/* * Copyright 2016-2017 Pascal Gauthier. * Copyright 2012 Google Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include "synth.h" #include "freqlut.h" #include "exp2.h" #include "controllers.h" #include "dx7note.h" const int FEEDBACK_BITDEPTH = 8; int32_t midinote_to_logfreq(int midinote) { const int base = 50857777; // (1 << 24) * (log(440) / log(2) - 69/12) const int step = (1 << 24) / 12; return base + step * midinote; } const int32_t coarsemul[] = { -16777216, 0, 16777216, 26591258, 33554432, 38955489, 43368474, 47099600, 50331648, 53182516, 55732705, 58039632, 60145690, 62083076, 63876816, 65546747, 67108864, 68576247, 69959732, 71268397, 72509921, 73690858, 74816848, 75892776, 76922906, 77910978, 78860292, 79773775, 80654032, 81503396, 82323963, 83117622 }; int32_t osc_freq(int midinote, int mode, int coarse, int fine, int detune) { // TODO: pitch randomization int32_t logfreq; if (mode == 0) { logfreq = midinote_to_logfreq(midinote); // could use more precision, closer enough for now. those numbers comes from my DX7 double detuneRatio = 0.0209 * exp(-0.396 * (((float)logfreq)/(1<<24))) / 7; logfreq += detuneRatio * logfreq * (detune - 7); logfreq += coarsemul[coarse & 31]; if (fine) { // (1 << 24) / log(2) logfreq += (int32_t)floor(24204406.323123 * log(1 + 0.01 * fine) + 0.5); } // // This was measured at 7.213Hz per count at 9600Hz, but the exact // // value is somewhat dependent on midinote. Close enough for now. // //logfreq += 12606 * (detune -7); } else { // ((1 << 24) * log(10) / log(2) * .01) << 3 logfreq = (4458616 * ((coarse & 3) * 100 + fine)) >> 3; logfreq += detune > 7 ? 13457 * (detune - 7) : 0; } return logfreq; } const uint8_t velocity_data[64] = { 0, 70, 86, 97, 106, 114, 121, 126, 132, 138, 142, 148, 152, 156, 160, 163, 166, 170, 173, 174, 178, 181, 184, 186, 189, 190, 194, 196, 198, 200, 202, 205, 206, 209, 211, 214, 216, 218, 220, 222, 224, 225, 227, 229, 230, 232, 233, 235, 237, 238, 240, 241, 242, 243, 244, 246, 246, 248, 249, 250, 251, 252, 253, 254 }; // See "velocity" section of notes. Returns velocity delta in microsteps. int ScaleVelocity(int velocity, int sensitivity) { int clamped_vel = max(0, min(127, velocity)); int vel_value = velocity_data[clamped_vel >> 1] - 239; int scaled_vel = ((sensitivity * vel_value + 7) >> 3) << 4; return scaled_vel; } int ScaleRate(int midinote, int sensitivity) { int x = min(31, max(0, midinote / 3 - 7)); int qratedelta = (sensitivity * x) >> 3; #ifdef SUPER_PRECISE int rem = x & 7; if (sensitivity == 3 && rem == 3) { qratedelta -= 1; } else if (sensitivity == 7 && rem > 0 && rem < 4) { qratedelta += 1; } #endif return qratedelta; } const uint8_t exp_scale_data[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 14, 16, 19, 23, 27, 33, 39, 47, 56, 66, 80, 94, 110, 126, 142, 158, 174, 190, 206, 222, 238, 250 }; int ScaleCurve(int group, int depth, int curve) { int scale; if (curve == 0 || curve == 3) { // linear scale = (group * depth * 329) >> 12; } else { // exponential int n_scale_data = sizeof(exp_scale_data); int raw_exp = exp_scale_data[min(group, n_scale_data - 1)]; scale = (raw_exp * depth * 329) >> 15; } if (curve < 2) { scale = -scale; } return scale; } int ScaleLevel(int midinote, int break_pt, int left_depth, int right_depth, int left_curve, int right_curve) { int offset = midinote - break_pt - 17; if (offset >= 0) { return ScaleCurve((offset+1) / 3, right_depth, right_curve); } else { return ScaleCurve(-(offset-1) / 3, left_depth, left_curve); } } static const uint8_t pitchmodsenstab[] = { 0, 10, 20, 33, 55, 92, 153, 255 }; // 0, 66, 109, 255 static const uint32_t ampmodsenstab[] = { 0, 4342338, 7171437, 16777216 }; Dx7Note::Dx7Note() { for(int op=0;op<6;op++) { params_[op].phase = 0; params_[op].gain_out = 0; } } //void Dx7Note::init(const uint8_t patch[156], int midinote, int velocity) { void Dx7Note::init(const uint8_t patch[173], int midinote, int velocity) { int rates[4]; int levels[4]; for (int op = 0; op < 6; op++) { int off = op * 21; for (int i = 0; i < 4; i++) { rates[i] = patch[off + i]; levels[i] = patch[off + 4 + i]; } int outlevel = patch[off + 16]; outlevel = Env::scaleoutlevel(outlevel); int level_scaling = ScaleLevel(midinote, patch[off + 8], patch[off + 9], patch[off + 10], patch[off + 11], patch[off + 12]); outlevel += level_scaling; outlevel = min(127, outlevel); outlevel = outlevel << 5; outlevel += ScaleVelocity(velocity, patch[off + 15]); outlevel = max(0, outlevel); int rate_scaling = ScaleRate(midinote, patch[off + 13]); env_[op].init(rates, levels, outlevel, rate_scaling); int mode = patch[off + 17]; int coarse = patch[off + 18]; int fine = patch[off + 19]; int detune = patch[off + 20]; int32_t freq = osc_freq(midinote, mode, coarse, fine, detune); opMode[op] = mode; basepitch_[op] = freq; ampmodsens_[op] = ampmodsenstab[patch[off + 14] & 3]; } for (int i = 0; i < 4; i++) { rates[i] = patch[126 + i]; levels[i] = patch[130 + i]; } pitchenv_.set(rates, levels); algorithm_ = patch[134]; int feedback = patch[135]; fb_shift_ = feedback != 0 ? FEEDBACK_BITDEPTH - feedback : 16; pitchmoddepth_ = (patch[139] * 165) >> 6; pitchmodsens_ = pitchmodsenstab[patch[143] & 7]; ampmoddepth_ = (patch[140] * 165) >> 6; } void Dx7Note::compute(int32_t *buf, int32_t lfo_val, int32_t lfo_delay, const Controllers *ctrls) { // ==== PITCH ==== uint32_t pmd = pitchmoddepth_ * lfo_delay; // Q32 int32_t senslfo = pitchmodsens_ * (lfo_val - (1 << 23)); int32_t pmod_1 = (((int64_t) pmd) * (int64_t) senslfo) >> 39; pmod_1 = abs(pmod_1); int32_t pmod_2 = (int32_t)(((int64_t)ctrls->pitch_mod * (int64_t)senslfo) >> 14); pmod_2 = abs(pmod_2); int32_t pitch_mod = max(pmod_1, pmod_2); pitch_mod = pitchenv_.getsample() + (pitch_mod * (senslfo < 0 ? -1 : 1)); // ---- PITCH BEND ---- int pitchbend = ctrls->values_[kControllerPitch]; int32_t pb = (pitchbend - 0x2000); if (pb != 0) { if (ctrls->values_[kControllerPitchStep] == 0) { pb = ((float) (pb << 11)) * ((float) ctrls->values_[kControllerPitchRange]) / 12.0; } else { int stp = 12 / ctrls->values_[kControllerPitchStep]; pb = pb * stp / 8191; pb = (pb * (8191 / stp)) << 11; } } int32_t