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Expose voice detune parameter of the lv2 plugin
[zyn.git] / analog_filter.cpp
blobf6ffb104133ae036588a79b56eb35a2b87225ca8
1 /*
2 ZynAddSubFX - a software synthesizer
3
4 AnalogFilter.C - Several analog filters (lowpass, highpass...)
5 Copyright (C) 2002-2005 Nasca Octavian Paul
6 Author: Nasca Octavian Paul
7
8 This program is free software; you can redistribute it and/or modify
9 it under the terms of version 2 of the GNU General Public License
10 as published by the Free Software Foundation.
11
12 This program is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License (version 2) for more details.
16
17 You should have received a copy of the GNU General Public License (version 2)
18 along with this program; if not, write to the Free Software Foundation,
19 Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
20
21 */
22
23 #include <math.h>
24 #include <stdio.h>
25 #include <assert.h>
26
27 #include "globals.h"
28 #include "filter_base.h"
29 #include "analog_filter.h"
30
31 void
32 AnalogFilter::init(
33 float sample_rate,
34 unsigned char Ftype,
35 float Ffreq,
36 float Fq,
37 unsigned char Fstages,
38 float gain)
39 {
40 int i;
41
42 m_sample_rate = sample_rate;
43
44 m_additional_stages = Fstages;
45
46 for (i = 0 ; i < 3 ; i++)
47 {
48 m_c_old[i] = 0.0;
49 m_d_old[i] = 0.0;
50 m_c[i] =0.0;
51 m_d[i] = 0.0;
52 }
53
54 m_type = Ftype;
55
56 m_frequency = Ffreq;
57
58 m_q_factor = Fq;
59
60 m_gain = 1.0;
61
62 if (m_additional_stages >= MAX_FILTER_STAGES)
63 {
64 m_additional_stages = MAX_FILTER_STAGES;
65 }
66
67 cleanup();
68
69 m_first_time = false;
70
71 m_above_nq = false;
72 m_old_above_nq = false;
73
74 setfreq_and_q(Ffreq, Fq);
75
76 m_first_time = true;
77
78 m_d[0] = 0; // this is not used
79 m_outgain = 1.0;
80
81 if (Ftype >= ZYN_FILTER_ANALOG_TYPE_PKF2 &&
82 Ftype <= ZYN_FILTER_ANALOG_TYPE_HSH2)
83 {
84 setgain(gain);
85 }
86 else
87 {
88 m_outgain = dB2rap(gain);
89 }
90 }
91
92 void
93 AnalogFilter::cleanup()
94 {
95 int i;
96
97 for (i=0 ; i < MAX_FILTER_STAGES + 1 ; i++)
98 {
99 m_x[i].c1 = 0.0;
100 m_x[i].c2 = 0.0;
101
102 m_y[i].c1 = 0.0;
103 m_y[i].c2 = 0.0;
104
105 m_x_old[i] = m_x[i];
106 m_y_old[i] = m_y[i];
107 };
108
109 m_needs_interpolation = false;
110 }
111
112 void
113 AnalogFilter::computefiltercoefs()
114 {
115 float tmp;
116 float omega, sn, cs, alpha, beta;
117 int zerocoefs = 0; // this is used if the freq is too high
118 float freq;
119 float tmpq, tmpgain;
120
121 // do not allow frequencies bigger than samplerate/2
122 freq = m_frequency;
123
124 if (freq > m_sample_rate / 2 - 500.0)
125 {
126 freq = m_sample_rate / 2 - 500.0;
127 zerocoefs = 1;
128 }
129
130 if (freq < 0.1)
131 {
132 freq = 0.1;
133 }
134
135 // do not allow bogus Q
136 if (m_q_factor < 0.0)
137 {
138 m_q_factor = 0.0;
139 }
140
141 if (m_additional_stages == 0)
142 {
143 tmpq = m_q_factor;
144 tmpgain = m_gain;
145 }
146 else
147 {
148 tmpq = (m_q_factor > 1.0 ? pow(m_q_factor, 1.0 / (m_additional_stages + 1)) : m_q_factor);
149 tmpgain = pow(m_gain, 1.0 / (m_additional_stages + 1));
150 }
151
