ref: ad69b23d21b20df735bb9fb2bccad7ab0c907f07
dir: /LEAF/Src/leaf-reverb.c/
/*==============================================================================
leaf-reverb.c
Created: 20 Jan 2017 12:02:04pm
Author: Michael R Mulshine
==============================================================================*/
#if _WIN32 || _WIN64
#include "..\Inc\leaf-reverb.h"
#include "..\leaf.h"
#else
#include "../Inc/leaf-reverb.h"
#include "../leaf.h"
#endif
// ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ PRCRev ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ //
void tPRCRev_init(tPRCRev* const r, float t60)
{
if (t60 <= 0.0f) t60 = 0.001f;
r->inv_441 = 1.0f/44100.0f;
int lengths[4] = { 341, 613, 1557, 2137 }; // Delay lengths for 44100 Hz sample rate.
double scaler = leaf.sampleRate * r->inv_441;
int delay, i;
if (scaler != 1.0f)
{
for (i=0; i<4; i++)
{
delay = (int) scaler * lengths[i];
if ( (delay & 1) == 0) delay++;
while ( !LEAF_isPrime(delay) ) delay += 2;
lengths[i] = delay;
}
}
r->allpassDelays[0] = (tDelay*) leaf_alloc(sizeof(tDelay));
tDelay_init(r->allpassDelays[0], lengths[0], lengths[0] * 2);
r->allpassDelays[1] = (tDelay*) leaf_alloc(sizeof(tDelay));
tDelay_init(r->allpassDelays[1], lengths[1], lengths[1] * 2);
r->combDelay = (tDelay*) leaf_alloc(sizeof(tDelay));
tDelay_init(r->combDelay, lengths[2], lengths[2] * 2);
tPRCRev_setT60(r, t60);
r->allpassCoeff = 0.7f;
r->mix = 0.5f;
}
void tPRCRev_free(tPRCRev* const r)
{
tDelay_free(r->allpassDelays[0]);
tDelay_free(r->allpassDelays[1]);
tDelay_free(r->combDelay);
leaf_free(r);
}
void tPRCRev_setT60(tPRCRev* const r, float t60)
{
if ( t60 <= 0.0f ) t60 = 0.001f;
r->t60 = t60;
r->combCoeff = pow(10.0f, (-3.0f * tDelay_getDelay(r->combDelay) * leaf.invSampleRate / t60 ));
}
void tPRCRev_setMix(tPRCRev* const r, float mix)
{
r->mix = mix;
}
float tPRCRev_tick(tPRCRev* const r, float input)
{
float temp, temp0, temp1, temp2;
float out;
r->lastIn = input;
temp = tDelay_getLastOut(r->allpassDelays[0]);
temp0 = r->allpassCoeff * temp;
temp0 += input;
tDelay_tick(r->allpassDelays[0], temp0);
temp0 = -( r->allpassCoeff * temp0) + temp;
temp = tDelay_getLastOut(r->allpassDelays[1]);
temp1 = r->allpassCoeff * temp;
temp1 += temp0;
tDelay_tick(r->allpassDelays[1], temp1);
temp1 = -(r->allpassCoeff * temp1) + temp;
temp2 = temp1 + ( r->combCoeff * tDelay_getLastOut(r->combDelay));
out = r->mix * tDelay_tick(r->combDelay, temp2);
temp = (1.0f - r->mix) * input;
out += temp;
r->lastOut = out;
return out;
}
void tPRCRevSampleRateChanged (tPRCRev* const r)
{
r->combCoeff = pow(10.0f, (-3.0f * tDelay_getDelay(r->combDelay) * leaf.invSampleRate / r->t60 ));
}
/* ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ NRev ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ */
void tNRev_init(tNRev* const r, float t60)
{
if (t60 <= 0.0f) t60 = 0.001f;
r->inv_441 = 1.0f/44100.0f;
int lengths[15] = {1433, 1601, 1867, 2053, 2251, 2399, 347, 113, 37, 59, 53, 43, 37, 29, 19}; // Delay lengths for 44100 Hz sample rate.
