1 /* -----------------------------------------------------------------------------
2 Software License for The Fraunhofer FDK AAC Codec Library for Android
3
4 © Copyright 1995 - 2019 Fraunhofer-Gesellschaft zur Förderung der angewandten
5 Forschung e.V. All rights reserved.
6
7 1. INTRODUCTION
8 The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software
9 that implements the MPEG Advanced Audio Coding ("AAC") encoding and decoding
10 scheme for digital audio. This FDK AAC Codec software is intended to be used on
11 a wide variety of Android devices.
12
13 AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient
14 general perceptual audio codecs. AAC-ELD is considered the best-performing
15 full-bandwidth communications codec by independent studies and is widely
16 deployed. AAC has been standardized by ISO and IEC as part of the MPEG
17 specifications.
18
19 Patent licenses for necessary patent claims for the FDK AAC Codec (including
20 those of Fraunhofer) may be obtained through Via Licensing
21 (www.vialicensing.com) or through the respective patent owners individually for
22 the purpose of encoding or decoding bit streams in products that are compliant
23 with the ISO/IEC MPEG audio standards. Please note that most manufacturers of
24 Android devices already license these patent claims through Via Licensing or
25 directly from the patent owners, and therefore FDK AAC Codec software may
26 already be covered under those patent licenses when it is used for those
27 licensed purposes only.
28
29 Commercially-licensed AAC software libraries, including floating-point versions
30 with enhanced sound quality, are also available from Fraunhofer. Users are
31 encouraged to check the Fraunhofer website for additional applications
32 information and documentation.
33
34 2. COPYRIGHT LICENSE
35
36 Redistribution and use in source and binary forms, with or without modification,
37 are permitted without payment of copyright license fees provided that you
38 satisfy the following conditions:
39
40 You must retain the complete text of this software license in redistributions of
41 the FDK AAC Codec or your modifications thereto in source code form.
42
43 You must retain the complete text of this software license in the documentation
44 and/or other materials provided with redistributions of the FDK AAC Codec or
45 your modifications thereto in binary form. You must make available free of
46 charge copies of the complete source code of the FDK AAC Codec and your
47 modifications thereto to recipients of copies in binary form.
48
49 The name of Fraunhofer may not be used to endorse or promote products derived
50 from this library without prior written permission.
51
52 You may not charge copyright license fees for anyone to use, copy or distribute
53 the FDK AAC Codec software or your modifications thereto.
54
55 Your modified versions of the FDK AAC Codec must carry prominent notices stating
56 that you changed the software and the date of any change. For modified versions
57 of the FDK AAC Codec, the term "Fraunhofer FDK AAC Codec Library for Android"
58 must be replaced by the term "Third-Party Modified Version of the Fraunhofer FDK
59 AAC Codec Library for Android."
60
61 3. NO PATENT LICENSE
62
63 NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without
64 limitation the patents of Fraunhofer, ARE GRANTED BY THIS SOFTWARE LICENSE.
65 Fraunhofer provides no warranty of patent non-infringement with respect to this
66 software.
67
68 You may use this FDK AAC Codec software or modifications thereto only for
69 purposes that are authorized by appropriate patent licenses.
70
71 4. DISCLAIMER
72
73 This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright
74 holders and contributors "AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES,
75 including but not limited to the implied warranties of merchantability and
76 fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
77 CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary,
78 or consequential damages, including but not limited to procurement of substitute
79 goods or services; loss of use, data, or profits, or business interruption,
80 however caused and on any theory of liability, whether in contract, strict
81 liability, or tort (including negligence), arising in any way out of the use of
82 this software, even if advised of the possibility of such damage.
83
84 5. CONTACT INFORMATION
85
86 Fraunhofer Institute for Integrated Circuits IIS
87 Attention: Audio and Multimedia Departments - FDK AAC LL
88 Am Wolfsmantel 33
89 91058 Erlangen, Germany
90
91 www.iis.fraunhofer.de/amm
92 amm-info@iis.fraunhofer.de
93 ----------------------------------------------------------------------------- */
94
95 /**************************** AAC decoder library ******************************
96
97 Author(s): Matthias Hildenbrand
98
99 Description: USAC ACELP frame decoder
100
101 *******************************************************************************/
102
103 #include "usacdec_acelp.h"
104
105 #include "usacdec_ace_d4t64.h"
106 #include "usacdec_ace_ltp.h"
107 #include "usacdec_rom.h"
108 #include "usacdec_lpc.h"
109 #include "genericStds.h"
110
111 #define PIT_FR2_12k8 128 /* Minimum pitch lag with resolution 1/2 */
112 #define PIT_FR1_12k8 160 /* Minimum pitch lag with resolution 1 */
113 #define TILT_CODE2 \
114 FL2FXCONST_SGL(0.3f * 2.0f) /* ACELP code pre-emphasis factor ( *2 ) */
115 #define PIT_SHARP \
116 FL2FXCONST_SGL(0.85f) /* pitch sharpening factor */
117 #define PREEMPH_FAC \
118 FL2FXCONST_SGL(0.68f) /* ACELP synth pre-emphasis factor */
119
120 #define ACELP_HEADROOM 1
121 #define ACELP_OUTSCALE (MDCT_OUT_HEADROOM - ACELP_HEADROOM)
122
123 /**
124 * \brief Calculate pre-emphasis (1 - mu z^-1) on input signal.
125 * \param[in] in pointer to input signal; in[-1] is also needed.
126 * \param[out] out pointer to output signal.
127 * \param[in] L length of filtering.
128 */
129 /* static */
E_UTIL_preemph(const FIXP_DBL * in,FIXP_DBL * out,INT L)130 void E_UTIL_preemph(const FIXP_DBL *in, FIXP_DBL *out, INT L) {
131 int i;
132
133 for (i = 0; i < L; i++) {
134 out[i] = fAddSaturate(in[i], -fMult(PREEMPH_FAC, in[i - 1]));
135 }
136
137 return;
138 }
139
140 /**
141 * \brief Calculate de-emphasis 1/(1 - TILT_CODE z^-1) on innovative codebook
142 * vector.
143 * \param[in,out] x innovative codebook vector.
144 */
Preemph_code(FIXP_COD x[])145 static void Preemph_code(
146 FIXP_COD x[] /* (i/o) : input signal overwritten by the output */
147 ) {
148 int i;
149 FIXP_DBL L_tmp;
150
151 /* ARM926: 12 cycles per sample */
152 for (i = L_SUBFR - 1; i > 0; i--) {
153 L_tmp = FX_COD2FX_DBL(x[i]);
154 L_tmp -= fMultDiv2(x[i - 1], TILT_CODE2);
155 x[i] = FX_DBL2FX_COD(L_tmp);
156 }
157 }
158
159 /**
160 * \brief Apply pitch sharpener to the innovative codebook vector.
161 * \param[in,out] x innovative codebook vector.
162 * \param[in] pit_lag decoded pitch lag.
163 */
Pit_shrp(FIXP_COD x[],int pit_lag)164 static void Pit_shrp(
165 FIXP_COD x[], /* in/out: impulse response (or algebraic code) */
166 int pit_lag /* input : pitch lag */
167 ) {
168 int i;
169 FIXP_DBL L_tmp;
170
171 for (i = pit_lag; i < L_SUBFR; i++) {
172 L_tmp = FX_COD2FX_DBL(x[i]);
173 L_tmp += fMult(x[i - pit_lag], PIT_SHARP);
174 x[i] = FX_DBL2FX_COD(L_tmp);
175 }
176
177 return;
178 }
179
180 /**
181 * \brief Calculate Quantized codebook gain, Quantized pitch gain and unbiased
182 * Innovative code vector energy.
183 * \param[in] index index of quantizer.
184 * \param[in] code innovative code vector with exponent = SF_CODE.
185 * \param[out] gain_pit Quantized pitch gain g_p with exponent = SF_GAIN_P.
186 * \param[out] gain_code Quantized codebook gain g_c.
187 * \param[in] mean_ener mean_ener defined in open-loop (2 bits), exponent = 7.
188 * \param[out] E_code unbiased innovative code vector energy.
189 * \param[out] E_code_e exponent of unbiased innovative code vector energy.