152 // most of theese are implementations of
153 // the "Cookbook formulae for audio EQ" by Robert Bristow-Johnson
154 // The original location of the Cookbook is:
155 // http://www.harmony-central.com/Computer/Programming/Audio-EQ-Cookbook.txt
156 switch(m_type)
157 {
158 case ZYN_FILTER_ANALOG_TYPE_LPF1:
159 if (zerocoefs == 0)
160 {
161 tmp = exp(-2.0 * PI * freq / m_sample_rate);
162 }
163 else
164 {
165 tmp = 0.0;
166 }
167
168 m_c[0] = 1.0-tmp;
169 m_c[1] = 0.0;
170 m_c[2] = 0.0;
171
172 m_d[1] = tmp;
173 m_d[2] = 0.0;
174
175 m_order = 1;
176
177 break;
178
179 case ZYN_FILTER_ANALOG_TYPE_HPF1:
180 if (zerocoefs == 0)
181 {
182 tmp = exp(-2.0 * PI * freq / m_sample_rate);
183 }
184 else
185 {
186 tmp = 0.0;
187 }
188
189 m_c[0] = (1.0 + tmp) / 2.0;
190 m_c[1] = -(1.0 + tmp) / 2.0;
191 m_c[2] = 0.0;
192
193 m_d[1] = tmp;
194 m_d[2] = 0.0;
195
196 m_order = 1;
197
198 break;
199
200 case ZYN_FILTER_ANALOG_TYPE_LPF2:
201 if (zerocoefs == 0)
202 {
203 omega = 2 * PI * freq / m_sample_rate;
204 sn = sin(omega);
205 cs = cos(omega);
206 alpha = sn / (2 * tmpq);
207 tmp = 1 + alpha;
208 m_c[0] = (1.0 - cs) / 2.0 / tmp;
209 m_c[1] = (1.0 - cs) / tmp;
210 m_c[2] = (1.0 - cs) / 2.0 / tmp;
211 m_d[1] = -2 * cs / tmp * (-1);
212 m_d[2] = (1 - alpha) / tmp * (-1);
213 }
214 else
215 {
216 m_c[0] = 1.0;
217 m_c[1] = 0.0;
218 m_c[2] = 0.0;
219
220 m_d[1] = 0.0;
221 m_d[2] = 0.0;
222 }
223
224 m_order = 2;
225
226 break;
227
228 case ZYN_FILTER_ANALOG_TYPE_HPF2:
229 if (zerocoefs == 0)
230 {
231 omega = 2 * PI * freq / m_sample_rate;
232 sn = sin(omega);
233 cs = cos(omega);
234 alpha = sn / (2 * tmpq);
235 tmp = 1 + alpha;
236 m_c[0] = (1.0 + cs) / 2.0 / tmp;
237 m_c[1] = -(1.0 + cs) / tmp;
238 m_c[2] = (1.0 + cs) / 2.0 / tmp;
239 m_d[1] = -2 * cs / tmp * (-1);
240 m_d[2] = (1 - alpha) / tmp * (-1);
241 }
242 else
243 {
244 m_c[0] = 0.0;
245 m_c[1] = 0.0;
246 m_c[2] = 0.0;
247
248 m_d[1] = 0.0;
249 m_d[2] = 0.0;
250 }
251
252 m_order = 2;
253
254 break;
255
256 case ZYN_FILTER_ANALOG_TYPE_BPF2:
257 if (zerocoefs == 0)
258 {
259 omega = 2 * PI * freq / m_sample_rate;
260 sn = sin(omega);
261 cs = cos(omega);
262 alpha = sn / (2 * tmpq);
263 tmp = 1 + alpha;
264 m_c[0] = alpha / tmp * sqrt(tmpq + 1);
265 m_c[1] = 0;
266 m_c[2] = -alpha / tmp * sqrt(tmpq + 1);
267 m_d[1] = -2 * cs / tmp * (-1);
268 m_d[2] = (1 - alpha) / tmp * (-1);
269 }
270 else
271 {
272 m_c[0] = 0.0;
273 m_c[1] = 0.0;
274 m_c[2] = 0.0;
275
276 m_d[1] = 0.0;
277 m_d[2] = 0.0;
278 }
279
280 m_order = 2;
281
282 break;
283
284 case ZYN_FILTER_ANALOG_TYPE_NF2:
285 if (zerocoefs == 0)
286 {
287 omega = 2 * PI * freq / m_sample_rate;
288 sn = sin(omega);
289 cs = cos(omega);
290 alpha = sn / (2 * sqrt(tmpq));
291 tmp = 1 + alpha;
292 m_c[0] = 1 / tmp;
293 m_c[1] = -2 * cs / tmp;
294 m_c[2] = 1 / tmp;
295 m_d[1] = -2 * cs / tmp * (-1);
296 m_d[2] = (1 - alpha) / tmp * (-1);
297 }
298 else
299 {
300 m_c[0] = 1.0;
301 m_c[1] = 0.0;
302 m_c[2] = 0.0;
303
304 m_d[1] = 0.0;
305 m_d[2] = 0.0;
306 }
307
308 m_order = 2;
309
310 break;
311 case ZYN_FILTER_ANALOG_TYPE_PKF2:
312 if (zerocoefs == 0)
313 {
