1 
2 /* -----------------------------------------------------------------------------------------------------------
3 Software License for The Fraunhofer FDK AAC Codec Library for Android
4 
5 � Copyright  1995 - 2015 Fraunhofer-Gesellschaft zur F�rderung der angewandten Forschung e.V.
6   All rights reserved.
7 
8  1.    INTRODUCTION
9 The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements
10 the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio.
11 This FDK AAC Codec software is intended to be used on a wide variety of Android devices.
12 
13 AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual
14 audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by
15 independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part
16 of the MPEG specifications.
17 
18 Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer)
19 may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
20 individually for the purpose of encoding or decoding bit streams in products that are compliant with
21 the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
22 these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
23 software may already be covered under those patent licenses when it is used for those licensed purposes only.
24 
25 Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality,
26 are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional
27 applications information and documentation.
28 
29 2.    COPYRIGHT LICENSE
30 
31 Redistribution and use in source and binary forms, with or without modification, are permitted without
32 payment of copyright license fees provided that you satisfy the following conditions:
33 
34 You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
35 your modifications thereto in source code form.
36 
37 You must retain the complete text of this software license in the documentation and/or other materials
38 provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form.
39 You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
40 modifications thereto to recipients of copies in binary form.
41 
42 The name of Fraunhofer may not be used to endorse or promote products derived from this library without
43 prior written permission.
44 
45 You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec
46 software or your modifications thereto.
47 
48 Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software
49 and the date of any change. For modified versions of the FDK AAC Codec, the term
50 "Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term
51 "Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."
52 
53 3.    NO PATENT LICENSE
54 
55 NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer,
56 ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
57 respect to this software.
58 
59 You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
60 by appropriate patent licenses.
61 
62 4.    DISCLAIMER
63 
64 This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
65 "AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
66 of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
67 CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages,
68 including but not limited to procurement of substitute goods or services; loss of use, data, or profits,
69 or business interruption, however caused and on any theory of liability, whether in contract, strict
70 liability, or tort (including negligence), arising in any way out of the use of this software, even if
71 advised of the possibility of such damage.
72 
73 5.    CONTACT INFORMATION
74 
75 Fraunhofer Institute for Integrated Circuits IIS
76 Attention: Audio and Multimedia Departments - FDK AAC LL
77 Am Wolfsmantel 33
78 91058 Erlangen, Germany
79 
80 www.iis.fraunhofer.de/amm
81 amm-info@iis.fraunhofer.de
82 ----------------------------------------------------------------------------------------------------------- */
83 
84 /***************************  Fraunhofer IIS FDK Tools  ***********************
85 
86    Author(s): Andreas Ehret, Tobias Chalupka
87    Description: SBR encoder top level processing.
88 
89 ******************************************************************************/
90 
91 #include "sbr_encoder.h"
92 
93 #include "sbr_ram.h"
94 #include "sbr_rom.h"
95 #include "sbrenc_freq_sca.h"
96 #include "env_bit.h"
97 #include "cmondata.h"
98 #include "sbr_misc.h"
99 #include "sbr.h"
100 #include "qmf.h"
101 
102 #include "ps_main.h"
103 
104 #define SBRENCODER_LIB_VL0 3
105 #define SBRENCODER_LIB_VL1 3
106 #define SBRENCODER_LIB_VL2 12
107 
108 
109 
110 /***************************************************************************/
111 /*
112  * SBR Delay balancing definitions.
113  */
114 
115 /*
116       input buffer (1ch)
117 
118       |------------ 1537   -------------|-----|---------- 2048 -------------|
119            (core2sbr delay     )          ds     (read, core and ds area)
120 */
121 
122 #define SFB(dwnsmp)        (32 << (dwnsmp-1))     /* SBR Frequency bands: 64 for dual-rate, 32 for single-rate */
123 #define STS(fl)            (((fl)==1024)?32:30)   /* SBR Time Slots: 32 for core frame length 1024, 30 for core frame length 960 */
124 
125 #define DELAY_QMF_ANA(dwnsmp) ((320<<((dwnsmp)-1)) - (32<<((dwnsmp)-1))) /* Full bandwidth */
126 #define DELAY_HYB_ANA         (10*64)       /* + 0.5 */              /*  */
127 #define DELAY_HYB_SYN         (6*64 - 32)                            /*  */
128 #define DELAY_QMF_POSTPROC(dwnsmp) (32*(dwnsmp))                     /* QMF postprocessing delay */
129 #define DELAY_DEC_QMF(dwnsmp) (6 * SFB(dwnsmp) )                     /* Decoder QMF overlap */
130 #define DELAY_QMF_SYN         (2)                                    /* NO_POLY/2=2.5, rounded down to 2 */
131 #define DELAY_QMF_DS          (32)                                   /* QMF synthesis for downsampled time signal */
132 
133 /* Delay in QMF paths */
134 #define DELAY_SBR(fl,dwnsmp)     (DELAY_QMF_ANA(dwnsmp) + (SFB(dwnsmp)*STS(fl) - 1) + DELAY_QMF_SYN)
135 #define DELAY_PS(fl,dwnsmp)      (DELAY_QMF_ANA(dwnsmp) + DELAY_HYB_ANA + DELAY_DEC_QMF(dwnsmp) + (SFB(dwnsmp)*STS(fl)-1) + DELAY_HYB_SYN + DELAY_QMF_SYN)
136 #define DELAY_ELDSBR(fl,dwnsmp)  ( ( ((fl)/2)*(dwnsmp) ) - 1 + DELAY_QMF_POSTPROC(dwnsmp) )
137 
138 /* Delay differences for SBR and SBR+PS */
139 #define MAX_DS_FILTER_DELAY (5)                                           /* the additional max downsampler filter delay (source fs) */
140 #define DELAY_AAC2SBR(fl,dwnsmp) ((DELAY_QMF_ANA(dwnsmp) + DELAY_DEC_QMF(dwnsmp) + DELAY_QMF_SYN) - DELAY_SBR((fl),(dwnsmp)))
141 #define DELAY_ELD2SBR(fl,dwnsmp) ((DELAY_QMF_POSTPROC(dwnsmp)) - DELAY_ELDSBR(fl,dwnsmp))
142 #define DELAY_AAC2PS(fl,dwnsmp) ((DELAY_QMF_ANA(dwnsmp) + DELAY_QMF_DS + /*(DELAY_AAC(fl)*2) + */ DELAY_QMF_ANA(dwnsmp) + DELAY_DEC_QMF(dwnsmp) + DELAY_HYB_SYN + DELAY_QMF_SYN) - DELAY_PS(fl,dwnsmp)) /* 2048 - 463*2 */
143 
144 /* Assumption: The sample delay resulting of of DELAY_AAC2PS is always smaller than the sample delay implied by DELAY_AAC2SBR */
145 #define MAX_SAMPLE_DELAY       (DELAY_AAC2SBR(1024,2) + MAX_DS_FILTER_DELAY) /* maximum delay: frame length of 1024 and dual-rate sbr */
146 
147 /***************************************************************************/
148 
149 
150 
151 #define INVALID_TABLE_IDX -1
152 
153 /***************************************************************************/
154 /*!
155 
156   \brief  Selects the SBR tuning settings to use dependent on number of
157           channels, bitrate, sample rate and core coder
158 
159   \return Index to the appropriate table
160 
161 ****************************************************************************/
162 #define DISTANCE_CEIL_VALUE 5000000
163 static INT
getSbrTuningTableIndex(UINT bitrate,UINT numChannels,UINT sampleRate,AUDIO_OBJECT_TYPE core,UINT * pBitRateClosest)164 getSbrTuningTableIndex(UINT bitrate,    /*! the total bitrate in bits/sec */
165                        UINT numChannels,/*! the number of channels for the core coder */
166                        UINT sampleRate,  /*! the sampling rate of the core coder */
167                        AUDIO_OBJECT_TYPE core,
168                        UINT *pBitRateClosest
169                        )
170 {
171   int i, bitRateClosestLowerIndex=-1, bitRateClosestUpperIndex=-1, found = 0;
172   UINT bitRateClosestUpper = 0, bitRateClosestLower=DISTANCE_CEIL_VALUE;
173 
174   #define isForThisCore(i) \
175     ( ( sbrTuningTable[i].coreCoder == CODEC_AACLD && core == AOT_ER_AAC_ELD ) || \
176       ( sbrTuningTable[i].coreCoder == CODEC_AAC   && core != AOT_ER_AAC_ELD ) )
177 
178   for (i=0; i < sbrTuningTableSize ; i++) {
179     if ( isForThisCore(i) ) /* tuning table is for this core codec */
180     {
181       if ( numChannels == sbrTuningTable [i].numChannels
182         && sampleRate == sbrTuningTable [i].sampleRate )
183       {
184         found = 1;
185         if ((bitrate >= sbrTuningTable [i].bitrateFrom) &&
186             (bitrate < sbrTuningTable [i].bitrateTo)) {
187               bitRateClosestLower = bitrate;
188               bitRateClosestUpper = bitrate;
189               //FDKprintf("entry %d\n", i);
190           return i ;
191         } else {
192           if ( sbrTuningTable [i].bitrateFrom > bitrate ) {
193             if (sbrTuningTable [i].bitrateFrom < bitRateClosestLower) {
194               bitRateClosestLower = sbrTuningTable [i].bitrateFrom;
195               bitRateClosestLowerIndex = i;
196             }
197           }
198           if ( sbrTuningTable [i].bitrateTo <= bitrate ) {
199             if (sbrTuningTable [i].bitrateTo > bitRateClosestUpper) {
200               bitRateClosestUpper = sbrTuningTable [i].bitrateTo-1;
201               bitRateClosestUpperIndex = i;
202             }
203           }
204         }
205       }
206     }
207   }
208 
209   if (pBitRateClosest != NULL)
210   {
211     /* If there was at least one matching tuning entry found then pick the least distance bit rate */
212     if (found)
213     {
214       int distanceUpper=DISTANCE_CEIL_VALUE, distanceLower=DISTANCE_CEIL_VALUE;
215       if (bitRateClosestLowerIndex >= 0) {
216         distanceLower = sbrTuningTable [bitRateClosestLowerIndex].bitrateFrom - bitrate;
217       }
218       if (bitRateClosestUpperIndex >= 0) {
219         distanceUpper = bitrate - sbrTuningTable [bitRateClosestUpperIndex].bitrateTo;
220       }
221       if ( distanceUpper < distanceLower )
222       {
223         *pBitRateClosest = bitRateClosestUpper;
224       } else {
225         *pBitRateClosest = bitRateClosestLower;
226       }
227     } else {
228       *pBitRateClosest = 0;
229     }
230   }
231 
232   return INVALID_TABLE_IDX;
233 }
234 
235 /***************************************************************************/
236 /*!