190 */
191
192 #define SF_MEAN_ENER_LG10 9
193
194 /* pow(10.0, {18, 30, 42, 54}/20.0) /(float)(1<<SF_MEAN_ENER_LG10) */
195 static const FIXP_DBL pow_10_mean_energy[4] = {0x01fc5ebd, 0x07e7db92,
196 0x1f791f65, 0x7d4bfba3};
197
D_gain2_plus(int index,FIXP_COD code[],FIXP_SGL * gain_pit,FIXP_DBL * gain_code,int mean_ener_bits,int bfi,FIXP_SGL * past_gpit,FIXP_DBL * past_gcode,FIXP_DBL * pEner_code,int * pEner_code_e)198 static void D_gain2_plus(int index, FIXP_COD code[], FIXP_SGL *gain_pit,
199 FIXP_DBL *gain_code, int mean_ener_bits, int bfi,
200 FIXP_SGL *past_gpit, FIXP_DBL *past_gcode,
201 FIXP_DBL *pEner_code, int *pEner_code_e) {
202 FIXP_DBL Ltmp;
203 FIXP_DBL gcode0, gcode_inov;
204 INT gcode0_e, gcode_inov_e;
205 int i;
206
207 FIXP_DBL ener_code;
208 INT ener_code_e;
209
210 /* ener_code = sum(code[]^2) */
211 ener_code = FIXP_DBL(0);
212 for (i = 0; i < L_SUBFR; i++) {
213 ener_code += fPow2Div2(code[i]);
214 }
215
216 ener_code_e = fMax(fNorm(ener_code) - 1, 0);
217 ener_code <<= ener_code_e;
218 ener_code_e = 2 * SF_CODE + 1 - ener_code_e;
219
220 /* export energy of code for calc_period_factor() */
221 *pEner_code = ener_code;
222 *pEner_code_e = ener_code_e;
223
224 ener_code += scaleValue(FL2FXCONST_DBL(0.01f), -ener_code_e);
225
226 /* ener_code *= 1/L_SUBFR, and make exponent even (because of square root
227 * below). */
228 if (ener_code_e & 1) {
229 ener_code_e -= 5;
230 ener_code >>= 1;
231 } else {
232 ener_code_e -= 6;
233 }
234 gcode_inov = invSqrtNorm2(ener_code, &gcode0_e);
235 gcode_inov_e = gcode0_e - (ener_code_e >> 1);
236
237 if (bfi) {
238 FIXP_DBL tgcode;
239 FIXP_SGL tgpit;
240
241 tgpit = *past_gpit;
242
243 if (tgpit > FL2FXCONST_SGL(0.95f / (1 << SF_GAIN_P))) {
244 tgpit = FL2FXCONST_SGL(0.95f / (1 << SF_GAIN_P));
245 } else if (tgpit < FL2FXCONST_SGL(0.5f / (1 << SF_GAIN_P))) {
246 tgpit = FL2FXCONST_SGL(0.5f / (1 << SF_GAIN_P));
247 }
248 *gain_pit = tgpit;
249 tgpit = FX_DBL2FX_SGL(fMult(tgpit, FL2FXCONST_DBL(0.95f)));
250 *past_gpit = tgpit;
251
252 tgpit = FL2FXCONST_SGL(1.4f / (1 << SF_GAIN_P)) - tgpit;
253 tgcode = fMult(*past_gcode, tgpit) << SF_GAIN_P;
254 *gain_code = scaleValue(fMult(tgcode, gcode_inov), gcode_inov_e);
255 *past_gcode = tgcode;
256
257 return;
258 }
259
260 /*-------------- Decode gains ---------------*/
261 /*
262 gcode0 = pow(10.0, (float)mean_ener/20.0);
263 gcode0 = gcode0 / sqrt(ener_code/L_SUBFR);
264 */
265 gcode0 = pow_10_mean_energy[mean_ener_bits];
266 gcode0 = fMultDiv2(gcode0, gcode_inov);
267 gcode0_e = gcode0_e + SF_MEAN_ENER_LG10 - (ener_code_e >> 1) + 1;
268
269 i = index << 1;
270 *gain_pit = t_qua_gain7b[i]; /* adaptive codebook gain */
271 /* t_qua_gain[ind2p1] : fixed codebook gain correction factor */
272 Ltmp = fMult(t_qua_gain7b[i + 1], gcode0);
273 *gain_code = scaleValue(Ltmp, gcode0_e - SF_GAIN_C + SF_QUA_GAIN7B);
274
275 /* update bad frame handler */
276 *past_gpit = *gain_pit;
277
278 /*--------------------------------------------------------
279 past_gcode = gain_code/gcode_inov
280 --------------------------------------------------------*/
281 {
282 FIXP_DBL gcode_m;
283 INT gcode_e;
284
285 gcode_m = fDivNormHighPrec(Ltmp, gcode_inov, &gcode_e);
286 gcode_e += (gcode0_e - SF_GAIN_C + SF_QUA_GAIN7B) - (gcode_inov_e);
287 *past_gcode = scaleValue(gcode_m, gcode_e);
288 }
289 }
290
291 /**
292 * \brief Calculate period/voicing factor r_v
293 * \param[in] exc pitch excitation.
294 * \param[in] gain_pit gain of pitch g_p.
295 * \param[in] gain_code gain of code g_c.
296 * \param[in] gain_code_e exponent of gain of code.
297 * \param[in] ener_code unbiased innovative code vector energy.
298 * \param[in] ener_code_e exponent of unbiased innovative code vector energy.
299 * \return period/voice factor r_v (-1=unvoiced to 1=voiced), exponent SF_PFAC.
300 */
calc_period_factor(FIXP_DBL exc[],FIXP_SGL gain_pit,FIXP_DBL gain_code,FIXP_DBL ener_code,int ener_code_e)301 static FIXP_DBL calc_period_factor(FIXP_DBL exc[], FIXP_SGL gain_pit,
302 FIXP_DBL gain_code, FIXP_DBL ener_code,
303 int ener_code_e) {
304 int ener_exc_e, L_tmp_e, s = 0;
305 FIXP_DBL ener_exc, L_tmp;
306 FIXP_DBL period_fac;
307
308 /* energy of pitch excitation */
309 ener_exc = (FIXP_DBL)0;
310 for (int i = 0; i < L_SUBFR; i++) {
311 ener_exc += fPow2Div2(exc[i]) >> s;
312 if (ener_exc >= FL2FXCONST_DBL(0.5f)) {
313 ener_exc >>= 1;
314 s++;
315 }
316 }
317
318 ener_exc_e = fNorm(ener_exc);
319 ener_exc = fMult(ener_exc << ener_exc_e, fPow2(gain_pit));
320 if (ener_exc != (FIXP_DBL)0) {
321 ener_exc_e = 2 * SF_EXC + 1 + 2 * SF_GAIN_P - ener_exc_e + s;
322 } else {
323 ener_exc_e = 0;
324 }
325
326 /* energy of innovative code excitation */
327 /* L_tmp = ener_code * gain_code*gain_code; */
328 L_tmp_e = fNorm(gain_code);
329 L_tmp = fPow2(gain_code << L_tmp_e);
330 L_tmp = fMult(ener_code, L_tmp);
331 L_tmp_e = 2 * SF_GAIN_C + ener_code_e - 2 * L_tmp_e;
332
333 /* Find common exponent */
334 {
335 FIXP_DBL num, den;
336 int exp_diff;
337
338 exp_diff = ener_exc_e - L_tmp_e;
339 if (exp_diff >= 0) {
340 ener_exc >>= 1;
341 if (exp_diff <= DFRACT_BITS - 2) {
342 L_tmp >>= exp_diff + 1;
343 } else {
344 L_tmp = (FIXP_DBL)0;
345 }
346 den = ener_exc + L_tmp;
347 if (ener_exc_e < DFRACT_BITS - 1) {
348 den += scaleValue(FL2FXCONST_DBL(0.01f), -ener_exc_e - 1);
349 }
350 } else {
351 if (exp_diff >= -(DFRACT_BITS - 2)) {
352 ener_exc >>= 1 - exp_diff;
353 } else {
354 ener_exc = (FIXP_DBL)0;
355 }
356 L_tmp >>= 1;
357 den = ener_exc + L_tmp;
358 if (L_tmp_e < DFRACT_BITS - 1) {
359 den += scaleValue(FL2FXCONST_DBL(0.01f), -L_tmp_e - 1);
360 }
361 }
362 num = (ener_exc - L_tmp);
363 num >>= SF_PFAC;
364
365 if (den > (FIXP_DBL)0) {
366 if (ener_exc > L_tmp) {
367 period_fac = schur_div(num, den, 16);
368 } else {
369 period_fac = -schur_div(-num, den, 16);
370 }
371 } else {
372 period_fac = (FIXP_DBL)MAXVAL_DBL;
373 }
374 }
375
376 /* exponent = SF_PFAC */
377 return period_fac;
378 }
379
380 /*------------------------------------------------------------*
381 * noise enhancer *
382 * ~~~~~~~~~~~~~~ *
383 * - Enhance excitation on noise. (modify gain of code) *
384 * If signal is noisy and LPC filter is stable, move gain *
385 * of code 1.5 dB toward gain of code threshold. *
386 * This decrease by 3 dB noise energy variation. *
387 *------------------------------------------------------------*/
388 /**
389 * \brief Enhance excitation on noise. (modify gain of code)
390 * \param[in] gain_code Quantized codebook gain g_c, exponent = SF_GAIN_C.
