = ((accumulator & 0x800000) != 0 ? 0x1000000 : 0x800000) - accumulator;
int delta_t_next = (delta_accumulator / freq);
if ((delta_accumulator % freq) != 0)
{
++delta_t_next;
}
if (delta_t_next < delta_t_min)
{
delta_t_min = delta_t_next;
}
}
// Clock oscillators.
voice0.wave.clock(delta_t_min);
voice1.wave.clock(delta_t_min);
voice2.wave.clock(delta_t_min);
// Synchronize oscillators.
voice0.wave.synchronize();
voice1.wave.synchronize();
voice2.wave.synchronize();
delta_t_osc -= delta_t_min;
}
// Clock filter.
filter.clock(delta_t, voice0.output, voice1.output, voice2.output, ext_in);
// Clock external filter.
extfilt.clock(delta_t, filter.output);
}
public State read_state()
{
State state = new State();
int j = 0;
WaveformGenerator wave = voice0.wave;
EnvelopeGenerator envelope = voice0.envelope;
state.sid_register[j + 0] = (char)(wave.freq & 0xff);
state.sid_register[j + 1] = (char)(wave.freq >> 8);
state.sid_register[j + 2] = (char)(wave.pw & 0xff);
state.sid_register[j + 3] = (char)(wave.pw >> 8);
state.sid_register[j + 4] = (char)((wave.waveform << 4) | ((wave.test != 0) ? 0x08 : 0) | ((wave.ring_mod != 0) ? 0x04 : 0) | ((wave.sync != 0) ? 0x02 : 0) | ((envelope.gate != 0) ? 0x01 : 0));
state.sid_register[j + 5] = (char)((envelope.attack << 4) | envelope.decay);
state.sid_register[j + 6] = (char)((envelope.sustain << 4) | envelope.release);
j++;
wave = voice1.wave;
envelope = voice1.envelope;
state.sid_register[j + 0] = (char)(wave.freq & 0xff);
state.sid_register[j + 1] = (char)(wave.freq >> 8);
state.sid_register[j + 2] = (char)(wave.pw & 0xff);
state.sid_register[j + 3] = (char)(wave.pw >> 8);
state.sid_register[j + 4] = (char)((wave.waveform << 4) | ((wave.test != 0) ? 0x08 : 0) | ((wave.ring_mod != 0) ? 0x04 : 0) | ((wave.sync != 0) ? 0x02 : 0) | ((envelope.gate != 0) ? 0x01 : 0));
state.sid_register[j + 5] = (char)((envelope.attack << 4) | envelope.decay);
state.sid_register[j + 6] = (char)((envelope.sustain << 4) | envelope.release);
j++;
wave = voice2.wave;
envelope = voice2.envelope;
state.sid_register[j + 0] = (char)(wave.freq & 0xff);
state.sid_register[j + 1] = (char)(wave.freq >> 8);
state.sid_register[j + 2] = (char)(wave.pw & 0xff);
state.sid_register[j + 3] = (char)(wave.pw >> 8);
state.sid_register[j + 4] = (char)((wave.waveform << 4) | ((wave.test != 0) ? 0x08 : 0) | ((wave.ring_mod != 0) ? 0x04 : 0) | ((wave.sync != 0) ? 0x02 : 0) | ((envelope.gate != 0) ? 0x01 : 0));
state.sid_register[j + 5] = (char)((envelope.attack << 4) | envelope.decay);
state.sid_register[j + 6] = (char)((envelope.sustain << 4) | envelope.release);
state.sid_register[j++] = (char)(filter.fc & 0x007);
state.sid_register[j++] = (char)(filter.fc >> 3);
state.sid_register[j++] = (char)((filter.res << 4) | filter.filt);
state.sid_register[j++] = (char)(((filter.voice3off != 0) ? 0x80 : 0) | (filter.hp_bp_lp << 4) | filter.vol);
// These registers are superfluous, but included for completeness.
for (; j < 0x1d; j++)
{
state.sid_register[j] = (char)(read(j));
}
for (; j < 0x20; j++)
{
state.sid_register[j] = (char)0;
}
state.bus_value = bus_value;
state.bus_value_ttl = bus_value_ttl;
state.accumulator0 = voice0.wave.accumulator;
state.shift_register0 = voice0.wave.shift_register;
state.rate_counter0 = voice0.envelope.rate_counter;
state.rate_counter_period0 = voice0.envelope.rate_period;
state.exponential_counter0 = voice0.envelope.exponential_counter;
state.exponential_counter_period0 = voice0.envelope.exponential_counter_period;
state.envelope_counter0 = voice0.envelope.envelope_counter;
state.envelope_state0 = voice0.envelope.state;
state.hold_zero0 = voice0.envelope.hold_zero;
state.accumulator1 = voice1.wave.accumulator;
state.shift_register1 = voice1.wave.shift_register;
state.rate_counter1 = voice1.envelope.rate_counter;
state.rate_counter_period1 = voice1.envelope.rate_period;
state.exponential_counter1 = voice1.envelope.exponential_counter;
state.exponential_counter_period1 = voice1.envelope.exponential_counter_period;
state.envelope_counter1 = voice1.envelope.envelope_counter;
state.envelope_state1 = voice1.envelope.state;
state.hold_zero1 = voice1.envelope.hold_zero;
state.accumulator2 = voice2.wave.accumulator;
state.shift_register2 = voice2.wave.shift_register;
state.rate_counter2 = voice2.envelope.rate_counter;
state.rate_counter_period2 = voice2.envelope.rate_period;
state.exponential_counter2 = voice2.envelope.exponential_counter;
state.exponential_counter_period2 = voice2.envelope.exponential_counter_period;
state.envelope_counter2 = voice2.envelope.envelope_counter;
state.envelope_state2 = voice2.envelope.state;
state.hold_zero2 = voice2.envelope.hold_zero;
return(state);
}
public void set_sync_source(WaveformGenerator source)
{
sync_source = source;
source.sync_dest = this;
}