237 
238   \brief  Selects the PS tuning settings to use dependent on bitrate
239   and core coder
240 
241   \return Index to the appropriate table
242 
243 ****************************************************************************/
244 static INT
getPsTuningTableIndex(UINT bitrate,UINT * pBitRateClosest)245 getPsTuningTableIndex(UINT bitrate, UINT *pBitRateClosest){
246 
247   INT i, paramSets = sizeof (psTuningTable) / sizeof (psTuningTable [0]);
248   int bitRateClosestLowerIndex=-1, bitRateClosestUpperIndex=-1;
249   UINT bitRateClosestUpper = 0, bitRateClosestLower=DISTANCE_CEIL_VALUE;
250 
251   for (i = 0 ; i < paramSets ; i++)  {
252     if ((bitrate >= psTuningTable [i].bitrateFrom) &&
253         (bitrate < psTuningTable [i].bitrateTo)) {
254       return i ;
255     } else {
256       if ( psTuningTable [i].bitrateFrom > bitrate ) {
257         if (psTuningTable [i].bitrateFrom < bitRateClosestLower) {
258           bitRateClosestLower = psTuningTable [i].bitrateFrom;
259           bitRateClosestLowerIndex = i;
260         }
261       }
262       if ( psTuningTable [i].bitrateTo <= bitrate ) {
263         if (psTuningTable [i].bitrateTo > bitRateClosestUpper) {
264           bitRateClosestUpper = psTuningTable [i].bitrateTo-1;
265           bitRateClosestUpperIndex = i;
266         }
267       }
268     }
269   }
270 
271   if (pBitRateClosest != NULL)
272   {
273     int distanceUpper=DISTANCE_CEIL_VALUE, distanceLower=DISTANCE_CEIL_VALUE;
274     if (bitRateClosestLowerIndex >= 0) {
275       distanceLower = sbrTuningTable [bitRateClosestLowerIndex].bitrateFrom - bitrate;
276     }
277     if (bitRateClosestUpperIndex >= 0) {
278       distanceUpper = bitrate - sbrTuningTable [bitRateClosestUpperIndex].bitrateTo;
279     }
280     if ( distanceUpper < distanceLower )
281     {
282       *pBitRateClosest = bitRateClosestUpper;
283     } else {
284       *pBitRateClosest = bitRateClosestLower;
285     }
286   }
287 
288   return INVALID_TABLE_IDX;
289 }
290 
291 /***************************************************************************/
292 /*!
293 
294   \brief  In case of downsampled SBR we may need to lower the stop freq
295           of a tuning setting to fit into the lower half of the
296           spectrum ( which is sampleRate/4 )
297 
298   \return the adapted stop frequency index (-1 -> error)
299 
300   \ingroup SbrEncCfg
301 
302 ****************************************************************************/
303 static INT
FDKsbrEnc_GetDownsampledStopFreq(const INT sampleRateCore,const INT startFreq,INT stopFreq,const INT downSampleFactor)304 FDKsbrEnc_GetDownsampledStopFreq (
305         const INT sampleRateCore,
306         const INT startFreq,
307               INT stopFreq,
308         const INT downSampleFactor
309         )
310 {
311   INT maxStopFreqRaw = sampleRateCore / 2;
312   INT startBand, stopBand;
313   HANDLE_ERROR_INFO err;
314 
315   while (stopFreq > 0 && FDKsbrEnc_getSbrStopFreqRAW(stopFreq, sampleRateCore) > maxStopFreqRaw) {
316     stopFreq--;
317   }
318 
319   if (FDKsbrEnc_getSbrStopFreqRAW( stopFreq, sampleRateCore) > maxStopFreqRaw)
320     return -1;
321 
322   err = FDKsbrEnc_FindStartAndStopBand (
323                 sampleRateCore<<(downSampleFactor-1),
324                 sampleRateCore,
325                 32<<(downSampleFactor-1),
326                 startFreq,
327                 stopFreq,
328                &startBand,
329                &stopBand
330                 );
331   if (err)
332     return -1;
333 
334   return stopFreq;
335 }
336 
337 
338 /***************************************************************************/
339 /*!
340 
341   \brief  tells us, if for the given coreCoder, bitrate, number of channels
342           and input sampling rate an SBR setting is available. If yes, it
343           tells us also the core sampling rate we would need to run with
344 
345   \return a flag indicating success: yes (1) or no (0)
346 
347 ****************************************************************************/
348 static UINT
FDKsbrEnc_IsSbrSettingAvail(UINT bitrate,UINT vbrMode,UINT numOutputChannels,UINT sampleRateInput,UINT sampleRateCore,AUDIO_OBJECT_TYPE core)349 FDKsbrEnc_IsSbrSettingAvail (
350         UINT bitrate,           /*! the total bitrate in bits/sec */
351         UINT vbrMode,           /*! the vbr paramter, 0 means constant bitrate */
352         UINT numOutputChannels, /*! the number of channels for the core coder */
353         UINT sampleRateInput,   /*! the input sample rate [in Hz] */
354         UINT sampleRateCore,    /*! the core's sampling rate */
355         AUDIO_OBJECT_TYPE core
356         )
357 {
358   INT idx = INVALID_TABLE_IDX;
359 
360   if (sampleRateInput < 16000)
361     return 0;
362 
363   if (bitrate==0) {
364     /* map vbr quality to bitrate */
365     if (vbrMode < 30)
366       bitrate = 24000;
367     else if (vbrMode < 40)
368       bitrate = 28000;
369     else if (vbrMode < 60)
370       bitrate = 32000;
371     else if (vbrMode < 75)
372       bitrate = 40000;
373     else
374       bitrate = 48000;
375     bitrate *= numOutputChannels;
376   }
377 
378   idx = getSbrTuningTableIndex(bitrate, numOutputChannels, sampleRateCore, core, NULL);
379 
380   return (idx == INVALID_TABLE_IDX ? 0 : 1);
381 }
382 
383 
384 /***************************************************************************/
385 /*!
386 
387   \brief  Adjusts the SBR settings according to the chosen core coder
388           settings which are accessible via config->codecSettings
389 
390   \return A flag indicating success: yes (1) or no (0)
391 
392 ****************************************************************************/
393 static UINT
FDKsbrEnc_AdjustSbrSettings(const sbrConfigurationPtr config,UINT bitRate,UINT numChannels,UINT sampleRateCore,UINT sampleRateSbr,UINT transFac,UINT standardBitrate,UINT vbrMode,UINT useSpeechConfig,UINT lcsMode,UINT bParametricStereo,AUDIO_OBJECT_TYPE core)394 FDKsbrEnc_AdjustSbrSettings (const sbrConfigurationPtr config, /*! output, modified */
395                    UINT bitRate,             /*! the total bitrate in bits/sec */
396                    UINT numChannels,         /*! the core coder number of channels */
397                    UINT sampleRateCore,      /*! the core coder sampling rate in Hz */
398                    UINT sampleRateSbr,       /*! the sbr coder sampling rate in Hz */
399                    UINT transFac,            /*! the short block to long block ratio */
400                    UINT standardBitrate,     /*! the standard bitrate per channel in bits/sec */
401                    UINT vbrMode,             /*! the vbr paramter, 0 poor quality .. 100 high quality*/
402                    UINT useSpeechConfig,     /*!< adapt tuning parameters for speech ? */
403                    UINT lcsMode,             /*! the low complexity stereo mode */
404                    UINT bParametricStereo,   /*!< use parametric stereo */
405                    AUDIO_OBJECT_TYPE core)   /* Core audio codec object type */
406 {
407   INT idx = INVALID_TABLE_IDX;
408   /* set the core codec settings */
409   config->codecSettings.bitRate         = bitRate;
410   config->codecSettings.nChannels       = numChannels;
411   config->codecSettings.sampleFreq      = sampleRateCore;
412   config->codecSettings.transFac        = transFac;
413   config->codecSettings.standardBitrate = standardBitrate;
414 
415   if (bitRate < 28000) {
416     config->threshold_AmpRes_FF_m = (FIXP_DBL)MAXVAL_DBL;
417     config->threshold_AmpRes_FF_e = 7;
418   }
419   else if (bitRate >= 28000 && bitRate <= 48000) {
420     /* The float threshold is 75
421        0.524288f is fractional part of RELAXATION, the quotaMatrix and therefore tonality are scaled by this
422        2/3 is because the original implementation divides the tonality values by 3, here it's divided by 2
423        128 compensates the necessary shiftfactor of 7 */
424     config->threshold_AmpRes_FF_m = FL2FXCONST_DBL(75.0f*0.524288f/(2.0f/3.0f)/128.0f);
425     config->threshold_AmpRes_FF_e = 7;
426   }
427   else if (bitRate > 48000) {
428     config->threshold_AmpRes_FF_m = FL2FXCONST_DBL(0);
429     config->threshold_AmpRes_FF_e = 0;
430   }
431 
432   if (bitRate==0) {
433     /* map vbr quality to bitrate */
434     if (vbrMode < 30)
435       bitRate = 24000;
436     else if (vbrMode < 40)
437       bitRate = 28000;
438     else if (vbrMode < 60)
439       bitRate = 32000;
440     else if (vbrMode < 75)
441       bitRate = 40000;
442     else
443       bitRate = 48000;
444     bitRate *= numChannels;
445     /* fix to enable mono vbrMode<40 @ 44.1 of 48kHz */
446     if (numChannels==1) {
447       if (sampleRateSbr==44100 || sampleRateSbr==48000) {
448         if (vbrMode<40) bitRate = 32000;
449       }
450     }