391 * \param[in] period_fac periodicity factor, exponent = SF_PFAC.
392 * \param[in] stab_fac stability factor, exponent = SF_STAB.
393 * \param[in,out] p_gc_threshold modified gain of previous subframe.
394 * \return gain_code smoothed gain of code g_sc, exponent = SF_GAIN_C.
395 */
396 static FIXP_DBL
noise_enhancer(FIXP_DBL gain_code,FIXP_DBL period_fac,FIXP_SGL stab_fac,FIXP_DBL * p_gc_threshold)397 noise_enhancer(/* (o) : smoothed gain g_sc SF_GAIN_C */
398 FIXP_DBL gain_code, /* (i) : Quantized codebook gain SF_GAIN_C */
399 FIXP_DBL period_fac, /* (i) : periodicity factor (-1=unvoiced to
400 1=voiced), SF_PFAC */
401 FIXP_SGL stab_fac, /* (i) : stability factor (0 <= ... < 1.0)
402 SF_STAB */
403 FIXP_DBL
404 *p_gc_threshold) /* (io): gain of code threshold SF_GAIN_C */
405 {
406 FIXP_DBL fac, L_tmp, gc_thres;
407
408 gc_thres = *p_gc_threshold;
409
410 L_tmp = gain_code;
411 if (L_tmp < gc_thres) {
412 L_tmp += fMultDiv2(gain_code,
413 FL2FXCONST_SGL(2.0 * 0.19f)); /* +1.5dB => *(1.0+0.19) */
414 if (L_tmp > gc_thres) {
415 L_tmp = gc_thres;
416 }
417 } else {
418 L_tmp = fMult(gain_code,
419 FL2FXCONST_SGL(1.0f / 1.19f)); /* -1.5dB => *10^(-1.5/20) */
420 if (L_tmp < gc_thres) {
421 L_tmp = gc_thres;
422 }
423 }
424 *p_gc_threshold = L_tmp;
425
426 /* voicing factor lambda = 0.5*(1-period_fac) */
427 /* gain smoothing factor S_m = lambda*stab_fac (=fac)
428 = 0.5(stab_fac - stab_fac * period_fac) */
429 fac = (FX_SGL2FX_DBL(stab_fac) >> (SF_PFAC + 1)) -
430 fMultDiv2(stab_fac, period_fac);
431 /* fac_e = SF_PFAC + SF_STAB */
432 FDK_ASSERT(fac >= (FIXP_DBL)0);
433
434 /* gain_code = (float)((fac*tmp) + ((1.0-fac)*gain_code)); */
435 gain_code = fMult(fac, L_tmp) -
436 fMult(FL2FXCONST_DBL(-1.0f / (1 << (SF_PFAC + SF_STAB))) + fac,
437 gain_code);
438 gain_code <<= (SF_PFAC + SF_STAB);
439
440 return gain_code;
441 }
442
443 /**
444 * \brief Update adaptive codebook u'(n) (exc)
445 * Enhance pitch of c(n) and build post-processed excitation u(n) (exc2)
446 * \param[in] code innovative codevector c(n), exponent = SF_CODE.
447 * \param[in,out] exc filtered adaptive codebook v(n), exponent = SF_EXC.
448 * \param[in] gain_pit adaptive codebook gain, exponent = SF_GAIN_P.
449 * \param[in] gain_code innovative codebook gain g_c, exponent = SF_GAIN_C.
450 * \param[in] gain_code_smoothed smoothed innov. codebook gain g_sc, exponent =
451 * SF_GAIN_C.
452 * \param[in] period_fac periodicity factor r_v, exponent = SF_PFAC.
453 * \param[out] exc2 post-processed excitation u(n), exponent = SF_EXC.
454 */
BuildAdaptiveExcitation(FIXP_COD code[],FIXP_DBL exc[],FIXP_SGL gain_pit,FIXP_DBL gain_code,FIXP_DBL gain_code_smoothed,FIXP_DBL period_fac,FIXP_DBL exc2[])455 void BuildAdaptiveExcitation(
456 FIXP_COD code[], /* (i) : algebraic codevector c(n) Q9 */
457 FIXP_DBL exc[], /* (io): filtered adaptive codebook v(n) Q15 */
458 FIXP_SGL gain_pit, /* (i) : adaptive codebook gain g_p Q14 */
459 FIXP_DBL gain_code, /* (i) : innovative codebook gain g_c Q16 */
460 FIXP_DBL gain_code_smoothed, /* (i) : smoothed innov. codebook gain g_sc
461 Q16 */
462 FIXP_DBL period_fac, /* (i) : periodicity factor r_v Q15 */
463 FIXP_DBL exc2[] /* (o) : post-processed excitation u(n) Q15 */
464 ) {
465 /* Note: code[L_SUBFR] and exc2[L_SUBFR] share the same memory!
466 If exc2[i] is written, code[i] will be destroyed!
467 */
468 #define SF_HEADROOM (1)
469 #define SF (SF_CODE + SF_GAIN_C + 1 - SF_EXC - SF_HEADROOM)
470 #define SF_GAIN_P2 (SF_GAIN_P - SF_HEADROOM)
471
472 int i;
473 FIXP_DBL tmp, cpe, code_smooth_prev, code_smooth;
474
475 FIXP_COD code_i;
476 FIXP_DBL cpe_code_smooth, cpe_code_smooth_prev;
477
478 /* cpe = (1+r_v)/8 * 2 ; ( SF = -1) */
479 cpe = (period_fac >> (2 - SF_PFAC)) + FL2FXCONST_DBL(0.25f);
480
481 /* u'(n) */
482 tmp = fMultDiv2(*exc, gain_pit) << (SF_GAIN_P2 + 1); /* v(0)*g_p */
483 *exc++ = (tmp + (fMultDiv2(code[0], gain_code) << SF)) << SF_HEADROOM;
484
485 /* u(n) */
486 code_smooth_prev = fMultDiv2(*code++, gain_code_smoothed)
487 << SF; /* c(0) * g_sc */
488 code_i = *code++;
489 code_smooth = fMultDiv2(code_i, gain_code_smoothed) << SF; /* c(1) * g_sc */
490 tmp += code_smooth_prev; /* tmp = v(0)*g_p + c(0)*g_sc */
491 cpe_code_smooth = fMultDiv2(cpe, code_smooth);
492 *exc2++ = (tmp - cpe_code_smooth) << SF_HEADROOM;
493 cpe_code_smooth_prev = fMultDiv2(cpe, code_smooth_prev);
494
495 i = L_SUBFR - 2;
496 do /* ARM926: 22 cycles per iteration */
497 {
498 /* u'(n) */
499 tmp = fMultDiv2(*exc, gain_pit) << (SF_GAIN_P2 + 1);
500 *exc++ = (tmp + (fMultDiv2(code_i, gain_code) << SF)) << SF_HEADROOM;
501 /* u(n) */
502 tmp += code_smooth; /* += g_sc * c(i) */
503 tmp -= cpe_code_smooth_prev;
504 cpe_code_smooth_prev = cpe_code_smooth;
505 code_i = *code++;
506 code_smooth = fMultDiv2(code_i, gain_code_smoothed) << SF;
507 cpe_code_smooth = fMultDiv2(cpe, code_smooth);
508 *exc2++ = (tmp - cpe_code_smooth)
509 << SF_HEADROOM; /* tmp - c_pe * g_sc * c(i+1) */
510 } while (--i != 0);
511
512 /* u'(n) */
513 tmp = fMultDiv2(*exc, gain_pit) << (SF_GAIN_P2 + 1);
514 *exc = (tmp + (fMultDiv2(code_i, gain_code) << SF)) << SF_HEADROOM;
515 /* u(n) */
516 tmp += code_smooth;
517 tmp -= cpe_code_smooth_prev;
518 *exc2++ = tmp << SF_HEADROOM;
519
520 return;
521 }
522
523 /**
524 * \brief Interpolate LPC vector in LSP domain for current subframe and convert
525 * to LP domain
526 * \param[in] lsp_old LPC vector (LSP domain) corresponding to the beginning of
527 * current ACELP frame.