pitch_base = pb + ctrls->masterTune; pitch_mod += pitch_base; // ==== AMP MOD ==== lfo_val = (1<<24) - lfo_val; uint32_t amod_1 = (uint32_t)(((int64_t) ampmoddepth_ * (int64_t) lfo_delay) >> 8); // Q24 :D amod_1 = (uint32_t)(((int64_t) amod_1 * (int64_t) lfo_val) >> 24); uint32_t amod_2 = (uint32_t)(((int64_t) ctrls->amp_mod * (int64_t) lfo_val) >> 7); // Q?? :| uint32_t amd_mod = max(amod_1, amod_2); // ==== EG AMP MOD ==== uint32_t amod_3 = (ctrls->eg_mod+1) << 17; amd_mod = max((1<<24) - amod_3, amd_mod); // ==== OP RENDER ==== for (int op = 0; op < 6; op++) { // if ( ctrls->opSwitch[op] == '0' ) { if (!(ctrls->opSwitch & (1<> 24); // TODO: mehhh.. this needs some real tuning. uint32_t pt = exp(((float)sensamp)/262144 * 0.07 + 12.2); uint32_t ldiff = (uint32_t)(((uint64_t)level) * (((uint64_t)pt<<4)) >> 28); level -= ldiff; } params_[op].level_in = level; } } ctrls->core->render(buf, params_, algorithm_, fb_buf_, fb_shift_); } void Dx7Note::keyup() { for (int op = 0; op < 6; op++) { env_[op].keydown(false); } pitchenv_.keydown(false); } void Dx7Note::update(const uint8_t patch[156], int midinote, int velocity) { int rates[4]; int levels[4]; for (int op = 0; op < 6; op++) { int off = op * 21; int mode = patch[off + 17]; int coarse = patch[off + 18]; int fine = patch[off + 19]; int detune = patch[off + 20]; basepitch_[op] = osc_freq(midinote, mode, coarse, fine, detune); ampmodsens_[op] = ampmodsenstab[patch[off + 14] & 3]; opMode[op] = mode; for (int i = 0; i < 4; i++) { rates[i] = patch[off + i]; levels[i] = patch[off + 4 + i]; } int outlevel = patch[off + 16]; outlevel = Env::scaleoutlevel(outlevel); int level_scaling = ScaleLevel(midinote, patch[off + 8], patch[off + 9], patch[off + 10], patch[off + 11], patch[off + 12]); outlevel += level_scaling; outlevel = min(127, outlevel); outlevel = outlevel << 5; outlevel += ScaleVelocity(velocity, patch[off + 15]); outlevel = max(0, outlevel); int rate_scaling = ScaleRate(midinote, patch[off + 13]); env_[op].update(rates, levels, outlevel, rate_scaling); } algorithm_ = patch[134]; int feedback = patch[135]; fb_shift_ = feedback != 0 ? FEEDBACK_BITDEPTH - feedback : 16; pitchmoddepth_ = (patch[139] * 165) >> 6; pitchmodsens_ = pitchmodsenstab[patch[143] & 7]; ampmoddepth_ = (patch[140] * 165) >> 6; } void Dx7Note::peekVoiceStatus(VoiceStatus &status) { for(int i=0;i<6;i++) { status.amp[i] = Exp2::lookup(params_[i].level_in - (14 * (1 << 24))); env_[i].getPosition(&status.ampStep[i]); } pitchenv_.getPosition(&status.pitchStep); } /** * Used in monophonic mode to transfert voice state from different notes */ void Dx7Note::transferState(Dx7Note &src) { for (int i=0;i<6;i++) { env_[i].transfer(src.env_[i]); params_[i].gain_out = src.params_[i].gain_out; params_[i].phase = src.params_[i].phase; } } void Dx7Note::transferSignal(Dx7Note &src) { for (int i=0;i<6;i++) { params_[i].gain_out = src.params_[i].gain_out; params_[i].phase = src.params_[i].phase; } } void Dx7Note::oscSync() { for (int i=0;i<6;i++) { params_[i].gain_out = 0; params_[i].phase = 0; } }