ref: 27cf83ad3cc3493951943efb7f0ee18e60805fd9
dir: /LEAF/Src/leaf-envelopes.c/
/* ============================================================================== leaf-envelopes.c Created: 20 Jan 2017 12:02:17pm Author: Michael R Mulshine ============================================================================== */ #if _WIN32 || _WIN64 #include "..\Inc\leaf-envelopes.h" #include "..\Inc\leaf-tables.h" #include "..\leaf.h" #else #include "../Inc/leaf-envelopes.h" #include "../Inc/leaf-tables.h" #include "../leaf.h" #endif // ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ Envelope ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ // void tEnvelope_init(tEnvelope* const envlp, float attack, float decay, oBool loop) { _tEnvelope* env = *envlp = (_tEnvelope*) leaf_alloc(sizeof(_tEnvelope)); env->exp_buff = exp_decay; env->inc_buff = attack_decay_inc; env->buff_size = sizeof(exp_decay); env->loop = loop; if (attack > 8192.0f) attack = 8192.0f; if (attack < 0.0f) attack = 0.0f; if (decay > 8192.0f) decay = 8192.0f; if (decay < 0.0f) decay = 0.0f; int16_t attackIndex = ((int16_t)(attack * 8.0f))-1; int16_t decayIndex = ((int16_t)(decay * 8.0f))-1; int16_t rampIndex = ((int16_t)(2.0f * 8.0f))-1; if (attackIndex < 0) attackIndex = 0; if (decayIndex < 0) decayIndex = 0; if (rampIndex < 0) rampIndex = 0; env->inRamp = OFALSE; env->inAttack = OFALSE; env->inDecay = OFALSE; env->attackInc = env->inc_buff[attackIndex]; env->decayInc = env->inc_buff[decayIndex]; env->rampInc = env->inc_buff[rampIndex]; } void tEnvelope_free(tEnvelope* const envlp) { _tEnvelope* env = *envlp; leaf_free(env); } void tEnvelope_initToPool (tEnvelope* const envlp, float attack, float decay, oBool loop, tMempool* const mp) { _tMempool* m = *mp; _tEnvelope* env = *envlp = (_tEnvelope*) mpool_alloc(sizeof(_tEnvelope), m); env->exp_buff = exp_decay; env->inc_buff = attack_decay_inc; env->buff_size = sizeof(exp_decay); env->loop = loop; if (attack > 8192.0f) attack = 8192.0f; if (attack < 0.0f) attack = 0.0f; if (decay > 8192.0f) decay = 8192.0f; if (decay < 0.0f) decay = 0.0f; int16_t attackIndex = ((int16_t)(attack * 8.0f))-1; int16_t decayIndex = ((int16_t)(decay * 8.0f))-1; int16_t rampIndex = ((int16_t)(2.0f * 8.0f))-1; if (attackIndex < 0) attackIndex = 0; if (decayIndex < 0) decayIndex = 0; if (rampIndex < 0) rampIndex = 0; env->inRamp = OFALSE; env->inAttack = OFALSE; env->inDecay = OFALSE; env->attackInc = env->inc_buff[attackIndex]; env->decayInc = env->inc_buff[decayIndex]; env->rampInc = env->inc_buff[rampIndex]; } void tEnvelope_freeFromPool (tEnvelope* const envlp, tMempool* const mp) { _tMempool* m = *mp; _tEnvelope* env = *envlp; mpool_free(env, m); } void tEnvelope_setAttack(tEnvelope* const envlp, float attack) { _tEnvelope* env = *envlp; int32_t attackIndex; if (attack < 0.0f) { attackIndex = 0.0f; } else if (attack < 8192.0f) { attackIndex = ((int32_t)(attack * 8.0f))-1; } else { attackIndex = ((int32_t)(8192.0f * 8.0f))-1; } env->attackInc = env->inc_buff[attackIndex]; } void tEnvelope_setDecay(tEnvelope* const envlp, float decay) { _tEnvelope* env = *envlp; int32_t decayIndex; if (decay < 0.0f) { decayIndex = 0; } else if (decay < 8192.0f) { decayIndex = ((int32_t)(decay * 8.0f)) - 1; } else { decayIndex = ((int32_t)(8192.0f * 8.0f)) - 1; } env->decayInc = env->inc_buff[decayIndex]; } void tEnvelope_loop(tEnvelope* const envlp, oBool loop) { _tEnvelope* env = *envlp; env->loop = loop; } void tEnvelope_on(tEnvelope* const envlp, float velocity) { _tEnvelope* env = *envlp; if (env->inAttack || env->inDecay) // In case envelope retriggered while it is still happening. { env->rampPhase = 0; env->inRamp = OTRUE; env->rampPeak = env->next; } else // Normal start. { env->inAttack = OTRUE; } env->attackPhase = 0; env->decayPhase = 0; env->inDecay = OFALSE; env->gain = velocity; } float tEnvelope_tick(tEnvelope* const envlp) { _tEnvelope* env = *envlp; if (env->inRamp) { if (env->rampPhase > UINT16_MAX) { env->inRamp = OFALSE; env->inAttack = OTRUE; env->next = 0.0f; } else { env->next = env->rampPeak * env->exp_buff[(uint32_t)env->rampPhase]; } env->rampPhase += env->rampInc; } if (env->inAttack) { // If attack done, time to turn around. if (env->attackPhase > UINT16_MAX) { env->inDecay = OTRUE; env->inAttack = OFALSE; env->next = env->gain * 1.0f; } else { // do interpolation ! env->next = env->gain * env->exp_buff[UINT16_MAX - (uint32_t)env->attackPhase]; // inverted and backwards to get proper rising exponential shape/perception } // Increment envelope attack. env->attackPhase += env->attackInc; } if (env->inDecay) { // If decay done, finish. if (env->decayPhase >= UINT16_MAX) { env->inDecay = OFALSE; if (env->loop) { env->attackPhase = 0; env->decayPhase = 0; env->inAttack = OTRUE; } else { env->next = 0.0f; } } else { env->next = env->gain * (env->exp_buff[(uint32_t)env->decayPhase]); // do interpolation ! } // Increment envelope decay; env->decayPhase += env->decayInc; } return env->next; } /* ADSR */ void tADSR_init(tADSR* const adsrenv, float attack, float decay, float sustain, float release) { _tADSR* adsr = *adsrenv = (_tADSR*) leaf_alloc(sizeof(_tADSR)); adsr->exp_buff = exp_decay; adsr->inc_buff = attack_decay_inc; adsr->buff_size = sizeof(exp_decay); if (attack > 8192.0f) attack = 8192.0f; if (attack < 0.0f) attack = 0.0f; if (decay > 8192.0f) decay = 8192.0f; if (decay < 0.0f) decay = 0.0f; if (sustain > 1.0f) sustain = 1.0f; if (sustain < 0.0f) sustain = 0.0f; if (release > 8192.0f) release = 8192.0f; if (release < 0.0f) release = 0.0f; int16_t attackIndex = ((int16_t)(attack * 8.0f))-1; int16_t decayIndex = ((int16_t)(decay * 8.0f))-1; int16_t releaseIndex = ((int16_t)(release * 8.0f))-1; int16_t rampIndex = ((int16_t)(2.0f * 8.0f))-1; if (attackIndex < 0) attackIndex = 0; if (decayIndex < 0) decayIndex = 0; if (releaseIndex < 0) releaseIndex = 0; if (rampIndex < 0) rampIndex = 0; adsr->inRamp = OFALSE; adsr->inAttack = OFALSE; adsr->inDecay = OFALSE; adsr->inSustain = OFALSE; adsr->inRelease = OFALSE; adsr->sustain = sustain; adsr->attackInc = adsr->inc_buff[attackIndex]; adsr->decayInc = adsr->inc_buff[decayIndex]; adsr->releaseInc = adsr->inc_buff[releaseIndex]; adsr->rampInc = adsr->inc_buff[rampIndex]; adsr->leakFactor = 1.0f; } void tADSR_free(tADSR* const adsrenv) { _tADSR* adsr = *adsrenv; leaf_free(adsr); } void tADSR_initToPool (tADSR* const adsrenv, float attack, float decay, float sustain, float release, tMempool* const mp) { _tMempool* m = *mp; _tADSR* adsr = *adsrenv = (_tADSR*) mpool_alloc(sizeof(_tADSR), m); adsr->exp_buff = exp_decay; adsr->inc_buff = attack_decay_inc; adsr->buff_size = sizeof(exp_decay); if (attack > 8192.0f) attack = 8192.0f; if (attack < 0.0f) attack = 0.0f; if (decay > 8192.0f) decay = 8192.0f; if (decay < 0.0f) decay = 0.0f; if (sustain > 1.0f) sustain = 1.0f; if (sustain < 0.0f) sustain = 0.0f; if (release > 8192.0f) release = 8192.0f; if (release < 0.0f) release = 0.0f; int16_t attackIndex = ((int16_t)(attack * 8.0f))-1; int16_t decayIndex = ((int16_t)(decay * 8.0f))-1; int16_t releaseIndex = ((int16_t)(release * 8.0f))-1; int16_t rampIndex = ((int16_t)(2.0f * 8.0f))-1; if (attackIndex < 0) attackIndex = 0; if (decayIndex < 0) decayIndex = 0; if (releaseIndex < 0) releaseIndex = 0; if (rampIndex < 0) rampIndex = 0; adsr->inRamp = OFALSE; adsr->inAttack = OFALSE; adsr->inDecay = OFALSE; adsr->inSustain = OFALSE; adsr->inRelease = OFALSE; adsr->sustain = sustain; adsr->attackInc = adsr->inc_buff[attackIndex]; adsr->decayInc = adsr->inc_buff[decayIndex]; adsr->releaseInc = adsr->inc_buff[releaseIndex]; adsr->rampInc = adsr->inc_buff[rampIndex]; adsr->leakFactor = 1.0f; } void tADSR_freeFromPool (tADSR* const adsrenv, tMempool* const mp) { _tMempool* m = *mp; _tADSR* adsr = *adsrenv; mpool_free(adsr, m); } void tADSR_setAttack(tADSR* const adsrenv, float attack) { _tADSR* adsr = *adsrenv; int32_t attackIndex; if (attack < 0.0f) { attackIndex = 0.0f; } else if (attack < 8192.0f) { attackIndex = ((int32_t)(attack * 8.0f))-1; } else { attackIndex = ((int32_t)(8192.0f * 8.0f))-1; } adsr->attackInc = adsr->inc_buff[attackIndex]; } void tADSR_setDecay(tADSR* const adsrenv, float decay) { _tADSR* adsr = *adsrenv; int32_t decayIndex; if (decay < 0.0f) { decayIndex = 0.0f; } else if (decay < 8192.0f) { decayIndex = ((int32_t)(decay * 8.0f)) - 1; } else { decayIndex = ((int32_t)(8192.0f * 8.0f)) - 1; } adsr->decayInc = adsr->inc_buff[decayIndex]; } void tADSR_setSustain(tADSR* const adsrenv, float sustain) { _tADSR* adsr = *adsrenv; if (sustain > 1.0f) adsr->sustain = 1.0f; else if (sustain < 0.0f) adsr->sustain = 0.0f; else adsr->sustain = sustain; } void tADSR_setRelease(tADSR* const adsrenv, float release) { _tADSR* adsr = *adsrenv; int32_t releaseIndex; if (release < 0.0f) { releaseIndex = 0.0f; } else if (release < 8192.0f) { releaseIndex = ((int32_t)(release * 8.0f)) - 1; } else { releaseIndex = ((int32_t)(8192.0f * 8.0f)) - 1; } adsr->releaseInc = adsr->inc_buff[releaseIndex]; } // 0.999999 is slow leak, 0.9 is fast leak void tADSR_setLeakFactor(tADSR* const adsrenv, float leakFactor) { _tADSR* adsr = *adsrenv; adsr->leakFactor = leakFactor; } void tADSR_on(tADSR* const adsrenv, float velocity) { _tADSR* adsr = *adsrenv; if ((adsr->inAttack || adsr->inDecay) || (adsr->inSustain || adsr->inRelease)) // In