528 * \param[in] lsp_new LPC vector (LSP domain) corresponding to the end of
529 * current ACELP frame.
530 * \param[in] subfr_nr number of current ACELP subframe 0..3.
531 * \param[in] nb_subfr total number of ACELP subframes in this frame.
532 * \param[out] A LP filter coefficients for current ACELP subframe, exponent =
533 * SF_A_COEFFS.
534 */
535 /* static */
int_lpc_acelp(const FIXP_LPC lsp_old[],const FIXP_LPC lsp_new[],int subfr_nr,int nb_subfr,FIXP_LPC A[],INT * A_exp)536 void int_lpc_acelp(
537 const FIXP_LPC lsp_old[], /* input : LSPs from past frame */
538 const FIXP_LPC lsp_new[], /* input : LSPs from present frame */
539 int subfr_nr, int nb_subfr,
540 FIXP_LPC
541 A[], /* output: interpolated LP coefficients for current subframe */
542 INT *A_exp) {
543 int i;
544 FIXP_LPC lsp_interpol[M_LP_FILTER_ORDER];
545 FIXP_SGL fac_old, fac_new;
546
547 FDK_ASSERT((nb_subfr == 3) || (nb_subfr == 4));
548
549 fac_old = lsp_interpol_factor[nb_subfr & 0x1][(nb_subfr - 1) - subfr_nr];
550 fac_new = lsp_interpol_factor[nb_subfr & 0x1][subfr_nr];
551 for (i = 0; i < M_LP_FILTER_ORDER; i++) {
552 lsp_interpol[i] = FX_DBL2FX_LPC(
553 (fMultDiv2(lsp_old[i], fac_old) + fMultDiv2(lsp_new[i], fac_new)) << 1);
554 }
555
556 E_LPC_f_lsp_a_conversion(lsp_interpol, A, A_exp);
557
558 return;
559 }
560
561 /**
562 * \brief Perform LP synthesis by filtering the post-processed excitation u(n)
563 * through the LP synthesis filter 1/A(z)
564 * \param[in] a LP filter coefficients, exponent = SF_A_COEFFS.
565 * \param[in] length length of input/output signal.
566 * \param[in] x post-processed excitation u(n).
567 * \param[in,out] y LP synthesis signal and filter memory
568 * y[-M_LP_FILTER_ORDER..-1].
569 */
570
571 /* static */
Syn_filt(const FIXP_LPC a[],const INT a_exp,INT length,FIXP_DBL x[],FIXP_DBL y[])572 void Syn_filt(const FIXP_LPC a[], /* (i) : a[m] prediction coefficients Q12 */
573 const INT a_exp,
574 INT length, /* (i) : length of input/output signal (64|128) */
575 FIXP_DBL x[], /* (i) : input signal Qx */
576 FIXP_DBL y[] /* (i/o) : filter states / output signal Qx-s*/
577 ) {
578 int i, j;
579 FIXP_DBL L_tmp;
580
581 for (i = 0; i < length; i++) {
582 L_tmp = (FIXP_DBL)0;
583
584 for (j = 0; j < M_LP_FILTER_ORDER; j++) {
585 L_tmp -= fMultDiv2(a[j], y[i - (j + 1)]) >> (LP_FILTER_SCALE - 1);
586 }
587
588 L_tmp = scaleValue(L_tmp, a_exp + LP_FILTER_SCALE);
589 y[i] = fAddSaturate(L_tmp, x[i]);
590 }
591
592 return;
593 }
594
595 /**
596 * \brief Calculate de-emphasis 1/(1 - mu z^-1) on input signal.
597 * \param[in] x input signal.
598 * \param[out] y output signal.
599 * \param[in] L length of signal.
600 * \param[in,out] mem memory (signal[-1]).
601 */
602 /* static */
Deemph(FIXP_DBL * x,FIXP_DBL * y,int L,FIXP_DBL * mem)603 void Deemph(FIXP_DBL *x, FIXP_DBL *y, int L, FIXP_DBL *mem) {
604 int i;
605 FIXP_DBL yi = *mem;
606
607 for (i = 0; i < L; i++) {
608 FIXP_DBL xi = x[i] >> 1;
609 xi = fMultAddDiv2(xi, PREEMPH_FAC, yi);
610 yi = SATURATE_LEFT_SHIFT(xi, 1, 32);
611 y[i] = yi;
612 }
613 *mem = yi;
614 return;
615 }
616
617 /**
618 * \brief Compute the LP residual by filtering the input speech through the
619 * analysis filter A(z).
620 * \param[in] a LP filter coefficients, exponent = SF_A_COEFFS
621 * \param[in] x input signal (note that values x[-m..-1] are needed), exponent =
622 * SF_SYNTH
623 * \param[out] y output signal (residual), exponent = SF_EXC
624 * \param[in] l length of filtering
625 */
626 /* static */
E_UTIL_residu(const FIXP_LPC * a,const INT a_exp,FIXP_DBL * x,FIXP_DBL * y,INT l)627 void E_UTIL_residu(const FIXP_LPC *a, const INT a_exp, FIXP_DBL *x, FIXP_DBL *y,
628 INT l) {
629 FIXP_DBL s;
630 INT i, j;
631
632 /* (note that values x[-m..-1] are needed) */
633 for (i = 0; i < l; i++) {
634 s = (FIXP_DBL)0;
635
636 for (j = 0; j < M_LP_FILTER_ORDER; j++) {
637 s += fMultDiv2(a[j], x[i - j - 1]) >> (LP_FILTER_SCALE - 1);
638 }
639
640 s = scaleValue(s, a_exp + LP_FILTER_SCALE);
641 y[i] = fAddSaturate(s, x[i]);
642 }
643
644 return;
645 }
646
647 /* use to map subfr number to number of bits used for acb_index */
648 static const UCHAR num_acb_idx_bits_table[2][NB_SUBFR] = {
649 {9, 6, 9, 6}, /* coreCoderFrameLength == 1024 */
650 {9, 6, 6, 0} /* coreCoderFrameLength == 768 */
651 };
652
DecodePitchLag(HANDLE_FDK_BITSTREAM hBs,const UCHAR num_acb_idx_bits,const int PIT_MIN,const int PIT_FR2,const int PIT_FR1,const int PIT_MAX,int * pT0,int * pT0_frac,int * pT0_min,int * pT0_max)653 static int DecodePitchLag(HANDLE_FDK_BITSTREAM hBs,
654 const UCHAR num_acb_idx_bits,
655 const int PIT_MIN, /* TMIN */
656 const int PIT_FR2, /* TFR2 */
657 const int PIT_FR1, /* TFR1 */
658 const int PIT_MAX, /* TMAX */
659 int *pT0, int *pT0_frac, int *pT0_min, int *pT0_max) {
660 int acb_idx;
661 int error = 0;
662 int T0, T0_frac;
663
664 FDK_ASSERT((num_acb_idx_bits == 9) || (num_acb_idx_bits == 6));
665
666 acb_idx = FDKreadBits(hBs, num_acb_idx_bits);
667
668 if (num_acb_idx_bits == 6) {
669 /* When the pitch value is encoded on 6 bits, a pitch resolution of 1/4 is
670 always used in the range [T1-8, T1+7.75], where T1 is nearest integer to
671 the fractional pitch lag of the previous subframe.