451   }
452 
453   idx = getSbrTuningTableIndex(bitRate,numChannels,sampleRateCore, core, NULL);
454 
455   if (idx != INVALID_TABLE_IDX) {
456     config->startFreq       = sbrTuningTable[idx].startFreq ;
457     config->stopFreq        = sbrTuningTable[idx].stopFreq ;
458     if (useSpeechConfig) {
459       config->startFreq     = sbrTuningTable[idx].startFreqSpeech;
460       config->stopFreq      = sbrTuningTable[idx].stopFreqSpeech;
461     }
462 
463     /* Adapt stop frequency in case of downsampled SBR - only 32 bands then */
464     if (1 == config->downSampleFactor) {
465       INT dsStopFreq = FDKsbrEnc_GetDownsampledStopFreq(
466                                sampleRateCore,
467                                config->startFreq,
468                                config->stopFreq,
469                                config->downSampleFactor
470                                );
471       if (dsStopFreq < 0) {
472         return 0;
473       }
474 
475       config->stopFreq = dsStopFreq;
476     }
477 
478     config->sbr_noise_bands = sbrTuningTable[idx].numNoiseBands ;
479     if (core == AOT_ER_AAC_ELD)
480       config->init_amp_res_FF = SBR_AMP_RES_1_5;
481     config->noiseFloorOffset= sbrTuningTable[idx].noiseFloorOffset;
482 
483     config->ana_max_level   = sbrTuningTable[idx].noiseMaxLevel ;
484     config->stereoMode      = sbrTuningTable[idx].stereoMode ;
485     config->freqScale       = sbrTuningTable[idx].freqScale ;
486 
487     if (numChannels == 1) {
488       /* stereo case */
489       switch (core) {
490         case AOT_AAC_LC:
491           if (bitRate <= (useSpeechConfig?24000U:20000U)) {
492             config->freq_res_fixfix[0] = FREQ_RES_LOW; /* set low frequency resolution for non-split frames */
493             config->freq_res_fixfix[1] = FREQ_RES_LOW; /* set low frequency resolution for split frames */
494           }
495           break;
496         case AOT_ER_AAC_ELD:
497           if (bitRate < 36000)
498             config->freq_res_fixfix[1] = FREQ_RES_LOW; /* set low frequency resolution for split frames */
499           if (bitRate < 26000) {
500             config->freq_res_fixfix[0] = FREQ_RES_LOW; /* set low frequency resolution for non-split frames */
501             config->fResTransIsLow = 1;                /* for transient frames, set low frequency resolution */
502           }
503           break;
504         default:
505           break;
506       }
507     }
508     else {
509       /* stereo case */
510       switch (core) {
511         case AOT_AAC_LC:
512           if (bitRate <= 28000) {
513             config->freq_res_fixfix[0] = FREQ_RES_LOW; /* set low frequency resolution for non-split frames */
514             config->freq_res_fixfix[1] = FREQ_RES_LOW; /* set low frequency resolution for split frames */
515           }
516           break;
517         case AOT_ER_AAC_ELD:
518           if (bitRate < 72000) {
519             config->freq_res_fixfix[1] = FREQ_RES_LOW; /* set low frequency resolution for split frames */
520           }
521           if (bitRate < 52000) {
522             config->freq_res_fixfix[0] = FREQ_RES_LOW; /* set low frequency resolution for non-split frames */
523             config->fResTransIsLow = 1;                /* for transient frames, set low frequency resolution */
524           }
525           break;
526         default:
527           break;
528       }
529       if (bitRate <= 28000) {
530         /*
531           additionally restrict frequency resolution in FIXFIX frames
532           to further reduce SBR payload size */
533         config->freq_res_fixfix[0] = FREQ_RES_LOW;
534         config->freq_res_fixfix[1] = FREQ_RES_LOW;
535       }
536     }
537 
538     /* adjust usage of parametric coding dependent on bitrate and speech config flag */
539     if (useSpeechConfig)
540       config->parametricCoding  = 0;
541 
542     if (core == AOT_ER_AAC_ELD) {
543       if (bitRate < 28000)
544         config->init_amp_res_FF = SBR_AMP_RES_3_0;
545       config->SendHeaderDataTime = -1;
546     }
547 
548     if (numChannels == 1) {
549       if (bitRate < 16000) {
550         config->parametricCoding  = 0;
551       }
552     }
553     else {
554       if (bitRate < 20000) {
555         config->parametricCoding  = 0;
556       }
557     }
558 
559     config->useSpeechConfig = useSpeechConfig;
560 
561     /* PS settings */
562     config->bParametricStereo = bParametricStereo;
563 
564     return 1 ;
565   }
566   else {
567     return 0 ;
568   }
569 }
570 
571 /*****************************************************************************
572 
573  functionname: FDKsbrEnc_InitializeSbrDefaults
574  description:  initializes the SBR confifuration
575  returns:      error status
576  input:        - core codec type,
577                - factor of SBR to core frame length,
578                - core frame length
579  output:       initialized SBR configuration
580 
581 *****************************************************************************/
582 static UINT
FDKsbrEnc_InitializeSbrDefaults(sbrConfigurationPtr config,INT downSampleFactor,UINT codecGranuleLen,const INT isLowDelay)583 FDKsbrEnc_InitializeSbrDefaults (sbrConfigurationPtr config,
584                                  INT                 downSampleFactor,
585                                  UINT                codecGranuleLen
586                                 ,const INT           isLowDelay
587                                  )
588 {
589     if ( (downSampleFactor < 1 || downSampleFactor > 2) ||
590          (codecGranuleLen*downSampleFactor > QMF_CHANNELS*QMF_MAX_TIME_SLOTS) )
591        return(0); /* error */
592 
593     config->SendHeaderDataTime     = 1000;
594     config->useWaveCoding          = 0;
595     config->crcSbr                 = 0;
596     config->dynBwSupported         = 1;
597     if (isLowDelay)
598       config->tran_thr             = 6000;
599     else
600       config->tran_thr             = 13000;
601 
602     config->parametricCoding       = 1;
603 
604     config->sbrFrameSize           = codecGranuleLen * downSampleFactor;
605     config->downSampleFactor       = downSampleFactor;
606 
607     /* sbr default parameters */
608     config->sbr_data_extra         = 0;
609     config->amp_res                = SBR_AMP_RES_3_0 ;
610     config->tran_fc                = 0 ;
611     config->tran_det_mode          = 1 ;
612     config->spread                 = 1 ;
613     config->stat                   = 0 ;
614     config->e                      = 1 ;
615     config->deltaTAcrossFrames     = 1 ;
616     config->dF_edge_1stEnv         = FL2FXCONST_DBL(0.3f) ;
617     config->dF_edge_incr           = FL2FXCONST_DBL(0.3f) ;
618 
619     config->sbr_invf_mode   = INVF_SWITCHED;
620     config->sbr_xpos_mode   = XPOS_LC;
621     config->sbr_xpos_ctrl   = SBR_XPOS_CTRL_DEFAULT;
622     config->sbr_xpos_level  = 0;
623     config->useSaPan        = 0;
624     config->dynBwEnabled    = 0;
625 
626 
627     /* the following parameters are overwritten by the FDKsbrEnc_AdjustSbrSettings() function since
628        they are included in the tuning table */
629     config->stereoMode             = SBR_SWITCH_LRC;
630     config->ana_max_level          = 6;
631     config->noiseFloorOffset       = 0;
632     config->startFreq              = 5; /*  5.9 respectively  6.0 kHz at fs = 44.1/48 kHz */
633     config->stopFreq               = 9; /* 16.2 respectively 16.8 kHz at fs = 44.1/48 kHz */
634     config->freq_res_fixfix[0]     = FREQ_RES_HIGH;  /* non-split case */
635     config->freq_res_fixfix[1]     = FREQ_RES_HIGH;  /* split case */
636     config->fResTransIsLow = 0;  /* for transient frames, set variable frequency resolution according to freqResTable */
637 
638     /* header_extra_1 */
639     config->freqScale       = SBR_FREQ_SCALE_DEFAULT;
640     config->alterScale      = SBR_ALTER_SCALE_DEFAULT;
641     config->sbr_noise_bands = SBR_NOISE_BANDS_DEFAULT;
642 
643     /* header_extra_2 */
644     config->sbr_limiter_bands    = SBR_LIMITER_BANDS_DEFAULT;
645     config->sbr_limiter_gains    = SBR_LIMITER_GAINS_DEFAULT;
646     config->sbr_interpol_freq    = SBR_INTERPOL_FREQ_DEFAULT;
647     config->sbr_smoothing_length = SBR_SMOOTHING_LENGTH_DEFAULT;
648 
649     return 1;
650 }
651 
652 
653 /*****************************************************************************
654 
655  functionname: DeleteEnvChannel
656  description:  frees memory of one SBR channel
657  returns:      -
658  input:        handle of channel
659  output:       released handle
660 
661 *****************************************************************************/
662 static void
deleteEnvChannel(HANDLE_ENV_CHANNEL hEnvCut)663 deleteEnvChannel (HANDLE_ENV_CHANNEL hEnvCut)
664 {
665   if (hEnvCut) {
666 
667     FDKsbrEnc_DeleteTonCorrParamExtr(&hEnvCut->TonCorr);
