ref: df30032d6f4315b19dae153d8ac32a85bbdee051
parent: 80fdd36cdc7aa8951e0a3d57dbd4df3a89b9fa67
parent: 8acb64c973bb8793d51f2af5fb3d79b3a4518940
author: Davis Polito <davispolito1@gmail.com>
date: Tue Aug 30 10:06:15 EDT 2022
Merge branch 'master' of github.com:spiricom/LEAF
--- a/leaf/Inc/leaf-oscillators.h
+++ b/leaf/Inc/leaf-oscillators.h
@@ -1472,10 +1472,8 @@
tMempool mempool;
int32_t phase;
int32_t inc;
- int32_t prevPhase;
float freq;
- uint8_t phaseDidReset;
- uint32_t invSampleRate;
+ float invSampleRate;
float invSampleRateTimesTwoTo32;
} _tTriLFO;
--- a/leaf/Src/leaf-analysis.c
+++ b/leaf/Src/leaf-analysis.c
@@ -1822,6 +1822,7 @@
collector->_fundamental._period = -1;
collector->_fundamental._periodicity = 0.0f;
collector->_fundamental._harmonic = 0;
+ collector->_first_period = 0.01f;
}
static inline float sub_collector_period_of(_sub_collector* collector, _auto_correlation_info info)
--- a/leaf/Src/leaf-envelopes.c
+++ b/leaf/Src/leaf-envelopes.c
@@ -1316,8 +1316,8 @@
smooth->curr = val;
smooth->dest = val;
- if (factor < 0) factor = 0;
- if (factor > 1) factor = 1;
+ if (factor < 0.0f) factor = 0.0f;
+ if (factor > 1.0f) factor = 1.0f;
smooth->baseFactor = factor;
smooth->factor = factor;
smooth->oneminusfactor = 1.0f - factor;
@@ -1334,9 +1334,9 @@
{ // factor is usually a value between 0 and 0.1. Lower value is slower. 0.01 for example gives you a smoothing time of about 10ms
_tExpSmooth* smooth = *expsmooth;
- if (factor < 0)
- factor = 0;
- else if (factor > 1) factor = 1;
+ if (factor < 0.0f)
+ factor = 0.0f;
+ else if (factor > 1.0f) factor = 1.0f;
smooth->baseFactor = factor;
smooth->factor = powf(factor, 44100.f * smooth->invSampleRate);
smooth->oneminusfactor = 1.0f - factor;
--- a/leaf/Src/leaf-oscillators.c
+++ b/leaf/Src/leaf-oscillators.c
@@ -1269,7 +1269,6 @@
sync = c->sync;
-
p = c->_p; /* phase [0, 1) */
w = c->_w; /* phase increment */
b = c->_b; /* duty cycle (0, 1) */
@@ -1482,6 +1481,7 @@
void tMBTriangle_setWidth(tMBTriangle* const osc, float w)
{
_tMBTriangle* c = *osc;
+ w = LEAF_clip(0.0f, w, 0.99f);
c->waveform = w;
}
@@ -1846,10 +1846,13 @@
}
- /* now place reset DD for pulse */
+
if (sw > 0)
{
- if (k) {
+ /* now place reset DD for saw*/
+ place_step_dd(c->_f, j, p, sw, p_at_reset * sawShape);
+ /* now place reset DD for pulse */
+ if (k) {
place_step_dd(c->_f, j, p, sw, 1.0f * shape);
k = 0;
x = 0.5f;
@@ -1862,6 +1865,9 @@
}
else if (sw < 0)
{
+ /* now place reset DD for saw*/
+ place_step_dd(c->_f, j, 1.0f - p, -sw, -p_at_reset * sawShape);
+ /* now place reset DD for pulse */
if (!k) {
place_step_dd(c->_f, j, 1.0f - p, -sw, -1.0f * shape);
k = 1;
@@ -1873,12 +1879,8 @@
x = 0.5f;
}
}
- /* now place reset DD for saw*/
- if (sw > 0)
- place_step_dd(c->_f, j, p, sw, p_at_reset * sawShape);
- else if (sw < 0)
- place_step_dd(c->_f, j, 1.0f - p, -sw, -p_at_reset * sawShape);
+
}
@@ -2835,7 +2837,6 @@
c->phase = 0;
c->invSampleRateTimesTwoTo32 = (leaf->invSampleRate * TWO_TO_32);
- c->mask = 0x7FFFFFFF;
}
void tIntPhasor_free (tIntPhasor* const cy)
@@ -2850,7 +2851,7 @@
{
_tIntPhasor* c = *cy;
// Phasor increment
- c->phase = (c->phase + c->inc);//& c->mask;
+ c->phase = (c->phase + c->inc);
return c->phase * INV_TWO_TO_32;
}
@@ -2891,10 +2892,9 @@
_tMempool* m = *mp;
_tSquareLFO* c = *cy = (_tSquareLFO*) mpool_alloc(sizeof(_tSquareLFO), m);
c->mempool = m;
- LEAF* leaf = c->mempool->leaf;
tIntPhasor_initToPool(&c->phasor,mp);
tIntPhasor_initToPool(&c->invPhasor,mp);
- tSquareLFO_setPulseWidth(cy, 0.5);
+ tSquareLFO_setPulseWidth(cy, 0.5f);
}