672 */
673 T0 = *pT0_min + acb_idx / 4;
674 T0_frac = acb_idx & 0x3;
675 } else { /* num_acb_idx_bits == 9 */
676 /* When the pitch value is encoded on 9 bits, a fractional pitch delay is
677 used with resolutions 0.25 in the range [TMIN, TFR2-0.25], resolutions
678 0.5 in the range [TFR2, TFR1-0.5], and integers only in the range [TFR1,
679 TMAX]. NOTE: for small sampling rates TMAX can get smaller than TFR1.
680 */
681 int T0_min, T0_max;
682
683 if (acb_idx < (PIT_FR2 - PIT_MIN) * 4) {
684 /* first interval with 0.25 pitch resolution */
685 T0 = PIT_MIN + (acb_idx / 4);
686 T0_frac = acb_idx & 0x3;
687 } else if (acb_idx < ((PIT_FR2 - PIT_MIN) * 4 + (PIT_FR1 - PIT_FR2) * 2)) {
688 /* second interval with 0.5 pitch resolution */
689 acb_idx -= (PIT_FR2 - PIT_MIN) * 4;
690 T0 = PIT_FR2 + (acb_idx / 2);
691 T0_frac = (acb_idx & 0x1) * 2;
692 } else {
693 /* third interval with 1.0 pitch resolution */
694 T0 = acb_idx + PIT_FR1 - ((PIT_FR2 - PIT_MIN) * 4) -
695 ((PIT_FR1 - PIT_FR2) * 2);
696 T0_frac = 0;
697 }
698 /* find T0_min and T0_max for subframe 1 or 3 */
699 T0_min = T0 - 8;
700 if (T0_min < PIT_MIN) {
701 T0_min = PIT_MIN;
702 }
703 T0_max = T0_min + 15;
704 if (T0_max > PIT_MAX) {
705 T0_max = PIT_MAX;
706 T0_min = T0_max - 15;
707 }
708 *pT0_min = T0_min;
709 *pT0_max = T0_max;
710 }
711 *pT0 = T0;
712 *pT0_frac = T0_frac;
713
714 return error;
715 }
ConcealPitchLag(CAcelpStaticMem * acelp_mem,const int PIT_MAX,int * pT0,int * pT0_frac)716 static void ConcealPitchLag(CAcelpStaticMem *acelp_mem, const int PIT_MAX,
717 int *pT0, int *pT0_frac) {
718 USHORT *pold_T0 = &acelp_mem->old_T0;
719 UCHAR *pold_T0_frac = &acelp_mem->old_T0_frac;
720
721 if ((int)*pold_T0 >= PIT_MAX) {
722 *pold_T0 = (UCHAR)(PIT_MAX - 5);
723 }
724 *pT0 = (int)*pold_T0;
725 *pT0_frac = (int)*pold_T0_frac;
726 }
727
728 static UCHAR tab_coremode2nbits[8] = {20, 28, 36, 44, 52, 64, 12, 16};
729
MapCoreMode2NBits(int core_mode)730 static int MapCoreMode2NBits(int core_mode) {
731 return (int)tab_coremode2nbits[core_mode];
732 }
733
CLpd_AcelpDecode(CAcelpStaticMem * acelp_mem,INT i_offset,const FIXP_LPC lsp_old[M_LP_FILTER_ORDER],const FIXP_LPC lsp_new[M_LP_FILTER_ORDER],FIXP_SGL stab_fac,CAcelpChannelData * pAcelpData,INT numLostSubframes,int lastLpcLost,int frameCnt,FIXP_DBL synth[],int pT[],FIXP_DBL * pit_gain,INT coreCoderFrameLength)734 void CLpd_AcelpDecode(CAcelpStaticMem *acelp_mem, INT i_offset,
735 const FIXP_LPC lsp_old[M_LP_FILTER_ORDER],
736 const FIXP_LPC lsp_new[M_LP_FILTER_ORDER],
737 FIXP_SGL stab_fac, CAcelpChannelData *pAcelpData,
738 INT numLostSubframes, int lastLpcLost, int frameCnt,
739 FIXP_DBL synth[], int pT[], FIXP_DBL *pit_gain,
740 INT coreCoderFrameLength) {
741 int i_subfr, subfr_nr, l_div, T;
742 int T0 = -1, T0_frac = -1; /* mark invalid */
743
744 int pit_gain_index = 0;
745
746 const int PIT_MAX = PIT_MAX_12k8 + (6 * i_offset); /* maximum pitch lag */
747
748 FIXP_COD *code;
749 FIXP_DBL *exc2;
750 FIXP_DBL *syn;
751 FIXP_DBL *exc;
752 FIXP_LPC A[M_LP_FILTER_ORDER];
753 INT A_exp;
754
755 FIXP_DBL period_fac;
756 FIXP_SGL gain_pit;
757 FIXP_DBL gain_code, gain_code_smooth, Ener_code;
758 int Ener_code_e;
759 int n;
760 int bfi = (numLostSubframes > 0) ? 1 : 0;
761
762 C_ALLOC_SCRATCH_START(
763 exc_buf, FIXP_DBL,
764 PIT_MAX_MAX + L_INTERPOL + L_DIV + 1); /* 411 + 17 + 256 + 1 = 685 */
765 C_ALLOC_SCRATCH_START(syn_buf, FIXP_DBL,
766 M_LP_FILTER_ORDER + L_DIV); /* 16 + 256 = 272 */
767 /* use same memory for code[L_SUBFR] and exc2[L_SUBFR] */
768 C_ALLOC_SCRATCH_START(tmp_buf, FIXP_DBL, L_SUBFR); /* 64 */
769 /* make sure they don't overlap if they are accessed alternatingly in
770 * BuildAdaptiveExcitation() */
771 #if (COD_BITS == FRACT_BITS)
772 code = (FIXP_COD *)(tmp_buf + L_SUBFR / 2);
773 #elif (COD_BITS == DFRACT_BITS)
774 code = (FIXP_COD *)tmp_buf;
775 #endif
776 exc2 = (FIXP_DBL *)tmp_buf;
777
778 syn = syn_buf + M_LP_FILTER_ORDER;
779 exc = exc_buf + PIT_MAX_MAX + L_INTERPOL;
780
781 FDKmemcpy(syn_buf, acelp_mem->old_syn_mem,
782 M_LP_FILTER_ORDER * sizeof(FIXP_DBL));
783 FDKmemcpy(exc_buf, acelp_mem->old_exc_mem,
784 (PIT_MAX_MAX + L_INTERPOL) * sizeof(FIXP_DBL));
785
786 FDKmemclear(exc_buf + (PIT_MAX_MAX + L_INTERPOL),
787 (L_DIV + 1) * sizeof(FIXP_DBL));
788
789 l_div = coreCoderFrameLength / NB_DIV;
790
791 for (i_subfr = 0, subfr_nr = 0; i_subfr < l_div;
792 i_subfr += L_SUBFR, subfr_nr++) {
793 /*-------------------------------------------------*
794 * - Decode pitch lag (T0 and T0_frac) *
795 *-------------------------------------------------*/
796 if (bfi) {
797 ConcealPitchLag(acelp_mem, PIT_MAX, &T0, &T0_frac);
798 } else {
799 T0 = (int)pAcelpData->T0[subfr_nr];
800 T0_frac = (int)pAcelpData->T0_frac[subfr_nr];
801 }
802
803 /*-------------------------------------------------*
804 * - Find the pitch gain, the interpolation filter *
805 * and the adaptive codebook vector. *
806 *-------------------------------------------------*/
807 Pred_lt4(&exc[i_subfr], T0, T0_frac);
808
809 if ((!bfi && pAcelpData->ltp_filtering_flag[subfr_nr] == 0) ||
810 (bfi && numLostSubframes == 1 && stab_fac < FL2FXCONST_SGL(0.25f))) {
811 /* find pitch excitation with lp filter: v'(n) => v(n) */
812 Pred_lt4_postfilter(&exc[i_subfr]);
813 }
814
815 /*-------------------------------------------------------*
816 * - Decode innovative codebook. *
817 * - Add the fixed-gain pitch contribution to code[]. *
818 *-------------------------------------------------------*/
819 if (bfi) {
820 for (n = 0; n < L_SUBFR; n++) {
821 code[n] =
822 FX_SGL2FX_COD((FIXP_SGL)E_UTIL_random(&acelp_mem->seed_ace)) >> 4;
823 }
824 } else {
825 int nbits = MapCoreMode2NBits((int)pAcelpData->acelp_core_mode);
826 D_ACELP_decode_4t64(pAcelpData->icb_index[subfr_nr], nbits, &code[0]);
827 }
828
829 T = T0;
830 if (T0_frac > 2) {
831 T += 1;
832 }
833
834 Preemph_code(code);
835 Pit_shrp(code, T);
836
837 /* Output pitch lag for bass post-filter */
838 if (T > PIT_MAX) {
839 pT[subfr_nr] = PIT_MAX;
840 } else {
841 pT[subfr_nr] = T;
842 }
843 D_gain2_plus(
844 pAcelpData->gains[subfr_nr],
845 code, /* (i) : Innovative code vector, exponent = SF_CODE */
846 &gain_pit, /* (o) : Quantized pitch gain, exponent = SF_GAIN_P */
