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#include <string>
#include <cmath>
#include "note.h"
#include "globals.h"
#include "defines.h"
using namespace std;
//this function returns the smallest phase_init possible for a
//given custom_wave which is greater or equal than PHASE_INIT
inline fixed_t init_custom_osc_phase(int len, fixed_t sr)
{
return ( (fixed_t(ceil( float(PHASE_INIT) * sr / len / ONE )) *len << (2*SCALE)) / sr);
}
Note::Note(int n, float v, program_t &prg, jack_nframes_t pf, fixed_t pb, int prg_no)
{
curr_prg=&prg;
n_oscillators=prg.n_osc;
pfactor.out=new fixed_t [n_oscillators];
pfactor.fm=new fixed_t* [n_oscillators];
for (int i=0;i<n_oscillators;i++)
pfactor.fm[i]=new fixed_t [n_oscillators];
oscval=new fixed_t[n_oscillators];
old_oscval=new fixed_t[n_oscillators];
for (int i=0;i<n_oscillators;i++)
oscval[i]=old_oscval[i]=0;
envelope=new Envelope*[n_oscillators];
for (int i=0;i<n_oscillators;i++)
envelope[i]=new Envelope(prg.env_settings[i]);
oscillator=new oscillator_t[n_oscillators];
orig.oscillator=new oscillator_t[n_oscillators];
copy(&prg.osc_settings[0],&prg.osc_settings[n_oscillators],oscillator);
copy(&prg.osc_settings[0],&prg.osc_settings[n_oscillators],orig.oscillator);
//initalize oscillator.phase to multiples of their wave resolution
//this has the following effect: the actual phase, i.e. the index
//in the wave-array (wave[phase]) doesn't change, because
// (n * wave_res) % wave_res is always zero.
//however, if doing phase modulation, it's very unlikely now that
//phase ever becomes negative (which would cause the program to
//segfault, or at least to produce noise). this saves an additional
//(slow) sanity check for the phase.
for (int i=0;i<n_oscillators;i++)
{
if (oscillator[i].custom_wave)
oscillator[i].phase=init_custom_osc_phase(oscillator[i].custom_wave->wave_len, oscillator[i].custom_wave->samp_rate);
else
oscillator[i].phase=ONE * PHASE_INIT;
}
do_ksl();
filter_params=prg.filter_settings;
orig.filter_params=prg.filter_settings;
if (filter_params.enabled)
{
filter_envelope=new Envelope(
filter_params.env_settings.attack,
filter_params.env_settings.decay,
filter_params.env_settings.sustain,
filter_params.env_settings.release,
filter_params.env_settings.hold );
filter_update_counter=filter_update_frames;
}
sync_factor=prg.sync_factor;
sync_phase=0;
portamento_frames=0;
set_portamento_frames(pf);
set_note(n);
freq=dest_freq;
set_vel(v);
pitchbend=pb;
program=prg_no;
}
Note::~Note()
{
int i;
for (i=0;i<n_oscillators;i++)
{
delete [] oscillator[i].fm_strength;
delete envelope[i];
delete [] pfactor.fm[i];
}
delete [] oscillator;
delete [] envelope;
delete [] oscval;
delete [] old_oscval;
delete [] pfactor.out;
delete [] pfactor.fm;
}
void Note::recalc_factors()
{
pfactor.filter_env=calc_pfactor(curr_prg->pfactor.filter_env, vel);
pfactor.filter_res=calc_pfactor(curr_prg->pfactor.filter_res, vel);
pfactor.filter_offset=calc_pfactor(curr_prg->pfactor.filter_offset, vel);
for (int i=0;i<n_oscillators;i++)
{
pfactor.out[i]=calc_pfactor(curr_prg->pfactor.out[i], vel);
for (int j=0;j<n_oscillators;j++)
pfactor.fm[i][j]=calc_pfactor(curr_prg->pfactor.fm[i][j], vel);
}
}
void Note::apply_pfactor()
{
//apply pfactor to all necessary parameters
for (int i=0;i<n_oscillators;i++)
{
oscillator[i].output=orig.oscillator[i].output*pfactor.out[i] >>SCALE;
for (int j=0;j<n_oscillators;j++)
oscillator[i].fm_strength[j]=orig.oscillator[i].fm_strength[j]*pfactor.fm[i][j] >>SCALE;
}
filter_params.env_amount=orig.filter_params.env_amount*pfactor.filter_env /ONE;
filter_params.freqfactor_offset=orig.filter_params.freqfactor_offset*pfactor.filter_offset /ONE;
filter_params.resonance=orig.filter_params.resonance*pfactor.filter_res /ONE;
}
void Note::set_param(const parameter_t &p, fixed_t v) //ACHTUNG:
{
//wenn das verändert wird, muss auch program_t::set_param verändert werden!