668 
669     FDKsbrEnc_deleteExtractSbrEnvelope (&hEnvCut->sbrExtractEnvelope);
670   }
671 
672 }
673 
674 
675 /*****************************************************************************
676 
677  functionname: sbrEncoder_ChannelClose
678  description:  close the channel coding handle
679  returns:
680  input:        phSbrChannel
681  output:
682 
683 *****************************************************************************/
684 static void
sbrEncoder_ChannelClose(HANDLE_SBR_CHANNEL hSbrChannel)685 sbrEncoder_ChannelClose(HANDLE_SBR_CHANNEL hSbrChannel)
686 {
687   if (hSbrChannel != NULL)
688   {
689     deleteEnvChannel (&hSbrChannel->hEnvChannel);
690   }
691 }
692 
693 /*****************************************************************************
694 
695  functionname: sbrEncoder_ElementClose
696  description:  close the channel coding handle
697  returns:
698  input:        phSbrChannel
699  output:
700 
701 *****************************************************************************/
702 static void
sbrEncoder_ElementClose(HANDLE_SBR_ELEMENT * phSbrElement)703 sbrEncoder_ElementClose(HANDLE_SBR_ELEMENT *phSbrElement)
704 {
705   HANDLE_SBR_ELEMENT hSbrElement = *phSbrElement;
706 
707   if (hSbrElement!=NULL) {
708     if (hSbrElement->sbrConfigData.v_k_master)
709       FreeRam_Sbr_v_k_master(&hSbrElement->sbrConfigData.v_k_master);
710     if (hSbrElement->sbrConfigData.freqBandTable[LO])
711       FreeRam_Sbr_freqBandTableLO(&hSbrElement->sbrConfigData.freqBandTable[LO]);
712     if (hSbrElement->sbrConfigData.freqBandTable[HI])
713       FreeRam_Sbr_freqBandTableHI(&hSbrElement->sbrConfigData.freqBandTable[HI]);
714 
715     FreeRam_SbrElement(phSbrElement);
716   }
717   return ;
718 
719 }
720 
721 
sbrEncoder_Close(HANDLE_SBR_ENCODER * phSbrEncoder)722 void sbrEncoder_Close (HANDLE_SBR_ENCODER *phSbrEncoder)
723 {
724   HANDLE_SBR_ENCODER hSbrEncoder = *phSbrEncoder;
725 
726   if (hSbrEncoder != NULL)
727   {
728     int el, ch;
729 
730     for (el=0; el<(8); el++)
731     {
732       if (hSbrEncoder->sbrElement[el]!=NULL) {
733         sbrEncoder_ElementClose(&hSbrEncoder->sbrElement[el]);
734       }
735     }
736 
737     /* Close sbr Channels */
738     for (ch=0; ch<(8); ch++)
739     {
740       if (hSbrEncoder->pSbrChannel[ch]) {
741         sbrEncoder_ChannelClose(hSbrEncoder->pSbrChannel[ch]);
742         FreeRam_SbrChannel(&hSbrEncoder->pSbrChannel[ch]);
743       }
744 
745       if (hSbrEncoder->QmfAnalysis[ch].FilterStates)
746         FreeRam_Sbr_QmfStatesAnalysis((FIXP_QAS**)&hSbrEncoder->QmfAnalysis[ch].FilterStates);
747 
748 
749     }
750 
751     if (hSbrEncoder->hParametricStereo)
752       PSEnc_Destroy(&hSbrEncoder->hParametricStereo);
753     if (hSbrEncoder->qmfSynthesisPS.FilterStates)
754       FreeRam_PsQmfStatesSynthesis((FIXP_DBL**)&hSbrEncoder->qmfSynthesisPS.FilterStates);
755 
756     /* Release Overlay */
757     FreeRam_SbrDynamic_RAM((FIXP_DBL**)&hSbrEncoder->pSBRdynamic_RAM);
758 
759 
760     FreeRam_SbrEncoder(phSbrEncoder);
761   }
762 
763 }
764 
765 /*****************************************************************************
766 
767  functionname: updateFreqBandTable
768  description:  updates vk_master
769  returns:      -
770  input:        config handle
771  output:       error info
772 
773 *****************************************************************************/
updateFreqBandTable(HANDLE_SBR_CONFIG_DATA sbrConfigData,HANDLE_SBR_HEADER_DATA sbrHeaderData,const INT downSampleFactor)774 static INT updateFreqBandTable(
775         HANDLE_SBR_CONFIG_DATA  sbrConfigData,
776         HANDLE_SBR_HEADER_DATA  sbrHeaderData,
777         const INT               downSampleFactor
778         )
779 {
780   INT k0, k2;
781 
782   if( FDKsbrEnc_FindStartAndStopBand (
783               sbrConfigData->sampleFreq,
784               sbrConfigData->sampleFreq >> (downSampleFactor-1),
785               sbrConfigData->noQmfBands,
786               sbrHeaderData->sbr_start_frequency,
787               sbrHeaderData->sbr_stop_frequency,
788              &k0,
789              &k2
790               )
791     )
792     return(1);
793 
794 
795   if( FDKsbrEnc_UpdateFreqScale(
796               sbrConfigData->v_k_master,
797              &sbrConfigData->num_Master,
798               k0,
799               k2,
800               sbrHeaderData->freqScale,
801               sbrHeaderData->alterScale
802               )
803     )
804     return(1);
805 
806 
807   sbrHeaderData->sbr_xover_band=0;
808 
809 
810   if( FDKsbrEnc_UpdateHiRes(
811               sbrConfigData->freqBandTable[HI],
812               &sbrConfigData->nSfb[HI],
813               sbrConfigData->v_k_master,
814               sbrConfigData->num_Master,
815               &sbrHeaderData->sbr_xover_band
816               )
817     )
818     return(1);
819 
820 
821   FDKsbrEnc_UpdateLoRes(
822           sbrConfigData->freqBandTable[LO],
823           &sbrConfigData->nSfb[LO],
824           sbrConfigData->freqBandTable[HI],
825           sbrConfigData->nSfb[HI]
826           );
827 
828 
829   sbrConfigData->xOverFreq = (sbrConfigData->freqBandTable[LOW_RES][0] * sbrConfigData->sampleFreq / sbrConfigData->noQmfBands+1)>>1;
830 
831   return (0);
832 }
833 
834 
835 /*****************************************************************************
836 
837  functionname: resetEnvChannel
838  description:  resets parameters and allocates memory
839  returns:      error status
840  input:
841  output:       hEnv
842 
843 *****************************************************************************/
resetEnvChannel(HANDLE_SBR_CONFIG_DATA sbrConfigData,HANDLE_SBR_HEADER_DATA sbrHeaderData,HANDLE_ENV_CHANNEL hEnv)844 static INT resetEnvChannel (HANDLE_SBR_CONFIG_DATA  sbrConfigData,
845                             HANDLE_SBR_HEADER_DATA  sbrHeaderData,
846                             HANDLE_ENV_CHANNEL      hEnv)
847 {
848   /* note !!! hEnv->encEnvData.noOfnoisebands will be updated later in function FDKsbrEnc_extractSbrEnvelope !!!*/
849   hEnv->TonCorr.sbrNoiseFloorEstimate.noiseBands =  sbrHeaderData->sbr_noise_bands;
850 
851 
852   if(FDKsbrEnc_ResetTonCorrParamExtr(&hEnv->TonCorr,
853                            sbrConfigData->xposCtrlSwitch,
854                            sbrConfigData->freqBandTable[HI][0],
855                            sbrConfigData->v_k_master,
856                            sbrConfigData->num_Master,
857                            sbrConfigData->sampleFreq,
858                            sbrConfigData->freqBandTable,
859                            sbrConfigData->nSfb,
860                            sbrConfigData->noQmfBands))
861     return(1);
862 
863   hEnv->sbrCodeNoiseFloor.nSfb[LO] = hEnv->TonCorr.sbrNoiseFloorEstimate.noNoiseBands;
864   hEnv->sbrCodeNoiseFloor.nSfb[HI] = hEnv->TonCorr.sbrNoiseFloorEstimate.noNoiseBands;
865 
866   hEnv->sbrCodeEnvelope.nSfb[LO] = sbrConfigData->nSfb[LO];
867   hEnv->sbrCodeEnvelope.nSfb[HI] = sbrConfigData->nSfb[HI];
868 
869   hEnv->encEnvData.noHarmonics = sbrConfigData->nSfb[HI];
870 
871   hEnv->sbrCodeEnvelope.upDate = 0;
872   hEnv->sbrCodeNoiseFloor.upDate = 0;
873 
874   return (0);
875 }
876 
877 /* ****************************** FDKsbrEnc_SbrGetXOverFreq ******************************/
878 /**
879  * @fn
880  * @brief       calculates the closest possible crossover frequency
881  * @return      the crossover frequency SBR accepts
882  *
883  */
884 static INT
FDKsbrEnc_SbrGetXOverFreq(HANDLE_SBR_ELEMENT hEnv,INT xoverFreq)885 FDKsbrEnc_SbrGetXOverFreq(HANDLE_SBR_ELEMENT  hEnv,        /*!< handle to SBR encoder instance */
886                           INT                 xoverFreq)   /*!< from core coder suggested crossover frequency */
887 {
888   INT band;
889   INT lastDiff, newDiff;
890   INT cutoffSb;
891 
892   UCHAR *RESTRICT pVKMaster = hEnv->sbrConfigData.v_k_master;
893 
894   /* Check if there is a matching cutoff frequency in the master table */
895   cutoffSb = (4*xoverFreq * hEnv->sbrConfigData.noQmfBands / hEnv->sbrConfigData.sampleFreq + 1)>>1;
896   lastDiff = cutoffSb;
897   for (band = 0; band < hEnv->sbrConfigData.num_Master; band++) {
898 
899     newDiff = fixp_abs((INT)pVKMaster[band] - cutoffSb);
900 
901     if(newDiff >= lastDiff) {
902       band--;
903       break;
904     }
905 
906     lastDiff = newDiff;
907   }
908 
909   return ((pVKMaster[band] * hEnv->sbrConfigData.sampleFreq/hEnv->sbrConfigData.noQmfBands+1)>>1);
910 }
911 
912 /*****************************************************************************
913 
914  functionname: FDKsbrEnc_EnvEncodeFrame
915  description: performs the sbr envelope calculation for one element
916  returns:
917  input:
918  output:
919 
920 *****************************************************************************/
921 INT