847 &gain_code, /* (o) : Quantized codebook gain */
848 pAcelpData
849 ->mean_energy, /* (i) : mean_ener defined in open-loop (2 bits) */
850 bfi, &acelp_mem->past_gpit, &acelp_mem->past_gcode,
851 &Ener_code, /* (o) : Innovative code vector energy */
852 &Ener_code_e); /* (o) : Innovative code vector energy exponent */
853
854 pit_gain[pit_gain_index++] = FX_SGL2FX_DBL(gain_pit);
855
856 /* calc periodicity factor r_v */
857 period_fac =
858 calc_period_factor(/* (o) : factor (-1=unvoiced to 1=voiced) */
859 &exc[i_subfr], /* (i) : pitch excitation, exponent =
860 SF_EXC */
861 gain_pit, /* (i) : gain of pitch, exponent =
862 SF_GAIN_P */
863 gain_code, /* (i) : gain of code */
864 Ener_code, /* (i) : Energy of code[] */
865 Ener_code_e); /* (i) : Exponent of energy of code[]
866 */
867
868 if (lastLpcLost && frameCnt == 0) {
869 if (gain_pit > FL2FXCONST_SGL(1.0f / (1 << SF_GAIN_P))) {
870 gain_pit = FL2FXCONST_SGL(1.0f / (1 << SF_GAIN_P));
871 }
872 }
873
874 gain_code_smooth =
875 noise_enhancer(/* (o) : smoothed gain g_sc exponent = SF_GAIN_C */
876 gain_code, /* (i) : Quantized codebook gain */
877 period_fac, /* (i) : periodicity factor (-1=unvoiced to
878 1=voiced) */
879 stab_fac, /* (i) : stability factor (0 <= ... < 1),
880 exponent = 1 */
881 &acelp_mem->gc_threshold);
882
883 /* Compute adaptive codebook update u'(n), pitch enhancement c'(n) and
884 * post-processed excitation u(n). */
885 BuildAdaptiveExcitation(code, exc + i_subfr, gain_pit, gain_code,
886 gain_code_smooth, period_fac, exc2);
887
888 /* Interpolate filter coeffs for current subframe in lsp domain and convert
889 * to LP domain */
890 int_lpc_acelp(lsp_old, /* input : LSPs from past frame */
891 lsp_new, /* input : LSPs from present frame */
892 subfr_nr, /* input : ACELP subframe index */
893 coreCoderFrameLength / L_DIV,
894 A, /* output: LP coefficients of this subframe */
895 &A_exp);
896
897 Syn_filt(A, /* (i) : a[m] prediction coefficients */
898 A_exp, L_SUBFR, /* (i) : length */
899 exc2, /* (i) : input signal */
900 &syn[i_subfr] /* (i/o) : filter states / output signal */
901 );
902
903 } /* end of subframe loop */
904
905 /* update pitch value for bfi procedure */
906 acelp_mem->old_T0_frac = T0_frac;
907 acelp_mem->old_T0 = T0;
908
909 /* save old excitation and old synthesis memory for next ACELP frame */
910 FDKmemcpy(acelp_mem->old_exc_mem, exc + l_div - (PIT_MAX_MAX + L_INTERPOL),
911 sizeof(FIXP_DBL) * (PIT_MAX_MAX + L_INTERPOL));
912 FDKmemcpy(acelp_mem->old_syn_mem, syn_buf + l_div,
913 sizeof(FIXP_DBL) * M_LP_FILTER_ORDER);
914
915 Deemph(syn, synth, l_div,
916 &acelp_mem->de_emph_mem); /* ref soft: mem = synth[-1] */
917
918 scaleValues(synth, l_div, -ACELP_OUTSCALE);
919 acelp_mem->deemph_mem_wsyn = acelp_mem->de_emph_mem;
920
921 C_ALLOC_SCRATCH_END(tmp_buf, FIXP_DBL, L_SUBFR);
922 C_ALLOC_SCRATCH_END(syn_buf, FIXP_DBL, M_LP_FILTER_ORDER + L_DIV);
923 C_ALLOC_SCRATCH_END(exc_buf, FIXP_DBL, PIT_MAX_MAX + L_INTERPOL + L_DIV + 1);
924 return;
925 }
926
CLpd_AcelpReset(CAcelpStaticMem * acelp)927 void CLpd_AcelpReset(CAcelpStaticMem *acelp) {
928 acelp->gc_threshold = (FIXP_DBL)0;
929
930 acelp->past_gpit = (FIXP_SGL)0;
931 acelp->past_gcode = (FIXP_DBL)0;
932 acelp->old_T0 = 64;
933 acelp->old_T0_frac = 0;
934 acelp->deemph_mem_wsyn = (FIXP_DBL)0;
935 acelp->wsyn_rms = (FIXP_DBL)0;
936 acelp->seed_ace = 0;
937 }
938
939 /* TCX time domain concealment */
940 /* Compare to figure 13a on page 54 in 3GPP TS 26.290 */
CLpd_TcxTDConceal(CAcelpStaticMem * acelp_mem,SHORT * pitch,const FIXP_LPC lsp_old[M_LP_FILTER_ORDER],const FIXP_LPC lsp_new[M_LP_FILTER_ORDER],const FIXP_SGL stab_fac,INT nLostSf,FIXP_DBL synth[],INT coreCoderFrameLength,UCHAR last_tcx_noise_factor)941 void CLpd_TcxTDConceal(CAcelpStaticMem *acelp_mem, SHORT *pitch,
942 const FIXP_LPC lsp_old[M_LP_FILTER_ORDER],
943 const FIXP_LPC lsp_new[M_LP_FILTER_ORDER],
944 const FIXP_SGL stab_fac, INT nLostSf, FIXP_DBL synth[],
945 INT coreCoderFrameLength, UCHAR last_tcx_noise_factor) {
946 /* repeat past excitation with pitch from previous decoded TCX frame */
947 C_ALLOC_SCRATCH_START(
948 exc_buf, FIXP_DBL,
949 PIT_MAX_MAX + L_INTERPOL + L_DIV); /* 411 + 17 + 256 + 1 = */
950 C_ALLOC_SCRATCH_START(syn_buf, FIXP_DBL,
951 M_LP_FILTER_ORDER + L_DIV); /* 256 + 16 = */
952 /* += */
953 FIXP_DBL ns_buf[L_DIV + 1];
954 FIXP_DBL *syn = syn_buf + M_LP_FILTER_ORDER;
955 FIXP_DBL *exc = exc_buf + PIT_MAX_MAX + L_INTERPOL;
956 FIXP_DBL *ns = ns_buf + 1;
957 FIXP_DBL tmp, fact_exc;
958 INT T = fMin(*pitch, (SHORT)PIT_MAX_MAX);
959 int i, i_subfr, subfr_nr;
960 int lDiv = coreCoderFrameLength / NB_DIV;
961
962 FDKmemcpy(syn_buf, acelp_mem->old_syn_mem,
963 M_LP_FILTER_ORDER * sizeof(FIXP_DBL));
964 FDKmemcpy(exc_buf, acelp_mem->old_exc_mem,
965 (PIT_MAX_MAX + L_INTERPOL) * sizeof(FIXP_DBL));
966
967 /* if we lost all packets (i.e. 1 packet of TCX-20 ms, 2 packets of
968 the TCX-40 ms or 4 packets of the TCX-80ms), we lost the whole
969 coded frame extrapolation strategy: repeat lost excitation and
970 use extrapolated LSFs */
971
972 /* AMR-WB+ like TCX TD concealment */
973
974 /* number of lost frame cmpt */
975 if (nLostSf < 2) {
976 fact_exc = FL2FXCONST_DBL(0.8f);
977 } else {
978 fact_exc = FL2FXCONST_DBL(0.4f);
979 }
980
981 /* repeat past excitation */
982 for (i = 0; i < lDiv; i++) {
983 exc[i] = fMult(fact_exc, exc[i - T]);
984 }
985
986 tmp = fMult(fact_exc, acelp_mem->wsyn_rms);
987 acelp_mem->wsyn_rms = tmp;
988
989 /* init deemph_mem_wsyn */
990 acelp_mem->deemph_mem_wsyn = exc[-1];
991
992 ns[-1] = acelp_mem->deemph_mem_wsyn;
993
994 for (i_subfr = 0, subfr_nr = 0; i_subfr < lDiv;
995 i_subfr += L_SUBFR, subfr_nr++) {
996 FIXP_DBL tRes[L_SUBFR];
997 FIXP_LPC A[M_LP_FILTER_ORDER];
998 INT A_exp;
999
1000 /* interpolate LPC coefficients */
1001 int_lpc_acelp(lsp_old, lsp_new, subfr_nr, lDiv / L_SUBFR, A, &A_exp);
1002
1003 Syn_filt(A, /* (i) : a[m] prediction coefficients */
1004 A_exp, L_SUBFR, /* (i) : length */
1005 &exc[i_subfr], /* (i) : input signal */
1006 &syn[i_subfr] /* (i/o) : filter states / output signal */
1007 );
1008
1009 E_LPC_a_weight(
1010 A, A,
1011 M_LP_FILTER_ORDER); /* overwrite A as it is not needed any longer */