void tSquareLFO_free (tSquareLFO* const cy)
@@ -2937,7 +2937,6 @@
_tSquareLFO *c = *cy;
c->pulsewidth = pw;
- //c->delay = c->pulsewidth * INV_TWO_TO_32;
tIntPhasor_setPhase(&c->invPhasor, c->pulsewidth + (c->phasor->phase * INV_TWO_TO_32));
}
@@ -2951,7 +2950,7 @@
void tSawSquareLFO_init (tSawSquareLFO* const cy, LEAF* const leaf)
{
tSawSquareLFO_initToPool(cy, &leaf->mempool);
- _tSawSquareLFO* c = *cy;
+
}
void tSawSquareLFO_initToPool (tSawSquareLFO* const cy, tMempool* const mp)
@@ -2959,7 +2958,6 @@
_tMempool* m = *mp;
_tSawSquareLFO* c = *cy = (_tSawSquareLFO*) mpool_alloc(sizeof(_tSawSquareLFO), m);
c->mempool = m;
- LEAF* leaf = c->mempool->leaf;
tSquareLFO_initToPool(&c->square,mp);
tIntPhasor_initToPool(&c->saw,mp);
}
@@ -3024,8 +3022,7 @@
c->phase = 0;
c->invSampleRate = leaf->invSampleRate;
c->invSampleRateTimesTwoTo32 = (c->invSampleRate * TWO_TO_32);
- //c->mask = TRI_TABLE_SIZE - 1;
- tTriLFO_setFreq(cy, 220);
+ tTriLFO_setFreq(cy, 220.0f);
}
void tTriLFO_free (tTriLFO* const cy)
@@ -3039,35 +3036,16 @@
float tTriLFO_tick(tTriLFO* const cy)
{
_tTriLFO* c = *cy;
- //uint32_t idx;
- //float frac, samp0, samp1;
- // Phasor increment
c->phase += c->inc;
//bitmask fun
- //
int32_t shiftedPhase = c->phase + 1073741824; // offset by 1/4" wave by adding 2^30 to get things in phase with the other LFO oscillators
- uint32_t mask = shiftedPhase >> 31;
- int32_t val2 = shiftedPhase + mask;
- int32_t test = val2 ^ mask;
- float output =( ((float)test * INV_TWO_TO_31)-0.5f) * 2.0f;
+ uint32_t mask = shiftedPhase >> 31; //get the sign bit
+ shiftedPhase = shiftedPhase + mask; // add 1 if negative, zero if positive, to balance
+ shiftedPhase = shiftedPhase ^ mask; //invert the value to get absolute value of integer
+ float output = (((float)shiftedPhase * INV_TWO_TO_31) - 0.5f) * 2.0f; //scale it to -1.0f to 1.0f float
return output;
- /*
- // Wavetable synthesis
- idx = c->phase >> 21;
- uint32_t idx2 = (idx + 1) & c->mask;
- uint32_t tempFrac = (c->phase & 2097151);
- frac = (float)tempFrac * 0.000000476837386f;// 1/2097151 (2097151 is the 21 bits after the 11 bits that represent the main index)
-
- samp0 = __leaf_table_triangle[0][idx];
- samp1 = __leaf_table_triangle[0][idx2];
- float oct0 = (samp0 + (samp1 - samp0) * frac);
-
-
- return oct0;
- */
-
}
void tTriLFO_setFreq(tTriLFO* const cy, float freq)
@@ -3081,7 +3059,6 @@
void tTriLFO_setPhase(tTriLFO* const cy, float phase)
{
_tTriLFO* c = *cy;
- phase = (phase + 0.5f);
int i = phase;
phase -= i;
c->phase = phase * TWO_TO_32_INT;
@@ -3090,8 +3067,8 @@
void tTriLFO_setSampleRate (tTriLFO* const cy, float sr)
{
_tTriLFO* c = *cy;
-
- c->invSampleRateTimesTwoTo32 = (1.0f/sr) * TWO_TO_32;
+ c->invSampleRate = (1.0f/sr);
+ c->invSampleRateTimesTwoTo32 = c->invSampleRate * TWO_TO_32;
tTriLFO_setFreq(cy, c->freq);
}
///sinetri
@@ -3099,7 +3076,6 @@
void tSineTriLFO_init (tSineTriLFO* const cy, LEAF* const leaf)
{
tSineTriLFO_initToPool(cy, &leaf->mempool);
- _tSineTriLFO* c = *cy;
}
void tSineTriLFO_initToPool (tSineTriLFO* const cy, tMempool* const mp)
@@ -3107,7 +3083,6 @@
_tMempool* m = *mp;
_tSineTriLFO* c = *cy = (_tSineTriLFO*) mpool_alloc(sizeof(_tSineTriLFO), m);
c->mempool = m;
- LEAF* leaf = c->mempool->leaf;
tTriLFO_initToPool(&c->tri,mp);
tCycle_initToPool(&c->sine,mp);
--- a/leaf/Src/leaf-sampling.c
+++ b/leaf/Src/leaf-sampling.c
@@ -1281,9 +1281,9 @@
int start, end, length;
float* buff;
int j;
- float syncin;
+ //float syncin;
float a, p, w, z;
- syncin = c->syncin;
+ // syncin = c->syncin;
start = c->start;
end = c->end;