case ADSR retriggered while it is still happening. { adsr->rampPhase = 0; adsr->inRamp = OTRUE; adsr->rampPeak = adsr->next; } else // Normal start. { adsr->inAttack = OTRUE; } adsr->attackPhase = 0; adsr->decayPhase = 0; adsr->releasePhase = 0; adsr->inDecay = OFALSE; adsr->inSustain = OFALSE; adsr->inRelease = OFALSE; adsr->gain = velocity; } void tADSR_off(tADSR* const adsrenv) { _tADSR* adsr = *adsrenv; if (adsr->inRelease) return; adsr->inAttack = OFALSE; adsr->inDecay = OFALSE; adsr->inSustain = OFALSE; adsr->inRelease = OTRUE; adsr->releasePeak = adsr->next; } float tADSR_tick(tADSR* const adsrenv) { _tADSR* adsr = *adsrenv; if (adsr->inRamp) { if (adsr->rampPhase > UINT16_MAX) { adsr->inRamp = OFALSE; adsr->inAttack = OTRUE; adsr->next = 0.0f; } else { adsr->next = adsr->rampPeak * adsr->exp_buff[(uint32_t)adsr->rampPhase]; } adsr->rampPhase += adsr->rampInc; } if (adsr->inAttack) { // If attack done, time to turn around. if (adsr->attackPhase > UINT16_MAX) { adsr->inDecay = OTRUE; adsr->inAttack = OFALSE; adsr->next = adsr->gain * 1.0f; } else { // do interpolation ! adsr->next = adsr->gain * adsr->exp_buff[UINT16_MAX - (uint32_t)adsr->attackPhase]; // inverted and backwards to get proper rising exponential shape/perception } // Increment ADSR attack. adsr->attackPhase += adsr->attackInc; } if (adsr->inDecay) { // If decay done, sustain. if (adsr->decayPhase >= UINT16_MAX) { adsr->inDecay = OFALSE; adsr->inSustain = OTRUE; adsr->next = adsr->gain * adsr->sustain; } else { adsr->next = adsr->gain * (adsr->sustain + ((adsr->exp_buff[(uint32_t)adsr->decayPhase]) * (1 - adsr->sustain))); // do interpolation ! } // Increment ADSR decay. adsr->decayPhase += adsr->decayInc; } if (adsr->inSustain) { adsr->next = adsr->next * adsr->leakFactor; } if (adsr->inRelease) { // If release done, finish. if (adsr->releasePhase >= UINT16_MAX) { adsr->inRelease = OFALSE; adsr->next = 0.0f; } else { adsr->next = adsr->releasePeak * (adsr->exp_buff[(uint32_t)adsr->releasePhase]); // do interpolation ! } // Increment envelope release; adsr->releasePhase += adsr->releaseInc; } return adsr->next; } /* Ramp */ void tRamp_init(tRamp* const r, float time, int samples_per_tick) { _tRamp* ramp = *r = (_tRamp*) leaf_alloc(sizeof(_tRamp)); ramp->inv_sr_ms = 1.0f/(leaf.sampleRate*0.001f); ramp->minimum_time = ramp->inv_sr_ms * samples_per_tick; ramp->curr = 0.0f; ramp->dest = 0.0f; if (time < ramp->minimum_time) { ramp->time = ramp->minimum_time; } else { ramp->time = time; } ramp->samples_per_tick = samples_per_tick; ramp->inc = ((ramp->dest - ramp->curr) / ramp->time * ramp->inv_sr_ms) * (float)ramp->samples_per_tick; } void tRamp_free(tRamp* const r) { _tRamp* ramp = *r; leaf_free(ramp); } void tRamp_initToPool (tRamp* const r, float time, int samples_per_tick, tMempool* const mp) { _tMempool* m = *mp; _tRamp* ramp = *r = (_tRamp*) mpool_alloc(sizeof(_tRamp), m); ramp->inv_sr_ms = 1.0f/(leaf.sampleRate*0.001f); ramp->minimum_time = ramp->inv_sr_ms * samples_per_tick; ramp->curr = 0.0f; ramp->dest = 0.0f; if (time < ramp->minimum_time) { ramp->time = ramp->minimum_time; } else { ramp->time = time; } ramp->samples_per_tick = samples_per_tick; ramp->inc = ((ramp->dest - ramp->curr) / ramp->time * ramp->inv_sr_ms) * (float)ramp->samples_per_tick; } void tRamp_freeFromPool (tRamp* const r, tMempool* const mp) { _tMempool* m = *mp; _tRamp* ramp = *r; mpool_free(ramp, m); } void tRamp_setTime(tRamp* const ramp, float time) { _tRamp* r = *ramp; if (time < r->minimum_time) { r->time = r->minimum_time; } else { r->time = time; } r->inc = ((r->dest-r->curr)/r->time * r->inv_sr_ms) * ((float)r->samples_per_tick); } void tRamp_setDest(tRamp* const ramp, float dest) { _tRamp* r = *ramp; r->dest = dest; r->inc = ((r->dest-r->curr)/r->time * r->inv_sr_ms) * ((float)r->samples_per_tick); } void tRamp_setVal(tRamp* const ramp, float val) { _tRamp* r = *ramp; r->curr = val; r->inc = ((r->dest-r->curr)/r->time * r->inv_sr_ms) * ((float)r->samples_per_tick); } float tRamp_tick(tRamp* const ramp) { _tRamp* r = *ramp; r->curr += r->inc; if (((r->curr >= r->dest) && (r->inc > 0.0f)) || ((r->curr <= r->dest) && (r->inc < 0.0f))) { r->inc = 0.0f; r->curr=r->dest; } return r->curr; } float tRamp_sample(tRamp* const ramp) { _tRamp* r = *ramp; return r->curr; } void tRampSampleRateChanged(tRamp* const ramp) { _tRamp* r = *ramp; r->inv_sr_ms = 1.0f / (leaf.sampleRate * 0.001f); r->inc = ((r->dest-r->curr)/r->time * r->inv_sr_ms)*((float)r->samples_per_tick); } /* Exponential Smoother */ void tExpSmooth_init(tExpSmooth* const expsmooth, float val, float factor) { // 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 = (_tExpSmooth*) leaf_alloc(sizeof(_tExpSmooth)); smooth->curr=val; smooth->dest=val; if (factor<0) factor=0; if (factor>1) factor=1; smooth->factor=factor; smooth->oneminusfactor=1.0f-factor; } void tExpSmooth_free(tExpSmooth* const expsmooth) { _tExpSmooth* smooth = *expsmooth; leaf_free(smooth); } void tExpSmooth_initToPool (tExpSmooth* const expsmooth, float val, float factor, tMempool* const mp) { _tMempool* m = *mp; _tExpSmooth* smooth = *expsmooth = (_tExpSmooth*) mpool_alloc(sizeof(_tExpSmooth), m); smooth->curr=val; smooth->dest=val; if (factor<0) factor=0; if (factor>1) factor=1; smooth->factor=factor; smooth->oneminusfactor=1.0f-factor; } void tExpSmooth_freeFromPool (tExpSmooth* const expsmooth, tMempool* const mp) { _tMempool* m = *mp; _tExpSmooth* smooth = *expsmooth; mpool_free(smooth, m); } void tExpSmooth_setFactor(tExpSmooth* const expsmooth, float factor) { // 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; smooth->factor=factor; smooth->oneminusfactor=1.0f-factor; } void tExpSmooth_setDest(tExpSmooth* const expsmooth, float dest) { _tExpSmooth* smooth = *expsmooth; smooth->dest=dest; } void tExpSmooth_setVal(tExpSmooth* const expsmooth, float val) { _tExpSmooth* smooth = *expsmooth; smooth->curr=val; } float tExpSmooth_tick(tExpSmooth* const expsmooth) { _tExpSmooth* smooth = *expsmooth; smooth->curr = smooth->factor*smooth->dest+smooth->oneminusfactor*smooth->curr; return smooth->curr; } float tExpSmooth_sample(tExpSmooth* const expsmooth) { _tExpSmooth* smooth = *expsmooth; return smooth->curr; }