314 omega = 2 * PI * freq / m_sample_rate;
315 sn = sin(omega);
316 cs = cos(omega);
317 tmpq *= 3.0;
318 alpha = sn / (2 * tmpq);
319 tmp = 1 + alpha / tmpgain;
320 m_c[0] = (1.0 + alpha * tmpgain) / tmp;
321 m_c[1] = (-2.0 * cs) / tmp;
322 m_c[2] = (1.0 - alpha * tmpgain) / tmp;
323 m_d[1] = -2 * cs / tmp * (-1);
324 m_d[2] = (1 - alpha / tmpgain) / tmp * (-1);
325 }
326 else
327 {
328 m_c[0] = 1.0;
329 m_c[1] = 0.0;
330 m_c[2] = 0.0;
331
332 m_d[1] = 0.0;
333 m_d[2] = 0.0;
334 }
335
336 m_order = 2;
337
338 break;
339
340 case ZYN_FILTER_ANALOG_TYPE_LSH2:
341 if (zerocoefs == 0)
342 {
343 omega = 2 * PI * freq / m_sample_rate;
344 sn = sin(omega);
345 cs = cos(omega);
346 tmpq = sqrt(tmpq);
347 alpha = sn / (2 * tmpq);
348 beta = sqrt(tmpgain) / tmpq;
349 tmp = (tmpgain + 1.0) + (tmpgain - 1.0) * cs + beta * sn;
350
351 m_c[0] = tmpgain * ((tmpgain + 1.0) - (tmpgain - 1.0) * cs + beta * sn) / tmp;
352 m_c[1] = 2.0 * tmpgain * ((tmpgain - 1.0) - (tmpgain + 1.0) * cs) / tmp;
353 m_c[2] = tmpgain * ((tmpgain + 1.0) - (tmpgain - 1.0) * cs - beta * sn) / tmp;
354 m_d[1] = -2.0 * ((tmpgain - 1.0) + (tmpgain + 1.0) * cs) / tmp * (-1);
355 m_d[2] = ((tmpgain + 1.0) + (tmpgain - 1.0) * cs - beta * sn) / tmp * (-1);
356 }
357 else
358 {
359 m_c[0] = tmpgain;
360 m_c[1] = 0.0;
361 m_c[2] = 0.0;
362
363 m_d[1] = 0.0;
364 m_d[2] = 0.0;
365 }
366
367 m_order = 2;
368
369 break;
370
371 case ZYN_FILTER_ANALOG_TYPE_HSH2:
372 if (zerocoefs == 0)
373 {
374 omega = 2 * PI * freq / m_sample_rate;
375 sn = sin(omega);
376 cs = cos(omega);
377 tmpq = sqrt(tmpq);
378 alpha = sn / (2 * tmpq);
379 beta = sqrt(tmpgain) / tmpq;
380 tmp = (tmpgain + 1.0) - (tmpgain - 1.0) * cs + beta * sn;
381
382 m_c[0] = tmpgain * ((tmpgain + 1.0) + (tmpgain - 1.0) * cs + beta * sn) / tmp;
383 m_c[1] = -2.0 * tmpgain * ((tmpgain - 1.0) + (tmpgain + 1.0) * cs) / tmp;
384 m_c[2] = tmpgain * ((tmpgain + 1.0) + (tmpgain - 1.0) * cs - beta * sn) / tmp;
385 m_d[1] = 2.0 * ((tmpgain - 1.0) - (tmpgain + 1.0) * cs) / tmp * (-1);
386 m_d[2] = ((tmpgain + 1.0) - (tmpgain - 1.0) * cs - beta * sn) / tmp * (-1);
387 }
388 else
389 {
390 m_c[0] = 1.0;
391 m_c[1] = 0.0;
392 m_c[2] = 0.0;
393
394 m_d[1] = 0.0;
395 m_d[2] = 0.0;
396 }
397
398 m_order = 2;
399
400 break;
401
402 default:
403 assert(0); // wrong type
404 }
405 }
406
407
408 void
409 AnalogFilter::setfreq(float frequency)
410 {
411 float rap;
412 bool nyquist_thresh;
413 int i;
414
415 if (frequency < 0.1)
416 {
417 frequency = 0.1;
418 }
419
420 rap = m_frequency / frequency;
421 if (rap < 1.0)
422 {
423 rap = 1.0 / rap;
424 }
425
426 m_old_above_nq = m_above_nq;
427 m_above_nq = frequency > (m_sample_rate / 2 - 500.0);
428
429 nyquist_thresh = ZYN_BOOL_XOR(m_above_nq, m_old_above_nq);
430
431 // if the frequency is changed fast, it needs interpolation (now, filter and coeficients backup)
432 if (rap > 3.0 || nyquist_thresh)
433 {
434 for (i = 0 ; i < 3 ; i++)
435 {
436 m_c_old[i] = m_c[i];
437 m_d_old[i] = m_d[i];
438 }
439
440 for (i = 0 ; i < MAX_FILTER_STAGES + 1 ; i++)
441 {
442 m_x_old[i] = m_x[i];
443 m_y_old[i] = m_y[i];
444 }
445
446 if (!m_first_time)