switch(p.par)
{
case ATTACK: envelope[p.osc]->set_attack(v*samp_rate >>SCALE); break;
case DECAY: envelope[p.osc]->set_decay(v*samp_rate >>SCALE); break;
case SUSTAIN: envelope[p.osc]->set_sustain(v); break;
case RELEASE: envelope[p.osc]->set_release(v*samp_rate >>SCALE); break;
case HOLD: envelope[p.osc]->set_hold(v!=0); break;
case KSR: oscillator[p.osc].ksr=float(v)/ONE; break;
case KSL: oscillator[p.osc].ksl=float(v)/ONE; break;
case FACTOR: oscillator[p.osc].factor=v; break;
case MODULATION: oscillator[p.osc].fm_strength[p.index]=v*pfactor.fm[p.osc][p.index] >>SCALE; break;
case OUTPUT: oscillator[p.osc].output=v*pfactor.out[p.osc] >>SCALE; break;
case TREMOLO: oscillator[p.osc].tremolo_depth=v; break;
case TREM_LFO: oscillator[p.osc].tremolo_lfo=v; break;
case VIBRATO: oscillator[p.osc].vibrato_depth=v; break;
case VIB_LFO: oscillator[p.osc].vibrato_lfo=v; break;
case WAVEFORM: oscillator[p.osc].waveform=v; break;
case SYNC: oscillator[p.osc].sync=(v!=0); break;
case FILTER_ENABLED: output_note("NOTE: cannot enable filter in playing notes"); break;
case FILTER_ENV_AMOUNT: filter_params.env_amount=float(v*pfactor.filter_env)/ONE/ONE; break;
case FILTER_ATTACK:
if (filter_params.enabled)
filter_envelope->set_attack(v*samp_rate/filter_update_frames >>SCALE);
else
output_note("NOTE: cannot set filter-attack when filter is disabled");
break;
case FILTER_DECAY:
if (filter_params.enabled)
filter_envelope->set_decay(v*samp_rate/filter_update_frames >>SCALE);
else
output_note("NOTE: cannot set filter-decay when filter is disabled");
break;
case FILTER_SUSTAIN:
if (filter_params.enabled)
filter_envelope->set_sustain(v);
else
output_note("NOTE: cannot set filter-sustain when filter is disabled");
break;
case FILTER_RELEASE:
if (filter_params.enabled)
filter_envelope->set_release(v*samp_rate/filter_update_frames >>SCALE);
else
output_note("NOTE: cannot set filter-release when filter is disabled");
break;
case FILTER_HOLD:
if (filter_params.enabled)
filter_envelope->set_hold(v!=0);
else
output_note("NOTE: cannot set filter-hold when filter is disabled");
break;
case FILTER_OFFSET: filter_params.freqfactor_offset=float(v*pfactor.filter_offset)/ONE/ONE; break;
case FILTER_RESONANCE: filter_params.resonance=float(v*pfactor.filter_res)/ONE/ONE; break;
case FILTER_TREMOLO: filter_params.trem_strength=v; break;
case FILTER_TREM_LFO: filter_params.trem_lfo=v; break;
case SYNC_FACTOR: sync_factor=v; break;
default: throw string("trying to set an unknown parameter");
}
}
bool Note::still_active()
{
for (int i=0; i<n_oscillators; i++)
if ((oscillator[i].output>0) && (envelope[i]->still_active()))
return true;
return false;
}
//this function must still work properly if called multiple times
//when called a second time, there shall be no effect
void Note::release_quickly(jack_nframes_t maxt)
{
for (int i=0;i<n_oscillators;i++)
{
if (envelope[i]->get_release() > maxt)
envelope[i]->set_release(maxt);
envelope[i]->release_key();
// i don't release the filter-env because lacking to do so
// does not generate a hearable difference (or would you hear
// when in the last half second a tone is filtered or not?)