FDKsbrEnc_EnvEncodeFrame(HANDLE_SBR_ENCODER hEnvEncoder,int iElement,INT_PCM * samples,UINT timeInStride,UINT * sbrDataBits,UCHAR * sbrData,int clearOutput)922 FDKsbrEnc_EnvEncodeFrame(HANDLE_SBR_ENCODER   hEnvEncoder,
923                          int                  iElement,
924                          INT_PCM             *samples,                 /*!< time samples, always interleaved */
925                          UINT                 timeInStride,            /*!< time buffer channel interleaving stride */
926                          UINT                *sbrDataBits,             /*!< Size of SBR payload  */
927                          UCHAR               *sbrData,                 /*!< SBR payload  */
928                          int                  clearOutput              /*!< Do not consider any input signal */
929                         )
930 {
931   HANDLE_SBR_ELEMENT hSbrElement = NULL;
932   FDK_CRCINFO  crcInfo;
933   INT    crcReg;
934   INT    ch;
935   INT    band;
936   INT    cutoffSb;
937   INT    newXOver;
938 
939   if (hEnvEncoder == NULL)
940     return -1;
941 
942   hSbrElement = hEnvEncoder->sbrElement[iElement];
943 
944   if (hSbrElement == NULL)
945     return -1;
946 
947 
948   /* header bitstream handling */
949   HANDLE_SBR_BITSTREAM_DATA sbrBitstreamData = &hSbrElement->sbrBitstreamData;
950 
951   INT psHeaderActive = 0;
952   sbrBitstreamData->HeaderActive = 0;
953 
954   /* Anticipate PS header because of internal PS bitstream delay in order to be in sync with SBR header. */
955   if ( sbrBitstreamData->CountSendHeaderData==(sbrBitstreamData->NrSendHeaderData-1) )
956   {
957       psHeaderActive = 1;
958   }
959 
960   /* Signal SBR header to be written into bitstream */
961   if ( sbrBitstreamData->CountSendHeaderData==0  )
962   {
963      sbrBitstreamData->HeaderActive = 1;
964   }
965 
966   /* Increment header interval counter */
967   if (sbrBitstreamData->NrSendHeaderData == 0) {
968     sbrBitstreamData->CountSendHeaderData = 1;
969   }
970   else {
971     if (sbrBitstreamData->CountSendHeaderData >= 0) {
972       sbrBitstreamData->CountSendHeaderData++;
973       sbrBitstreamData->CountSendHeaderData %= sbrBitstreamData->NrSendHeaderData;
974     }
975   }
976 
977   if (hSbrElement->CmonData.dynBwEnabled ) {
978     INT i;
979     for ( i = 4; i > 0; i-- )
980       hSbrElement->dynXOverFreqDelay[i] = hSbrElement->dynXOverFreqDelay[i-1];
981 
982     hSbrElement->dynXOverFreqDelay[0] = hSbrElement->CmonData.dynXOverFreqEnc;
983     if (hSbrElement->dynXOverFreqDelay[1] > hSbrElement->dynXOverFreqDelay[2])
984       newXOver = hSbrElement->dynXOverFreqDelay[2];
985     else
986       newXOver = hSbrElement->dynXOverFreqDelay[1];
987 
988     /* has the crossover frequency changed? */
989     if ( hSbrElement->sbrConfigData.dynXOverFreq != newXOver ) {
990 
991       /* get corresponding master band */
992       cutoffSb = ((4* newXOver * hSbrElement->sbrConfigData.noQmfBands
993                   / hSbrElement->sbrConfigData.sampleFreq)+1)>>1;
994 
995       for ( band = 0; band < hSbrElement->sbrConfigData.num_Master; band++ ) {
996         if ( cutoffSb == hSbrElement->sbrConfigData.v_k_master[band] )
997           break;
998       }
999       FDK_ASSERT( band < hSbrElement->sbrConfigData.num_Master );
1000 
1001       hSbrElement->sbrConfigData.dynXOverFreq = newXOver;
1002       hSbrElement->sbrHeaderData.sbr_xover_band = band;
1003       hSbrElement->sbrBitstreamData.HeaderActive=1;
1004       psHeaderActive = 1; /* ps header is one frame delayed */
1005 
1006       /*
1007         update vk_master table
1008       */
1009       if(updateFreqBandTable(&hSbrElement->sbrConfigData,
1010                              &hSbrElement->sbrHeaderData,
1011                              hEnvEncoder->downSampleFactor
1012                              ))
1013         return(1);
1014 
1015 
1016       /* reset SBR channels */
1017       INT nEnvCh = hSbrElement->sbrConfigData.nChannels;
1018       for ( ch = 0; ch < nEnvCh; ch++ ) {
1019         if(resetEnvChannel (&hSbrElement->sbrConfigData,
1020                             &hSbrElement->sbrHeaderData,
1021                             &hSbrElement->sbrChannel[ch]->hEnvChannel))
1022           return(1);
1023 
1024       }
1025     }
1026   }
1027 
1028   /*
1029     allocate space for dummy header and crc
1030   */
1031   crcReg = FDKsbrEnc_InitSbrBitstream(&hSbrElement->CmonData,
1032                                        hSbrElement->payloadDelayLine[hEnvEncoder->nBitstrDelay],
1033                                        MAX_PAYLOAD_SIZE*sizeof(UCHAR),
1034                                       &crcInfo,
1035                                        hSbrElement->sbrConfigData.sbrSyntaxFlags);
1036 
1037   /* Temporal Envelope Data */
1038   SBR_FRAME_TEMP_DATA _fData;
1039   SBR_FRAME_TEMP_DATA *fData = &_fData;
1040   SBR_ENV_TEMP_DATA eData[MAX_NUM_CHANNELS];
1041 
1042   /* Init Temporal Envelope Data */
1043   {
1044     int i;
1045 
1046     FDKmemclear(&eData[0], sizeof(SBR_ENV_TEMP_DATA));
1047     FDKmemclear(&eData[1], sizeof(SBR_ENV_TEMP_DATA));
1048     FDKmemclear(fData, sizeof(SBR_FRAME_TEMP_DATA));
1049 
1050     for(i=0; i<MAX_NUM_NOISE_VALUES; i++)
1051       fData->res[i] = FREQ_RES_HIGH;
1052   }
1053 
1054 
1055   if (!clearOutput)
1056   {
1057     /*
1058      * Transform audio data into QMF domain
1059      */
1060     for(ch = 0; ch < hSbrElement->sbrConfigData.nChannels; ch++)
1061     {
1062       HANDLE_ENV_CHANNEL h_envChan = &hSbrElement->sbrChannel[ch]->hEnvChannel;
1063       HANDLE_SBR_EXTRACT_ENVELOPE sbrExtrEnv = &h_envChan->sbrExtractEnvelope;
1064 
1065       if(hSbrElement->elInfo.fParametricStereo == 0)
1066       {
1067         QMF_SCALE_FACTOR tmpScale;
1068         FIXP_DBL **pQmfReal, **pQmfImag;
1069         C_AALLOC_SCRATCH_START(qmfWorkBuffer, FIXP_DBL, QMF_CHANNELS*2)
1070 
1071 
1072         /* Obtain pointers to QMF buffers. */
1073         pQmfReal = sbrExtrEnv->rBuffer;
1074         pQmfImag = sbrExtrEnv->iBuffer;
1075 
1076         qmfAnalysisFiltering( hSbrElement->hQmfAnalysis[ch],
1077                                pQmfReal,
1078                                pQmfImag,
1079                               &tmpScale,
1080                                samples + hSbrElement->elInfo.ChannelIndex[ch],
1081                                timeInStride,
1082                                qmfWorkBuffer );
1083 
1084         h_envChan->qmfScale = tmpScale.lb_scale + 7;
1085 
1086 
1087         C_AALLOC_SCRATCH_END(qmfWorkBuffer, FIXP_DBL, QMF_CHANNELS*2)
1088 
1089       } /* fParametricStereo == 0 */
1090 
1091 
1092       /*
1093         Parametric Stereo processing
1094       */
1095       if (hSbrElement->elInfo.fParametricStereo)
1096       {
1097         INT error = noError;
1098 
1099 
1100         /* Limit Parametric Stereo to one instance */
1101         FDK_ASSERT(ch == 0);
1102 
1103 
1104         if(error == noError){
1105           /* parametric stereo processing:
1106              - input:
1107                o left and right time domain samples
1108              - processing:
1109                o stereo qmf analysis
1110                o stereo hybrid analysis
1111                o ps parameter extraction
1112                o downmix + hybrid synthesis
1113              - output:
1114                o downmixed qmf data is written to sbrExtrEnv->rBuffer and sbrExtrEnv->iBuffer
1115           */
1116           SCHAR qmfScale;
1117           INT_PCM* pSamples[2] = {samples + hSbrElement->elInfo.ChannelIndex[0],samples + hSbrElement->elInfo.ChannelIndex[1]};
1118           error = FDKsbrEnc_PSEnc_ParametricStereoProcessing( hEnvEncoder->hParametricStereo,
1119                                                               pSamples,
1120                                                               timeInStride,
1121                                                               hSbrElement->hQmfAnalysis,
1122                                                               sbrExtrEnv->rBuffer,
1123                                                               sbrExtrEnv->iBuffer,
1124                                                               samples + hSbrElement->elInfo.ChannelIndex[ch],
1125                                                              &hEnvEncoder->qmfSynthesisPS,
1126                                                              &qmfScale,
1127                                                               psHeaderActive );
1128           if (noError != error)
1129           {
1130             error = handBack(error);
1131           }
1132           h_envChan->qmfScale = (int)qmfScale;
1133         }
1134 
1135 
1136       } /* if (hEnvEncoder->hParametricStereo) */
1137 
1138       /*
1139 
1140          Extract Envelope relevant things from QMF data