1012
1013 E_UTIL_residu(A, A_exp, &syn[i_subfr], tRes, L_SUBFR);
1014
1015 Deemph(tRes, &ns[i_subfr], L_SUBFR, &acelp_mem->deemph_mem_wsyn);
1016
1017 /* Amplitude limiter (saturate at wsyn_rms) */
1018 for (i = i_subfr; i < i_subfr + L_SUBFR; i++) {
1019 if (ns[i] > tmp) {
1020 ns[i] = tmp;
1021 } else {
1022 if (ns[i] < -tmp) {
1023 ns[i] = -tmp;
1024 }
1025 }
1026 }
1027
1028 E_UTIL_preemph(&ns[i_subfr], tRes, L_SUBFR);
1029
1030 Syn_filt(A, /* (i) : a[m] prediction coefficients */
1031 A_exp, L_SUBFR, /* (i) : length */
1032 tRes, /* (i) : input signal */
1033 &syn[i_subfr] /* (i/o) : filter states / output signal */
1034 );
1035
1036 FDKmemmove(&synth[i_subfr], &syn[i_subfr], L_SUBFR * sizeof(FIXP_DBL));
1037 }
1038
1039 /* save old excitation and old synthesis memory for next ACELP frame */
1040 FDKmemcpy(acelp_mem->old_exc_mem, exc + lDiv - (PIT_MAX_MAX + L_INTERPOL),
1041 sizeof(FIXP_DBL) * (PIT_MAX_MAX + L_INTERPOL));
1042 FDKmemcpy(acelp_mem->old_syn_mem, syn_buf + lDiv,
1043 sizeof(FIXP_DBL) * M_LP_FILTER_ORDER);
1044 acelp_mem->de_emph_mem = acelp_mem->deemph_mem_wsyn;
1045
1046 C_ALLOC_SCRATCH_END(syn_buf, FIXP_DBL, M_LP_FILTER_ORDER + L_DIV);
1047 C_ALLOC_SCRATCH_END(exc_buf, FIXP_DBL, PIT_MAX_MAX + L_INTERPOL + L_DIV);
1048 }
1049
Acelp_PreProcessing(FIXP_DBL * synth_buf,FIXP_DBL * old_synth,INT * pitch,INT * old_T_pf,FIXP_DBL * pit_gain,FIXP_DBL * old_gain_pf,INT samplingRate,INT * i_offset,INT coreCoderFrameLength,INT synSfd,INT nbSubfrSuperfr)1050 void Acelp_PreProcessing(FIXP_DBL *synth_buf, FIXP_DBL *old_synth, INT *pitch,
1051 INT *old_T_pf, FIXP_DBL *pit_gain,
1052 FIXP_DBL *old_gain_pf, INT samplingRate, INT *i_offset,
1053 INT coreCoderFrameLength, INT synSfd,
1054 INT nbSubfrSuperfr) {
1055 int n;
1056
1057 /* init beginning of synth_buf with old synthesis from previous frame */
1058 FDKmemcpy(synth_buf, old_synth, sizeof(FIXP_DBL) * (PIT_MAX_MAX - BPF_DELAY));
1059
1060 /* calculate pitch lag offset for ACELP decoder */
1061 *i_offset =
1062 (samplingRate * PIT_MIN_12k8 + (FSCALE_DENOM / 2)) / FSCALE_DENOM -
1063 PIT_MIN_12k8;
1064
1065 /* for bass postfilter */
1066 for (n = 0; n < synSfd; n++) {
1067 pitch[n] = old_T_pf[n];
1068 pit_gain[n] = old_gain_pf[n];
1069 }
1070 for (n = 0; n < nbSubfrSuperfr; n++) {
1071 pitch[n + synSfd] = L_SUBFR;
1072 pit_gain[n + synSfd] = (FIXP_DBL)0;
1073 }
1074 }
1075
Acelp_PostProcessing(FIXP_DBL * synth_buf,FIXP_DBL * old_synth,INT * pitch,INT * old_T_pf,INT coreCoderFrameLength,INT synSfd,INT nbSubfrSuperfr)1076 void Acelp_PostProcessing(FIXP_DBL *synth_buf, FIXP_DBL *old_synth, INT *pitch,
1077 INT *old_T_pf, INT coreCoderFrameLength, INT synSfd,
1078 INT nbSubfrSuperfr) {
1079 int n;
1080
1081 /* store last part of synth_buf (which is not handled by the IMDCT overlap)
1082 * for next frame */
1083 FDKmemcpy(old_synth, synth_buf + coreCoderFrameLength,
1084 sizeof(FIXP_DBL) * (PIT_MAX_MAX - BPF_DELAY));
1085
1086 /* for bass postfilter */
1087 for (n = 0; n < synSfd; n++) {
1088 old_T_pf[n] = pitch[nbSubfrSuperfr + n];
1089 }
1090 }
1091
1092 #define L_FAC_ZIR (LFAC)
1093
CLpd_Acelp_Zir(const FIXP_LPC A[],const INT A_exp,CAcelpStaticMem * acelp_mem,const INT length,FIXP_DBL zir[],int doDeemph)1094 void CLpd_Acelp_Zir(const FIXP_LPC A[], const INT A_exp,
1095 CAcelpStaticMem *acelp_mem, const INT length,
1096 FIXP_DBL zir[], int doDeemph) {
1097 C_ALLOC_SCRATCH_START(tmp_buf, FIXP_DBL, L_FAC_ZIR + M_LP_FILTER_ORDER);
1098 FDK_ASSERT(length <= L_FAC_ZIR);
1099
1100 FDKmemcpy(tmp_buf, acelp_mem->old_syn_mem,
1101 M_LP_FILTER_ORDER * sizeof(FIXP_DBL));
1102 FDKmemset(tmp_buf + M_LP_FILTER_ORDER, 0, L_FAC_ZIR * sizeof(FIXP_DBL));
1103
1104 Syn_filt(A, A_exp, length, &tmp_buf[M_LP_FILTER_ORDER],
1105 &tmp_buf[M_LP_FILTER_ORDER]);
1106 if (!doDeemph) {
1107 /* if last lpd mode was TD concealment, then bypass deemph */
1108 FDKmemcpy(zir, tmp_buf, length * sizeof(*zir));
1109 } else {
1110 Deemph(&tmp_buf[M_LP_FILTER_ORDER], &zir[0], length,
1111 &acelp_mem->de_emph_mem);
1112 scaleValues(zir, length, -ACELP_OUTSCALE);
1113 }
1114 C_ALLOC_SCRATCH_END(tmp_buf, FIXP_DBL, L_FAC_ZIR + M_LP_FILTER_ORDER);
1115 }
1116
CLpd_AcelpPrepareInternalMem(const FIXP_DBL * synth,UCHAR last_lpd_mode,UCHAR last_last_lpd_mode,const FIXP_LPC * A_new,const INT A_new_exp,const FIXP_LPC * A_old,const INT A_old_exp,CAcelpStaticMem * acelp_mem,INT coreCoderFrameLength,INT clearOldExc,UCHAR lpd_mode)1117 void CLpd_AcelpPrepareInternalMem(const FIXP_DBL *synth, UCHAR last_lpd_mode,
1118 UCHAR last_last_lpd_mode,
1119 const FIXP_LPC *A_new, const INT A_new_exp,
1120 const FIXP_LPC *A_old, const INT A_old_exp,
1121 CAcelpStaticMem *acelp_mem,
1122 INT coreCoderFrameLength, INT clearOldExc,
1123 UCHAR lpd_mode) {
1124 int l_div =
1125 coreCoderFrameLength / NB_DIV; /* length of one ACELP/TCX20 frame */
1126 int l_div_partial;
1127 FIXP_DBL *syn, *old_exc_mem;
1128
1129 C_ALLOC_SCRATCH_START(synth_buf, FIXP_DBL,
1130 PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER);
1131 syn = &synth_buf[M_LP_FILTER_ORDER];
1132
1133 l_div_partial = PIT_MAX_MAX + L_INTERPOL - l_div;
1134 old_exc_mem = acelp_mem->old_exc_mem;
1135
1136 if (lpd_mode == 4) {
1137 /* Bypass Domain conversion. TCXTD Concealment does no deemphasis in the
1138 * end. */
1139 FDKmemcpy(
1140 synth_buf, &synth[-(PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER)],
1141 (PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER) * sizeof(FIXP_DBL));
1142 /* Set deemphasis memory state for TD concealment */
1143 acelp_mem->deemph_mem_wsyn = scaleValueSaturate(synth[-1], ACELP_OUTSCALE);
1144 } else {
1145 /* convert past [PIT_MAX_MAX+L_INTERPOL+M_LP_FILTER_ORDER] synthesis to
1146 * preemph domain */
1147 E_UTIL_preemph(&synth[-(PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER)],
1148 synth_buf, PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER);
1149 scaleValuesSaturate(synth_buf, PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER,
1150 ACELP_OUTSCALE);
1151 }
1152
1153 /* Set deemphasis memory state */
1154 acelp_mem->de_emph_mem = scaleValueSaturate(synth[-1], ACELP_OUTSCALE);
1155
1156 /* update acelp synth filter memory */
1157 FDKmemcpy(acelp_mem->old_syn_mem,