double scaler = leaf.sampleRate / 25641.0f;
int delay, i;
for (i=0; i < 15; i++)
{
delay = (int) scaler * lengths[i];
if ( (delay & 1) == 0)
delay++;
while ( !LEAF_isPrime(delay) )
delay += 2;
lengths[i] = delay;
}
for ( i=0; i<6; i++ )
{
r->combDelays[i] = (tDelay*) leaf_alloc(sizeof(tDelay));
tDelay_init(r->combDelays[i], lengths[i], lengths[i] * 2.0f);
r->combCoeffs[i] = pow(10.0, (-3 * lengths[i] * leaf.invSampleRate / t60));
}
for ( i=0; i<8; i++ )
{
r->allpassDelays[i] = (tDelay*) leaf_alloc(sizeof(tDelay));
tDelay_init(r->allpassDelays[i], lengths[i+6], lengths[i+6] * 2.0f);
}
for ( i=0; i<2; i++ )
{
tDelay_setDelay(r->allpassDelays[i], lengths[i]);
tDelay_setDelay(r->combDelays[i], lengths[i+2]);
}
tNRev_setT60(r, t60);
r->allpassCoeff = 0.7f;
r->mix = 0.3f;
}
void tNRev_free(tNRev* const r)
{
for (int i = 0; i < 6; i++)
{
tDelay_free(r->combDelays[i]);
}
for (int i = 0; i < 8; i++)
{
tDelay_free(r->allpassDelays[i]);
}
leaf_free(r);
}
void tNRev_setT60(tNRev* const r, float t60)
{
if (t60 <= 0.0f) t60 = 0.001f;
r->t60 = t60;
for (int i=0; i<6; i++) r->combCoeffs[i] = pow(10.0, (-3.0 * tDelay_getDelay(r->combDelays[i]) * leaf.invSampleRate / t60 ));
}
void tNRev_setMix(tNRev* const r, float mix)
{
r->mix = mix;
}
float tNRev_tick(tNRev* const r, float input)
{
r->lastIn = input;
float temp, temp0, temp1, temp2, out;
int i;
temp0 = 0.0;
for ( i=0; i<6; i++ )
{
temp = input + (r->combCoeffs[i] * tDelay_getLastOut(r->combDelays[i]));
temp0 += tDelay_tick(r->combDelays[i],temp);
}
for ( i=0; i<3; i++ )
{
temp = tDelay_getLastOut(r->allpassDelays[i]);
temp1 = r->allpassCoeff * temp;
temp1 += temp0;
tDelay_tick(r->allpassDelays[i], temp1);
temp0 = -(r->allpassCoeff * temp1) + temp;
}
// One-pole lowpass filter.
r->lowpassState = 0.7f * r->lowpassState + 0.3f * temp0;
temp = tDelay_getLastOut(r->allpassDelays[3]);
temp1 = r->allpassCoeff * temp;
temp1 += r->lowpassState;
tDelay_tick(r->allpassDelays[3], temp1 );
temp1 = -(r->allpassCoeff * temp1) + temp;
temp = tDelay_getLastOut(r->allpassDelays[4]);
temp2 = r->allpassCoeff * temp;
temp2 += temp1;
tDelay_tick(r->allpassDelays[4], temp2 );
out = r->mix * ( -( r->allpassCoeff * temp2 ) + temp );
/*
temp = tDelayLGetLastOut(&r->allpassDelays[5]);
temp3 = r->allpassCoeff * temp;
temp3 += temp1;
tDelayLTick(&r->allpassDelays[5], temp3 );
lastFrame_[1] = effectMix_*( - ( r->allpassCoeff * temp3 ) + temp );
*/
temp = ( 1.0f - r->mix ) * input;
out += temp;
r->lastOut = out;
return out;
}
void tNRevSampleRateChanged (tNRev* const r)
{
for (int i=0; i<6; i++) r->combCoeffs[i] = pow(10.0, (-3.0 * tDelay_getDelay(r->combDelays[i]) * leaf.invSampleRate / r->t60 ));
}
// ======================================DATTORRO=========================================
#define SAMP(in) (in*r->t)
float in_allpass_delays[4] = { 4.771f, 3.595f, 12.73f, 9.307f };
float in_allpass_gains[4] = { 0.75f, 0.75f, 0.625f, 0.625f };
void tDattorro_init (tDattorro* const r)
{
r->size_max = 2.0f;
r->size = 1.f;
r->t = r->size * leaf.sampleRate * 0.001f;
// INPUT
tTapeDelay_init(&r->in_delay, 0.f, SAMP(200.f));