1141 
1142       */
1143       FDKsbrEnc_extractSbrEnvelope1(
1144                                 &hSbrElement->sbrConfigData,
1145                                 &hSbrElement->sbrHeaderData,
1146                                 &hSbrElement->sbrBitstreamData,
1147                                  h_envChan,
1148                                 &hSbrElement->CmonData,
1149                                 &eData[ch],
1150                                  fData
1151                                  );
1152 
1153     } /* hEnvEncoder->sbrConfigData.nChannels */
1154  }
1155 
1156   /*
1157      Process Envelope relevant things and calculate envelope data and write payload
1158   */
1159   FDKsbrEnc_extractSbrEnvelope2(
1160                                 &hSbrElement->sbrConfigData,
1161                                 &hSbrElement->sbrHeaderData,
1162                                 (hSbrElement->elInfo.fParametricStereo) ? hEnvEncoder->hParametricStereo : NULL,
1163                                 &hSbrElement->sbrBitstreamData,
1164                                 &hSbrElement->sbrChannel[0]->hEnvChannel,
1165                                 &hSbrElement->sbrChannel[1]->hEnvChannel,
1166                                 &hSbrElement->CmonData,
1167                                  eData,
1168                                  fData,
1169                                  clearOutput
1170                                );
1171 
1172   /*
1173     format payload, calculate crc
1174   */
1175   FDKsbrEnc_AssembleSbrBitstream(&hSbrElement->CmonData, &crcInfo, crcReg, hSbrElement->sbrConfigData.sbrSyntaxFlags);
1176 
1177   /*
1178     save new payload, set to zero length if greater than MAX_PAYLOAD_SIZE
1179   */
1180   hSbrElement->payloadDelayLineSize[hEnvEncoder->nBitstrDelay] = FDKgetValidBits(&hSbrElement->CmonData.sbrBitbuf);
1181 
1182   if(hSbrElement->payloadDelayLineSize[hEnvEncoder->nBitstrDelay] > (MAX_PAYLOAD_SIZE<<3))
1183     hSbrElement->payloadDelayLineSize[hEnvEncoder->nBitstrDelay]=0;
1184 
1185   /* While filling the Delay lines, sbrData is NULL */
1186   if (sbrData) {
1187     *sbrDataBits = hSbrElement->payloadDelayLineSize[0];
1188     FDKmemcpy(sbrData, hSbrElement->payloadDelayLine[0], (hSbrElement->payloadDelayLineSize[0]+7)>>3);
1189 
1190 
1191   }
1192 
1193 
1194 /*******************************/
1195 
1196   if (hEnvEncoder->fTimeDomainDownsampling)
1197   {
1198     int ch;
1199     int nChannels = hSbrElement->sbrConfigData.nChannels;
1200 
1201     for (ch=0; ch < nChannels; ch++)
1202     {
1203       INT nOutSamples;
1204 
1205       FDKaacEnc_Downsample(&hSbrElement->sbrChannel[ch]->downSampler,
1206                             samples + hSbrElement->elInfo.ChannelIndex[ch] + hEnvEncoder->bufferOffset,
1207                             hSbrElement->sbrConfigData.frameSize,
1208                             timeInStride,
1209                             samples + hSbrElement->elInfo.ChannelIndex[ch],
1210                            &nOutSamples,
1211                             hEnvEncoder->nChannels);
1212     }
1213   } /* downsample */
1214 
1215 
1216   return (0);
1217 }
1218 
1219 /*****************************************************************************
1220 
1221  functionname: createEnvChannel
1222  description:  initializes parameters and allocates memory
1223  returns:      error status
1224  input:
1225  output:       hEnv
1226 
1227 *****************************************************************************/
1228 
1229 static INT
createEnvChannel(HANDLE_ENV_CHANNEL hEnv,INT channel,UCHAR * dynamic_RAM)1230 createEnvChannel (HANDLE_ENV_CHANNEL     hEnv,
1231                   INT                    channel
1232                  ,UCHAR*                 dynamic_RAM
1233                  )
1234 {
1235   FDKmemclear(hEnv,sizeof (struct ENV_CHANNEL));
1236 
1237   if ( FDKsbrEnc_CreateTonCorrParamExtr(&hEnv->TonCorr,
1238                                          channel) )
1239   {
1240     return(1);
1241   }
1242 
1243   if ( FDKsbrEnc_CreateExtractSbrEnvelope (&hEnv->sbrExtractEnvelope,
1244                                channel
1245                               ,/*chan*/0
1246                               ,dynamic_RAM
1247                               ) )
1248   {
1249     return(1);
1250   }
1251 
1252   return 0;
1253 }
1254 
1255 /*****************************************************************************
1256 
1257  functionname: initEnvChannel
1258  description:  initializes parameters
1259  returns:      error status
1260  input:
1261  output:
1262 
1263 *****************************************************************************/
1264 static INT
initEnvChannel(HANDLE_SBR_CONFIG_DATA sbrConfigData,HANDLE_SBR_HEADER_DATA sbrHeaderData,HANDLE_ENV_CHANNEL hEnv,sbrConfigurationPtr params,ULONG statesInitFlag,INT chanInEl,UCHAR * dynamic_RAM)1265 initEnvChannel (  HANDLE_SBR_CONFIG_DATA sbrConfigData,
1266                   HANDLE_SBR_HEADER_DATA sbrHeaderData,
1267                   HANDLE_ENV_CHANNEL     hEnv,
1268                   sbrConfigurationPtr    params,
1269                   ULONG                  statesInitFlag
1270                  ,INT                    chanInEl
1271                  ,UCHAR*                 dynamic_RAM
1272                  )
1273 {
1274   int frameShift, tran_off=0;
1275   INT e;
1276   INT tran_fc;
1277   INT timeSlots, timeStep, startIndex;
1278   INT noiseBands[2] = { 3, 3 };
1279 
1280   e = 1 << params->e;
1281 
1282   FDK_ASSERT(params->e >= 0);
1283 
1284   hEnv->encEnvData.freq_res_fixfix[0] = params->freq_res_fixfix[0];
1285   hEnv->encEnvData.freq_res_fixfix[1] = params->freq_res_fixfix[1];
1286   hEnv->encEnvData.fResTransIsLow     = params->fResTransIsLow;
1287 
1288   hEnv->fLevelProtect = 0;
1289 
1290   hEnv->encEnvData.ldGrid = (sbrConfigData->sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY) ? 1 : 0;
1291 
1292   hEnv->encEnvData.sbr_xpos_mode = (XPOS_MODE)params->sbr_xpos_mode;
1293 
1294   if (hEnv->encEnvData.sbr_xpos_mode == XPOS_SWITCHED) {
1295     /*
1296        no other type than XPOS_MDCT or XPOS_SPEECH allowed,
1297        but enable switching
1298     */
1299     sbrConfigData->switchTransposers = TRUE;
1300     hEnv->encEnvData.sbr_xpos_mode = XPOS_MDCT;
1301   }
1302   else {
1303     sbrConfigData->switchTransposers = FALSE;
1304   }
1305 
1306   hEnv->encEnvData.sbr_xpos_ctrl = params->sbr_xpos_ctrl;
1307 
1308 
1309   /* extended data */
1310   if(params->parametricCoding) {
1311     hEnv->encEnvData.extended_data = 1;
1312   }
1313   else {
1314     hEnv->encEnvData.extended_data = 0;
1315   }
1316 
1317   hEnv->encEnvData.extension_size = 0;
1318 
1319   startIndex = QMF_FILTER_PROTOTYPE_SIZE - sbrConfigData->noQmfBands;
1320 
1321   switch (params->sbrFrameSize) {
1322   case 2304:
1323     timeSlots = 18;
1324     break;
1325   case 2048:
1326   case 1024:
1327   case 512:
1328     timeSlots = 16;
1329     break;
1330   case 1920:
1331   case 960:
1332   case 480:
1333     timeSlots = 15;
1334     break;
1335   case 1152:
1336     timeSlots = 9;
1337     break;
1338   default:
1339     return (1); /* Illegal frame size */
1340   }
1341 
1342   timeStep = sbrConfigData->noQmfSlots / timeSlots;
1343 
1344   if ( FDKsbrEnc_InitTonCorrParamExtr(params->sbrFrameSize,
1345                                      &hEnv->TonCorr,
1346                                       sbrConfigData,
1347                                       timeSlots,
1348                                       params->sbr_xpos_ctrl,
1349                                       params->ana_max_level,
1350                                       sbrHeaderData->sbr_noise_bands,
1351                                       params->noiseFloorOffset,
1352                                       params->useSpeechConfig) )
1353     return(1);
1354 
1355   hEnv->encEnvData.noOfnoisebands = hEnv->TonCorr.sbrNoiseFloorEstimate.noNoiseBands;
1356 
1357   noiseBands[0] = hEnv->encEnvData.noOfnoisebands;
1358   noiseBands[1] = hEnv->encEnvData.noOfnoisebands;
1359 
1360   hEnv->encEnvData.sbr_invf_mode = (INVF_MODE)params->sbr_invf_mode;
1361 
1362   if (hEnv->encEnvData.sbr_invf_mode == INVF_SWITCHED) {
1363     hEnv->encEnvData.sbr_invf_mode = INVF_MID_LEVEL;
1364     hEnv->TonCorr.switchInverseFilt = TRUE;
1365   }
1366   else {
1367     hEnv->TonCorr.switchInverseFilt = FALSE;
1368   }
1369 
1370 
1371   tran_fc  = params->tran_fc;
1372 
1373   if (tran_fc == 0) {
1374     tran_fc = fixMin (5000, FDKsbrEnc_getSbrStartFreqRAW (sbrHeaderData->sbr_start_frequency,params->codecSettings.sampleFreq));
1375   }
1376 
1377   tran_fc = (tran_fc*4*sbrConfigData->noQmfBands/sbrConfigData->sampleFreq + 1)>>1;
1378 
1379   if (sbrConfigData->sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY) {