447 {
448 m_needs_interpolation = true;
449 }
450 }
451
452 m_frequency = frequency;
453
454 computefiltercoefs();
455
456 m_first_time = false;
457 }
458
459 void AnalogFilter::setfreq_and_q(float frequency, float q_factor)
460 {
461 m_q_factor = q_factor;
462
463 setfreq(frequency);
464 }
465
466 void AnalogFilter::setq(float q_factor)
467 {
468 m_q_factor = q_factor;
469
470 computefiltercoefs();
471 }
472
473 void AnalogFilter::settype(int type)
474 {
475 m_type = type;
476
477 computefiltercoefs();
478 }
479
480 void AnalogFilter::setgain(float dBgain)
481 {
482 m_gain = dB2rap(dBgain);
483
484 computefiltercoefs();
485 }
486
487 void AnalogFilter::setstages(int additional_stages)
488 {
489 if (additional_stages >= MAX_FILTER_STAGES)
490 {
491 m_additional_stages = MAX_FILTER_STAGES - 1;
492 }
493 else
494 {
495 m_additional_stages = additional_stages;
496 }
497
498 cleanup();
499
500 computefiltercoefs();
501 }
502
503 void
504 AnalogFilter::singlefilterout(
505 float * smp,
506 struct analog_filter_stage * x,
507 struct analog_filter_stage * y,
508 float * c,
509 float * d)
510 {
511 int i;
512 float y0;
513
514 if (m_order == 1) // First order filter
515 {
516 for (i=0 ; i < SOUND_BUFFER_SIZE ; i++)
517 {
518 y0 = smp[i] * c[0] + x->c1 * c[1] + y->c1 * d[1];
519 y->c1 = y0;
520 x->c1 = smp[i];
521 // output
522 smp[i] = y0;
523 }
524 }
525
526 if (m_order == 2) // Second order filter
527 {
528 for (i = 0 ; i < SOUND_BUFFER_SIZE ; i++)
529 {
530 y0 = smp[i] * c[0] + x->c1 * c[1] + x->c2 * c[2] + y->c1 * d[1] + y->c2 * d[2];
531 y->c2 = y->c1;
532 y->c1 = y0;
533 x->c2 = x->c1;
534 x->c1 = smp[i];
535 //output
536 smp[i] = y0;
537 }
538 }
539 }
540
541 void AnalogFilter::filterout(float *smp)
542 {
543 int i;
544 float x;
545
546 if (m_needs_interpolation)
547 {
548 for (i = 0 ; i < SOUND_BUFFER_SIZE ; i++)
549 {
550 m_interpolation_buffer[i] = smp[i];
551 }
552
553 for (i = 0 ; i < 1 + m_additional_stages ; i++)
554 {
555 singlefilterout(m_interpolation_buffer, m_x_old + i , m_y_old + i , m_c_old , m_d_old);
556 }
557 }
558
559 for (i = 0 ; i < 1 + m_additional_stages ; i++)
560 {
561 singlefilterout(smp, m_x + i, m_y + i, m_c, m_d);
562 }
563
564 if (m_needs_interpolation)
565 {
566 for (i = 0 ; i < SOUND_BUFFER_SIZE ; i++)
567 {
568 x = i / (float)SOUND_BUFFER_SIZE;
569 smp[i] = m_interpolation_buffer[i] * (1.0 - x) + smp[i] * x;
570 }
571
572 m_needs_interpolation = false;
573 }
574
575 for (i = 0 ; i < SOUND_BUFFER_SIZE ; i++)
576 {
577 smp[i] *= m_outgain;
578 }
579 }
580
581 float
582 AnalogFilter::H(float freq)
583 {
584 float fr;
585 float x;
586 float y;
587 float h;
588 int n;
589
590 fr = freq / m_sample_rate * PI * 2.0;
591 x = m_c[0];
592 y = 0.0;
593
594 for (n = 1 ; n < 3 ; n++)
595 {
596 x += cos(n * fr) * m_c[n];
597 y -= sin(n * fr) * m_c[n];
598 }
599
600 h = x * x + y * y;
601
602 x = 1.0;
603 y = 0.0;
604
605 for (n = 1 ; n < 3 ; n++)
606 {
607 x -= cos(n * fr) * m_d[n];
608 y += sin(n * fr) * m_d[n];
609 }
610
611 h = h / (x * x + y * y);
612
613 return pow(h, (m_additional_stages + 1.0) / 2.0);
614 }
Improved ZynAddSubFX engines