}
}
void Note::release()
{
for (int i=0;i<n_oscillators;i++)
envelope[i]->release_key();
if (filter_params.enabled)
filter_envelope->release_key();
}
void Note::reattack()
{
for (int i=0;i<n_oscillators;i++)
envelope[i]->reattack();
}
void Note::do_ksl()
{ //osc.ksl is in Bel/octave (i.e. dB/10)
//if ksl=1, this means that for each octave the loudness
//decreases by half
for (int i=0;i<n_oscillators;i++)
{
if (oscillator[i].ksl==0)
envelope[i]->set_max(ONE);
else
envelope[i]->set_max( fixed_t(double(ONE) / pow(freq>>SCALE, oscillator[i].ksl)) );
}
}
void Note::do_ksr()
{
for (int i=0;i<n_oscillators;i++)
envelope[i]->set_ratefactor(1.0 / pow(freq>>SCALE, oscillator[i].ksr));
}
fixed_t Note::get_sample()
{
if (freq!=dest_freq)
{
// the div.by.zero if p_frames=0 is avoided because then the
// if-condition below is always true
if (portamento_t>=portamento_frames)
freq=dest_freq;
else //will only happen if p_t < p_frames -> p_frames is always > 0 -> div. ok
freq = old_freq + (dest_freq-old_freq)*portamento_t/portamento_frames;
do_ksl();
portamento_t++;
}
fixed_t actual_freq=freq*pitchbend >>SCALE;
fixed_t *temp;
temp=old_oscval; //swap the current and old oscval-pointers
old_oscval=oscval;
oscval=temp;
fixed_t fm=0;
fixed_t out=0;
int i,j;
if (sync_factor)
{
sync_phase+=(actual_freq*sync_factor/samp_rate) >> SCALE;
if (sync_phase >= ONE)
{
sync_phase-=ONE;
for (i=0;i<n_oscillators;i++)
if (oscillator[i].sync)
{
if (oscillator[i].custom_wave)
oscillator[i].phase=init_custom_osc_phase(oscillator[i].custom_wave->wave_len, oscillator[i].custom_wave->samp_rate);
else
oscillator[i].phase=ONE * PHASE_INIT;
}
}
}
for (i=0;i<n_oscillators;i++)
{
fm=0;
oscval[i]=0;
for (j=0;j<n_oscillators;j++)
if (oscillator[i].fm_strength[j]!=0) //osc_j affects osc_i (FM)
fm+=(old_oscval[j]*oscillator[i].fm_strength[j])>>SCALE;
//phase increases in one second, i.e. in samp_rate frames, by the osc's freq
if (oscillator[i].vibrato_depth!=0)
oscillator[i].phase+=( (curr_lfo[oscillator[i].vibrato_lfo][oscillator[i].vibrato_depth]*actual_freq >>SCALE)*oscillator[i].factor/samp_rate)>>SCALE;
else
oscillator[i].phase+=(actual_freq*oscillator[i].factor/samp_rate)>>SCALE;
if (oscillator[i].custom_wave)
{
//sampler
custom_wave_t *cw=oscillator[i].custom_wave;
oscval[i]=cw->wave[ ((oscillator[i].phase + fm) * cw->samp_rate >>(2*SCALE)) % cw->wave_len ] * envelope[i]->get_level() >> (SCALE);
}
else
{
//normal oscillator
oscval[i]=wave[oscillator[i].waveform][ ((oscillator[i].phase + fm) * WAVE_RES >>SCALE) % WAVE_RES ] * envelope[i]->get_level() >> (SCALE);
}
if (oscillator[i].tremolo_depth!=0)
oscval[i]=oscval[i]* curr_lfo[oscillator[i].tremolo_lfo][oscillator[i].tremolo_depth] >> SCALE;
if (oscillator[i].output!=0)
out+=oscillator[i].output*oscval[i] >>SCALE;
}
if (filter_params.enabled)
{
filter_update_counter++;
if (filter_update_counter>=filter_update_frames)
{
filter_update_counter=0;
float cutoff= float(actual_freq)/ONE *
float(curr_lfo[filter_params.trem_lfo][filter_params.trem_strength])/ONE *
( filter_params.freqfactor_offset + filter_envelope->get_level() * filter_params.env_amount / float(ONE) );
filter.set_params( cutoff, filter_params.resonance );
}
fixed_t tmp=out;
filter.process_sample(&tmp);
return tmp;
}
else
{
return out;
}
}
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