1380     frameShift = LD_PRETRAN_OFF;
1381     tran_off = LD_PRETRAN_OFF + FRAME_MIDDLE_SLOT_512LD*timeStep;
1382   } else
1383   {
1384     frameShift = 0;
1385     switch (timeSlots) {
1386       /* The factor of 2 is by definition. */
1387       case NUMBER_TIME_SLOTS_2048: tran_off = 8 + FRAME_MIDDLE_SLOT_2048 * timeStep; break;
1388       case NUMBER_TIME_SLOTS_1920: tran_off = 7 + FRAME_MIDDLE_SLOT_1920 * timeStep; break;
1389       default: return 1;
1390     }
1391   }
1392   if ( FDKsbrEnc_InitExtractSbrEnvelope (&hEnv->sbrExtractEnvelope,
1393                                sbrConfigData->noQmfSlots,
1394                                sbrConfigData->noQmfBands, startIndex,
1395                                timeSlots, timeStep, tran_off,
1396                                statesInitFlag
1397                               ,chanInEl
1398                               ,dynamic_RAM
1399                               ,sbrConfigData->sbrSyntaxFlags
1400                                ) )
1401     return(1);
1402 
1403   if(FDKsbrEnc_InitSbrCodeEnvelope (&hEnv->sbrCodeEnvelope,
1404                             sbrConfigData->nSfb,
1405                             params->deltaTAcrossFrames,
1406                             params->dF_edge_1stEnv,
1407                             params->dF_edge_incr))
1408     return(1);
1409 
1410   if(FDKsbrEnc_InitSbrCodeEnvelope (&hEnv->sbrCodeNoiseFloor,
1411                             noiseBands,
1412                             params->deltaTAcrossFrames,
1413                             0,0))
1414     return(1);
1415 
1416   sbrConfigData->initAmpResFF = params->init_amp_res_FF;
1417 
1418   if(FDKsbrEnc_InitSbrHuffmanTables (&hEnv->encEnvData,
1419                            &hEnv->sbrCodeEnvelope,
1420                            &hEnv->sbrCodeNoiseFloor,
1421                            sbrHeaderData->sbr_amp_res))
1422    return(1);
1423 
1424   FDKsbrEnc_initFrameInfoGenerator (&hEnv->SbrEnvFrame,
1425                             params->spread,
1426                             e,
1427                             params->stat,
1428                             timeSlots,
1429                             hEnv->encEnvData.freq_res_fixfix,
1430                             hEnv->encEnvData.fResTransIsLow,
1431                             hEnv->encEnvData.ldGrid
1432                             );
1433 
1434   if(sbrConfigData->sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY)
1435   {
1436     INT bandwidth_qmf_slot = (sbrConfigData->sampleFreq>>1) / (sbrConfigData->noQmfBands);
1437     if(FDKsbrEnc_InitSbrFastTransientDetector(
1438               &hEnv->sbrFastTransientDetector,
1439                sbrConfigData->noQmfSlots,
1440                bandwidth_qmf_slot,
1441                sbrConfigData->noQmfBands,
1442                sbrConfigData->freqBandTable[0][0]
1443                ))
1444       return(1);
1445   }
1446 
1447   /* The transient detector has to be initialized also if the fast transient
1448      detector was active, because the values from the transient detector
1449      structure are used. */
1450   if(FDKsbrEnc_InitSbrTransientDetector (&hEnv->sbrTransientDetector,
1451                                           sbrConfigData->sbrSyntaxFlags,
1452                                           sbrConfigData->frameSize,
1453                                           sbrConfigData->sampleFreq,
1454                                           params,
1455                                           tran_fc,
1456                                           sbrConfigData->noQmfSlots,
1457                                           sbrConfigData->noQmfBands,
1458                                           hEnv->sbrExtractEnvelope.YBufferWriteOffset,
1459                                           hEnv->sbrExtractEnvelope.YBufferSzShift,
1460                                           frameShift,
1461                                           tran_off
1462                                           ))
1463   return(1);
1464 
1465 
1466   sbrConfigData->xposCtrlSwitch = params->sbr_xpos_ctrl;
1467 
1468   hEnv->encEnvData.noHarmonics = sbrConfigData->nSfb[HI];
1469   hEnv->encEnvData.addHarmonicFlag = 0;
1470 
1471   return (0);
1472 }
1473 
sbrEncoder_Open(HANDLE_SBR_ENCODER * phSbrEncoder,INT nElements,INT nChannels,INT supportPS)1474 INT sbrEncoder_Open(
1475         HANDLE_SBR_ENCODER  *phSbrEncoder,
1476         INT                  nElements,
1477         INT                  nChannels,
1478         INT                  supportPS
1479         )
1480 {
1481   INT i;
1482   INT errorStatus = 1;
1483   HANDLE_SBR_ENCODER hSbrEncoder = NULL;
1484 
1485   if (phSbrEncoder==NULL
1486      )
1487   {
1488     goto bail;
1489   }
1490 
1491   hSbrEncoder = GetRam_SbrEncoder();
1492   if (hSbrEncoder==NULL) {
1493     goto bail;
1494   }
1495   FDKmemclear(hSbrEncoder, sizeof(SBR_ENCODER));
1496 
1497       hSbrEncoder->pSBRdynamic_RAM = (UCHAR*)GetRam_SbrDynamic_RAM();
1498       hSbrEncoder->dynamicRam = hSbrEncoder->pSBRdynamic_RAM;
1499 
1500   for (i=0; i<nElements; i++) {
1501     hSbrEncoder->sbrElement[i] = GetRam_SbrElement(i);
1502     if (hSbrEncoder->sbrElement[i]==NULL) {
1503         goto bail;
1504     }
1505     FDKmemclear(hSbrEncoder->sbrElement[i], sizeof(SBR_ELEMENT));
1506     hSbrEncoder->sbrElement[i]->sbrConfigData.freqBandTable[LO] =  GetRam_Sbr_freqBandTableLO(i);
1507     hSbrEncoder->sbrElement[i]->sbrConfigData.freqBandTable[HI] =  GetRam_Sbr_freqBandTableHI(i);
1508     hSbrEncoder->sbrElement[i]->sbrConfigData.v_k_master        =  GetRam_Sbr_v_k_master(i);
1509     if ( (hSbrEncoder->sbrElement[i]->sbrConfigData.freqBandTable[LO]==NULL) ||
1510          (hSbrEncoder->sbrElement[i]->sbrConfigData.freqBandTable[HI]==NULL) ||
1511          (hSbrEncoder->sbrElement[i]->sbrConfigData.v_k_master==NULL) )
1512     {
1513         goto bail;
1514     }
1515   }
1516 
1517   for (i=0; i<nChannels; i++) {
1518     hSbrEncoder->pSbrChannel[i] = GetRam_SbrChannel(i);
1519     if (hSbrEncoder->pSbrChannel[i]==NULL) {
1520         goto bail;
1521     }
1522 
1523     if ( createEnvChannel(&hSbrEncoder->pSbrChannel[i]->hEnvChannel,
1524                            i
1525                           ,hSbrEncoder->dynamicRam
1526                            ) )
1527     {
1528         goto bail;
1529     }
1530 
1531   }
1532 
1533   for (i=0; i<fixMax(nChannels,(supportPS)?2:0); i++) {
1534     hSbrEncoder->QmfAnalysis[i].FilterStates = GetRam_Sbr_QmfStatesAnalysis(i);
1535     if (hSbrEncoder->QmfAnalysis[i].FilterStates==NULL) {
1536         goto bail;
1537     }
1538   }
1539 
1540   if (supportPS) {
1541     if (PSEnc_Create(&hSbrEncoder->hParametricStereo))
1542     {
1543       goto bail;
1544     }
1545 
1546     hSbrEncoder->qmfSynthesisPS.FilterStates = GetRam_PsQmfStatesSynthesis();
1547     if (hSbrEncoder->qmfSynthesisPS.FilterStates==NULL) {
1548       goto bail;
1549     }
1550   }  /* supportPS */
1551 
1552   *phSbrEncoder = hSbrEncoder;
1553 
1554   errorStatus = 0;
1555   return errorStatus;
1556 
1557 bail:
1558   /* Close SBR encoder instance */
1559   sbrEncoder_Close(&hSbrEncoder);
1560   return errorStatus;
1561 }
1562 
1563 static
FDKsbrEnc_Reallocate(HANDLE_SBR_ENCODER hSbrEncoder,SBR_ELEMENT_INFO elInfo[(8)],const INT noElements)1564 INT FDKsbrEnc_Reallocate(
1565                     HANDLE_SBR_ENCODER   hSbrEncoder,
1566                     SBR_ELEMENT_INFO     elInfo[(8)],
1567                     const INT            noElements)
1568 {
1569   INT totalCh = 0;
1570   INT totalQmf = 0;
1571   INT coreEl;
1572   INT el=-1;
1573 
1574   hSbrEncoder->lfeChIdx = -1; /* default value, until lfe found */
1575 
1576   for (coreEl=0; coreEl<noElements; coreEl++)
1577   {
1578     /* SBR only handles SCE and CPE's */
1579     if (elInfo[coreEl].elType == ID_SCE || elInfo[coreEl].elType == ID_CPE) {
1580       el++;
1581     } else {
1582       if (elInfo[coreEl].elType == ID_LFE) {
1583           hSbrEncoder->lfeChIdx = elInfo[coreEl].ChannelIndex[0];
1584       }
1585       continue;
1586     }
1587 
1588     SBR_ELEMENT_INFO    *pelInfo = &elInfo[coreEl];
1589     HANDLE_SBR_ELEMENT  hSbrElement = hSbrEncoder->sbrElement[el];
1590 
1591     int ch;
1592     for ( ch = 0; ch < pelInfo->nChannelsInEl; ch++ ) {
1593       hSbrElement->sbrChannel[ch] = hSbrEncoder->pSbrChannel[totalCh];
1594       totalCh++;
1595     }
1596     /* analysis QMF */
1597     for ( ch = 0; ch < ((pelInfo->fParametricStereo)?2:pelInfo->nChannelsInEl); ch++ ) {
1598       hSbrElement->elInfo.ChannelIndex[ch] = pelInfo->ChannelIndex[ch];
1599       hSbrElement->hQmfAnalysis[ch] = &hSbrEncoder->QmfAnalysis[totalQmf++];
1600     }
1601 
1602     /* Copy Element info */
1603     hSbrElement->elInfo.elType            = pelInfo->elType;