1158 &syn[PIT_MAX_MAX + L_INTERPOL - M_LP_FILTER_ORDER],
1159 M_LP_FILTER_ORDER * sizeof(FIXP_DBL));
1160
1161 if (clearOldExc) {
1162 FDKmemclear(old_exc_mem, (PIT_MAX_MAX + L_INTERPOL) * sizeof(FIXP_DBL));
1163 C_ALLOC_SCRATCH_END(synth_buf, FIXP_DBL,
1164 PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER);
1165 return;
1166 }
1167
1168 /* update past [PIT_MAX_MAX+L_INTERPOL] samples of exc memory */
1169 if (last_lpd_mode == 1) { /* last frame was TCX20 */
1170 if (last_last_lpd_mode == 0) { /* ACELP -> TCX20 -> ACELP transition */
1171 /* Delay valid part of excitation buffer (from previous ACELP frame) by
1172 * l_div samples */
1173 FDKmemmove(old_exc_mem, old_exc_mem + l_div,
1174 sizeof(FIXP_DBL) * l_div_partial);
1175 } else if (last_last_lpd_mode > 0) { /* TCX -> TCX20 -> ACELP transition */
1176 E_UTIL_residu(A_old, A_old_exp, syn, old_exc_mem, l_div_partial);
1177 }
1178 E_UTIL_residu(A_new, A_new_exp, syn + l_div_partial,
1179 old_exc_mem + l_div_partial, l_div);
1180 } else { /* prev frame was FD, TCX40 or TCX80 */
1181 int exc_A_new_length = (coreCoderFrameLength / 2 > PIT_MAX_MAX + L_INTERPOL)
1182 ? PIT_MAX_MAX + L_INTERPOL
1183 : coreCoderFrameLength / 2;
1184 int exc_A_old_length = PIT_MAX_MAX + L_INTERPOL - exc_A_new_length;
1185 E_UTIL_residu(A_old, A_old_exp, syn, old_exc_mem, exc_A_old_length);
1186 E_UTIL_residu(A_new, A_new_exp, &syn[exc_A_old_length],
1187 &old_exc_mem[exc_A_old_length], exc_A_new_length);
1188 }
1189 C_ALLOC_SCRATCH_END(synth_buf, FIXP_DBL,
1190 PIT_MAX_MAX + L_INTERPOL + M_LP_FILTER_ORDER);
1191
1192 return;
1193 }
1194
CLpd_ACELP_GetFreeExcMem(CAcelpStaticMem * acelp_mem,INT length)1195 FIXP_DBL *CLpd_ACELP_GetFreeExcMem(CAcelpStaticMem *acelp_mem, INT length) {
1196 FDK_ASSERT(length <= PIT_MAX_MAX + L_INTERPOL);
1197 return acelp_mem->old_exc_mem;
1198 }
1199
CLpd_AcelpRead(HANDLE_FDK_BITSTREAM hBs,CAcelpChannelData * acelp,INT acelp_core_mode,INT coreCoderFrameLength,INT i_offset)1200 INT CLpd_AcelpRead(HANDLE_FDK_BITSTREAM hBs, CAcelpChannelData *acelp,
1201 INT acelp_core_mode, INT coreCoderFrameLength,
1202 INT i_offset) {
1203 int nb_subfr = coreCoderFrameLength / L_DIV;
1204 const UCHAR *num_acb_index_bits =
1205 (nb_subfr == 4) ? num_acb_idx_bits_table[0] : num_acb_idx_bits_table[1];
1206 int nbits;
1207 int error = 0;
1208
1209 const int PIT_MIN = PIT_MIN_12k8 + i_offset;
1210 const int PIT_FR2 = PIT_FR2_12k8 - i_offset;
1211 const int PIT_FR1 = PIT_FR1_12k8;
1212 const int PIT_MAX = PIT_MAX_12k8 + (6 * i_offset);
1213 int T0, T0_frac, T0_min = 0, T0_max;
1214
1215 if (PIT_MAX > PIT_MAX_MAX) {
1216 error = AAC_DEC_DECODE_FRAME_ERROR;
1217 goto bail;
1218 }
1219
1220 acelp->acelp_core_mode = acelp_core_mode;
1221
1222 nbits = MapCoreMode2NBits(acelp_core_mode);
1223
1224 /* decode mean energy with 2 bits : 18, 30, 42 or 54 dB */
1225 acelp->mean_energy = FDKreadBits(hBs, 2);
1226
1227 for (int sfr = 0; sfr < nb_subfr; sfr++) {
1228 /* read ACB index and store T0 and T0_frac for each ACELP subframe. */
1229 error = DecodePitchLag(hBs, num_acb_index_bits[sfr], PIT_MIN, PIT_FR2,
1230 PIT_FR1, PIT_MAX, &T0, &T0_frac, &T0_min, &T0_max);
1231 if (error) {
1232 goto bail;
1233 }
1234 acelp->T0[sfr] = (USHORT)T0;
1235 acelp->T0_frac[sfr] = (UCHAR)T0_frac;
1236 acelp->ltp_filtering_flag[sfr] = FDKreadBits(hBs, 1);
1237 switch (nbits) {
1238 case 12: /* 12 bits AMR-WB codebook is used */
1239 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 1);
1240 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 5);
1241 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 1);
1242 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 5);
1243 break;
1244 case 16: /* 16 bits AMR-WB codebook is used */
1245 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 1);
1246 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 5);
1247 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 5);
1248 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 5);
1249 break;
1250 case 20: /* 20 bits AMR-WB codebook is used */
1251 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 5);
1252 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 5);
1253 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 5);
1254 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 5);
1255 break;
1256 case 28: /* 28 bits AMR-WB codebook is used */
1257 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 9);
1258 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 9);
1259 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 5);
1260 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 5);
1261 break;
1262 case 36: /* 36 bits AMR-WB codebook is used */
1263 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 9);
1264 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 9);
1265 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 9);
1266 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 9);
1267 break;
1268 case 44: /* 44 bits AMR-WB codebook is used */
1269 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 13);
1270 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 13);
1271 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 9);
1272 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 9);
1273 break;
1274 case 52: /* 52 bits AMR-WB codebook is used */
1275 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 13);
1276 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 13);
1277 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 13);
1278 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 13);
1279 break;
1280 case 64: /* 64 bits AMR-WB codebook is used */
1281 acelp->icb_index[sfr][0] = FDKreadBits(hBs, 2);
1282 acelp->icb_index[sfr][1] = FDKreadBits(hBs, 2);
1283 acelp->icb_index[sfr][2] = FDKreadBits(hBs, 2);
1284 acelp->icb_index[sfr][3] = FDKreadBits(hBs, 2);
1285 acelp->icb_index[sfr][4] = FDKreadBits(hBs, 14);
1286 acelp->icb_index[sfr][5] = FDKreadBits(hBs, 14);
1287 acelp->icb_index[sfr][6] = FDKreadBits(hBs, 14);
1288 acelp->icb_index[sfr][7] = FDKreadBits(hBs, 14);
1289 break;
1290 default:
1291 FDK_ASSERT(0);
1292 break;
1293 }
1294 acelp->gains[sfr] = FDKreadBits(hBs, 7);
1295 }
1296
1297 bail:
1298 return error;
1299 }
1300