tOnePole_init(&r->in_filter, 1.f);
for (int i = 0; i < 4; i++)
{
tAllpass_init(&r->in_allpass[i], SAMP(in_allpass_delays[i]), SAMP(20.f)); // * r->size_max
tAllpass_setGain(&r->in_allpass[i], in_allpass_gains[i]);
}
// FEEDBACK 1
tAllpass_init(&r->f1_allpass, SAMP(30.51f), SAMP(100.f)); // * r->size_max
tAllpass_setGain(&r->f1_allpass, 0.7f);
tTapeDelay_init(&r->f1_delay_1, SAMP(141.69f), SAMP(200.0f) * r->size_max + 1);
tTapeDelay_init(&r->f1_delay_2, SAMP(89.24f), SAMP(100.0f) * r->size_max + 1);
tTapeDelay_init(&r->f1_delay_3, SAMP(125.f), SAMP(200.0f) * r->size_max + 1);
tOnePole_init(&r->f1_filter, 1.f);
tHighpass_init(&r->f1_hp, 20.f);
tCycle_init(&r->f1_lfo);
tCycle_setFreq(&r->f1_lfo, 0.1f);
// FEEDBACK 2
tAllpass_init(&r->f2_allpass, SAMP(22.58f), SAMP(100.f)); // * r->size_max
tAllpass_setGain(&r->f2_allpass, 0.7f);
tTapeDelay_init(&r->f2_delay_1, SAMP(149.62f), SAMP(200.f) * r->size_max + 1);
tTapeDelay_init(&r->f2_delay_2, SAMP(60.48f), SAMP(100.f) * r->size_max + 1);
tTapeDelay_init(&r->f2_delay_3, SAMP(106.28f), SAMP(200.f) * r->size_max + 1);
tOnePole_init(&r->f2_filter, 1.f);
tHighpass_init(&r->f2_hp, 20.f);
tCycle_init(&r->f2_lfo);
tCycle_setFreq(&r->f2_lfo, 0.07f);
// PARAMETERS
tDattorro_setMix(r, 0.5f);
tDattorro_setInputDelay(r, 0.f);
tDattorro_setInputFilter(r, 10000.f);
tDattorro_setFeedbackFilter(r, 5000.f);
tDattorro_setFeedbackGain(r, 0.4f);
}
void tDattorro_free (tDattorro* const r)
{
// INPUT
tTapeDelay_free(&r->in_delay);
tOnePole_free(&r->in_filter);
for (int i = 0; i < 4; i++)
{
tAllpass_free(&r->in_allpass[i]);
}
// FEEDBACK 1
tAllpass_free(&r->f1_allpass);
tTapeDelay_free(&r->f1_delay_1);
tTapeDelay_free(&r->f1_delay_2);
tTapeDelay_free(&r->f1_delay_3);
tOnePole_free(&r->f1_filter);
tCycle_free(&r->f1_lfo);
// FEEDBACK 2
tAllpass_free(&r->f2_allpass);
tTapeDelay_free(&r->f2_delay_1);
tTapeDelay_free(&r->f2_delay_2);
tTapeDelay_free(&r->f2_delay_3);
tOnePole_free(&r->f2_filter);
tCycle_free(&r->f2_lfo);
leaf_free(r);
}
float tDattorro_tick (tDattorro* const r, float input)
{
// INPUT
float in_sample = tTapeDelay_tick(&r->in_delay, input);
in_sample = tOnePole_tick(&r->in_filter, in_sample);
for (int i = 0; i < 4; i++)
{
in_sample = tAllpass_tick(&r->in_allpass[i], in_sample);
}
// FEEDBACK 1
float f1_sample = in_sample + r->f2_last; // + f2_last_out;
tAllpass_setDelay(&r->f1_allpass, SAMP(30.51f) + tCycle_tick(&r->f1_lfo) * SAMP(4.0f));
f1_sample = tAllpass_tick(&r->f1_allpass, f1_sample);
f1_sample = tTapeDelay_tick(&r->f1_delay_1, f1_sample);
f1_sample = tOnePole_tick(&r->f1_filter, f1_sample);
f1_sample = f1_sample + r->f1_delay_2_last * 0.5f;
float f1_delay_2_sample = tTapeDelay_tick(&r->f1_delay_2, f1_sample * 0.5f);
r->f1_delay_2_last = f1_delay_2_sample;
f1_sample = r->f1_delay_2_last + f1_sample;
f1_sample = tHighpass_tick(&r->f1_hp, f1_sample);
f1_sample *= r->feedback_gain;
r->f1_last = tTapeDelay_tick(&r->f1_delay_3, f1_sample);
// FEEDBACK 2
float f2_sample = in_sample + r->f1_last;
tAllpass_setDelay(&r->f2_allpass, SAMP(22.58f) + tCycle_tick(&r->f2_lfo) * SAMP(4.0f));
f2_sample = tAllpass_tick(&r->f2_allpass, f2_sample);
f2_sample = tTapeDelay_tick(&r->f2_delay_1, f2_sample);
f2_sample = tOnePole_tick(&r->f2_filter, f2_sample);
f2_sample = f2_sample + r->f2_delay_2_last * 0.5f;
float f2_delay_2_sample = tTapeDelay_tick(&r->f2_delay_2, f2_sample * 0.5f);
r->f2_delay_2_last = f2_delay_2_sample;
f2_sample = r->f2_delay_2_last + f2_sample;
f2_sample = tHighpass_tick(&r->f2_hp, f2_sample);
f2_sample *= r->feedback_gain;
r->f2_last = tTapeDelay_tick(&r->f2_delay_3, f2_sample);
// TAP OUT 1
f1_sample = tTapeDelay_tapOut(&r->f1_delay_1, SAMP(8.9f)) +
tTapeDelay_tapOut(&r->f1_delay_1, SAMP(99.8f));
f1_sample -= tTapeDelay_tapOut(&r->f1_delay_2, SAMP(64.2f));
f1_sample += tTapeDelay_tapOut(&r->f1_delay_3, SAMP(67.f));
f1_sample -= tTapeDelay_tapOut(&r->f2_delay_1, SAMP(66.8f));
f1_sample -= tTapeDelay_tapOut(&r->f2_delay_2, SAMP(6.3f));
f1_sample -= tTapeDelay_tapOut(&r->f2_delay_3, SAMP(35.8f));
f1_sample *= 0.14f;
// TAP OUT 2
f2_sample = tTapeDelay_tapOut(&r->f2_delay_1, SAMP(11.8f)) +
tTapeDelay_tapOut(&r->f2_delay_1, SAMP(121.7f));
f2_sample -= tTapeDelay_tapOut(&r->f2_delay_2, SAMP(6.3f));
f2_sample += tTapeDelay_tapOut(&r->f2_delay_3, SAMP(89.7f));
f2_sample -= tTapeDelay_tapOut(&r->f1_delay_1, SAMP(70.8f));
f2_sample -= tTapeDelay_tapOut(&r->f1_delay_2, SAMP(11.2f));
f2_sample -= tTapeDelay_tapOut(&r->f1_delay_3, SAMP(4.1f));
f2_sample *= 0.14f;
float sample = (f1_sample + f2_sample) * 0.5f;
return (input * (1.0f - r->mix) + sample * r->mix);
}
void tDattorro_setMix (tDattorro* const r, float mix)
{
r->mix = LEAF_clip(0.0f, mix, 1.0f);
}
void tDattorro_setSize (tDattorro* const r, float size)
{
r->size = LEAF_clip(0.01f, size*r->size_max, r->size_max);
r->t = r->size * leaf.sampleRate * 0.001f;
/*
for (int i = 0; i < 4; i++)
{
tAllpass_setDelay(&r->in_allpass[i], SAMP(in_allpass_delays[i]));
}
*/
// FEEDBACK 1
//tAllpass_setDelay(&r->f1_allpass, SAMP(30.51f));
tTapeDelay_setDelay(&r->f1_delay_1, SAMP(141.69f));
tTapeDelay_setDelay(&r->f1_delay_2, SAMP(89.24f));
tTapeDelay_setDelay(&r->f1_delay_3, SAMP(125.f));
// maybe change rate of SINE LFO's when size changes?
// FEEDBACK 2
//tAllpass_setDelay(&r->f2_allpass, SAMP(22.58f));
tTapeDelay_setDelay(&r->f2_delay_1, SAMP(149.62f));
tTapeDelay_setDelay(&r->f2_delay_2, SAMP(60.48f));
tTapeDelay_setDelay(&r->f2_delay_3, SAMP(106.28f));
}
void tDattorro_setInputDelay (tDattorro* const r, float preDelay)
{
r->predelay = LEAF_clip(0.0f, preDelay, 200.0f);
tTapeDelay_setDelay(&r->in_delay, SAMP(r->predelay));
}
void tDattorro_setInputFilter (tDattorro* const r, float freq)
{
r->input_filter = LEAF_clip(0.0f, freq, 20000.0f);
tOnePole_setFreq(&r->in_filter, r->input_filter);
}
void tDattorro_setFeedbackFilter (tDattorro* const r, float freq)
{
r->feedback_filter = LEAF_clip(0.0f, freq, 20000.0f);
tOnePole_setFreq(&r->f1_filter, r->feedback_filter);
tOnePole_setFreq(&r->f2_filter, r->feedback_filter);
}
void tDattorro_setFeedbackGain (tDattorro* const r, float gain)
{
r->feedback_gain = gain;
}