1604     hSbrElement->elInfo.instanceTag       = pelInfo->instanceTag;
1605     hSbrElement->elInfo.nChannelsInEl     = pelInfo->nChannelsInEl;
1606     hSbrElement->elInfo.fParametricStereo = pelInfo->fParametricStereo;
1607   } /* coreEl */
1608 
1609   return 0;
1610 }
1611 
1612 
1613 
1614 /*****************************************************************************
1615 
1616  functionname: FDKsbrEnc_EnvInit
1617  description:  initializes parameters
1618  returns:      error status
1619  input:
1620  output:       hEnv
1621 
1622 *****************************************************************************/
1623 static
FDKsbrEnc_EnvInit(HANDLE_SBR_ELEMENT hSbrElement,sbrConfigurationPtr params,INT * coreBandWith,AUDIO_OBJECT_TYPE aot,int nBitstrDelay,int nElement,const int headerPeriod,ULONG statesInitFlag,int fTimeDomainDownsampling,UCHAR * dynamic_RAM)1624 INT FDKsbrEnc_EnvInit (
1625                        HANDLE_SBR_ELEMENT   hSbrElement,
1626                        sbrConfigurationPtr params,
1627                        INT      *coreBandWith,
1628                        AUDIO_OBJECT_TYPE aot,
1629                        int       nBitstrDelay,
1630                        int       nElement,
1631                        const int headerPeriod,
1632                        ULONG     statesInitFlag,
1633                        int       fTimeDomainDownsampling
1634                       ,UCHAR    *dynamic_RAM
1635                       )
1636 {
1637   UCHAR    *bitstreamBuffer;
1638   int ch, i;
1639 
1640   if ((params->codecSettings.nChannels < 1) || (params->codecSettings.nChannels > MAX_NUM_CHANNELS)){
1641     return(1);
1642   }
1643 
1644   /* initialize the encoder handle  and structs*/
1645   bitstreamBuffer = hSbrElement->payloadDelayLine[nBitstrDelay];
1646 
1647   /* init and set syntax flags */
1648   hSbrElement->sbrConfigData.sbrSyntaxFlags = 0;
1649 
1650   switch (aot) {
1651   case AOT_ER_AAC_ELD:
1652     hSbrElement->sbrConfigData.sbrSyntaxFlags |= SBR_SYNTAX_LOW_DELAY;
1653     break;
1654   default:
1655     break;
1656   }
1657   if (params->crcSbr) {
1658     hSbrElement->sbrConfigData.sbrSyntaxFlags |= SBR_SYNTAX_CRC;
1659   }
1660 
1661   hSbrElement->sbrConfigData.noQmfBands = QMF_CHANNELS>>(2-params->downSampleFactor);
1662   switch (hSbrElement->sbrConfigData.noQmfBands)
1663   {
1664     case 64: hSbrElement->sbrConfigData.noQmfSlots = params->sbrFrameSize>>6;
1665              break;
1666     case 32: hSbrElement->sbrConfigData.noQmfSlots = params->sbrFrameSize>>5;
1667              break;
1668     default: hSbrElement->sbrConfigData.noQmfSlots = params->sbrFrameSize>>6;
1669              return(2);
1670   }
1671 
1672   FDKinitBitStream(&hSbrElement->CmonData.sbrBitbuf, bitstreamBuffer, MAX_PAYLOAD_SIZE*sizeof(UCHAR), 0, BS_WRITER);
1673 
1674   /*
1675     now initialize sbrConfigData, sbrHeaderData and sbrBitstreamData,
1676   */
1677   hSbrElement->sbrConfigData.nChannels = params->codecSettings.nChannels;
1678 
1679   if(params->codecSettings.nChannels == 2)
1680      hSbrElement->sbrConfigData.stereoMode = params->stereoMode;
1681   else
1682      hSbrElement->sbrConfigData.stereoMode = SBR_MONO;
1683 
1684   hSbrElement->sbrConfigData.frameSize   = params->sbrFrameSize;
1685 
1686   hSbrElement->sbrConfigData.sampleFreq = params->downSampleFactor * params->codecSettings.sampleFreq;
1687 
1688   hSbrElement->sbrBitstreamData.CountSendHeaderData = 0;
1689   if (params->SendHeaderDataTime > 0 ) {
1690 
1691     if (headerPeriod==-1) {
1692 
1693       hSbrElement->sbrBitstreamData.NrSendHeaderData = (INT)(params->SendHeaderDataTime * hSbrElement->sbrConfigData.sampleFreq
1694                                                / (1000 * hSbrElement->sbrConfigData.frameSize));
1695       hSbrElement->sbrBitstreamData.NrSendHeaderData = fixMax(hSbrElement->sbrBitstreamData.NrSendHeaderData,1);
1696     }
1697     else {
1698       /* assure header period at least once per second */
1699       hSbrElement->sbrBitstreamData.NrSendHeaderData = fixMin(fixMax(headerPeriod,1),(hSbrElement->sbrConfigData.sampleFreq/hSbrElement->sbrConfigData.frameSize));
1700     }
1701   }
1702   else {
1703    hSbrElement->sbrBitstreamData.NrSendHeaderData = 0;
1704   }
1705 
1706   hSbrElement->sbrHeaderData.sbr_data_extra = params->sbr_data_extra;
1707   hSbrElement->sbrBitstreamData.HeaderActive = 0;
1708   hSbrElement->sbrHeaderData.sbr_start_frequency = params->startFreq;
1709   hSbrElement->sbrHeaderData.sbr_stop_frequency  = params->stopFreq;
1710   hSbrElement->sbrHeaderData.sbr_xover_band = 0;
1711   hSbrElement->sbrHeaderData.sbr_lc_stereo_mode = 0;
1712 
1713   /* data_extra */
1714   if (params->sbr_xpos_ctrl!= SBR_XPOS_CTRL_DEFAULT)
1715      hSbrElement->sbrHeaderData.sbr_data_extra = 1;
1716 
1717   hSbrElement->sbrHeaderData.sbr_amp_res = (AMP_RES)params->amp_res;
1718 
1719   /* header_extra_1 */
1720   hSbrElement->sbrHeaderData.freqScale  = params->freqScale;
1721   hSbrElement->sbrHeaderData.alterScale = params->alterScale;
1722   hSbrElement->sbrHeaderData.sbr_noise_bands = params->sbr_noise_bands;
1723   hSbrElement->sbrHeaderData.header_extra_1 = 0;
1724 
1725   if ((params->freqScale != SBR_FREQ_SCALE_DEFAULT) ||
1726       (params->alterScale != SBR_ALTER_SCALE_DEFAULT) ||
1727       (params->sbr_noise_bands != SBR_NOISE_BANDS_DEFAULT))
1728   {
1729    hSbrElement->sbrHeaderData.header_extra_1 = 1;
1730   }
1731 
1732   /* header_extra_2 */
1733   hSbrElement->sbrHeaderData.sbr_limiter_bands = params->sbr_limiter_bands;
1734   hSbrElement->sbrHeaderData.sbr_limiter_gains = params->sbr_limiter_gains;
1735 
1736   if ((hSbrElement->sbrConfigData.sampleFreq > 48000) &&
1737       (hSbrElement->sbrHeaderData.sbr_start_frequency >= 9))
1738   {
1739     hSbrElement->sbrHeaderData.sbr_limiter_gains = SBR_LIMITER_GAINS_INFINITE;
1740   }
1741 
1742   hSbrElement->sbrHeaderData.sbr_interpol_freq = params->sbr_interpol_freq;
1743   hSbrElement->sbrHeaderData.sbr_smoothing_length = params->sbr_smoothing_length;
1744   hSbrElement->sbrHeaderData.header_extra_2 = 0;
1745 
1746   if ((params->sbr_limiter_bands != SBR_LIMITER_BANDS_DEFAULT) ||
1747       (params->sbr_limiter_gains != SBR_LIMITER_GAINS_DEFAULT) ||
1748       (params->sbr_interpol_freq != SBR_INTERPOL_FREQ_DEFAULT) ||
1749       (params->sbr_smoothing_length != SBR_SMOOTHING_LENGTH_DEFAULT))
1750   {
1751      hSbrElement->sbrHeaderData.header_extra_2 = 1;
1752   }
1753 
1754    /* other switches */
1755   hSbrElement->sbrConfigData.useWaveCoding             = params->useWaveCoding;
1756   hSbrElement->sbrConfigData.useParametricCoding       = params->parametricCoding;
1757   hSbrElement->sbrConfigData.thresholdAmpResFF_m       = params->threshold_AmpRes_FF_m;
1758   hSbrElement->sbrConfigData.thresholdAmpResFF_e       = params->threshold_AmpRes_FF_e;
1759 
1760   /* init freq band table */
1761   if(updateFreqBandTable(&hSbrElement->sbrConfigData,
1762                          &hSbrElement->sbrHeaderData,
1763                          params->downSampleFactor
1764                          ))
1765   {
1766     return(1);
1767   }
1768 
1769   /* now create envelope ext and QMF for each available channel */
1770   for ( ch = 0; ch < hSbrElement->sbrConfigData.nChannels; ch++ ) {
1771 
1772      if ( initEnvChannel(&hSbrElement->sbrConfigData,
1773                          &hSbrElement->sbrHeaderData,
1774                          &hSbrElement->sbrChannel[ch]->hEnvChannel,
1775                           params,
1776                           statesInitFlag
1777                         ,ch
1778                         ,dynamic_RAM
1779                          ) )
1780      {
1781        return(1);
1782      }
1783 
1784 
1785   } /* nChannels */
1786 
1787   /* reset and intialize analysis qmf */
1788   for ( ch = 0; ch < ((hSbrElement->elInfo.fParametricStereo)?2:hSbrElement->sbrConfigData.nChannels); ch++ )
1789   {
1790     int err;
1791     UINT qmfFlags = (hSbrElement->sbrConfigData.sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY) ? QMF_FLAG_CLDFB : 0;
1792     if (statesInitFlag)
1793       qmfFlags &= ~QMF_FLAG_KEEP_STATES;
1794     else
1795       qmfFlags |=  QMF_FLAG_KEEP_STATES;
1796 
1797     err = qmfInitAnalysisFilterBank( hSbrElement->hQmfAnalysis[ch],
1798                                      (FIXP_QAS*)hSbrElement->hQmfAnalysis[ch]->FilterStates,
1799                                      hSbrElement->sbrConfigData.noQmfSlots,
1800                                      hSbrElement->sbrConfigData.noQmfBands,
1801                                      hSbrElement->sbrConfigData.noQmfBands,
1802                                      hSbrElement->sbrConfigData.noQmfBands,
1803                                      qmfFlags );
1804     if (0!=err) {
1805       return err;
1806     }
1807   }
1808 
1809   /*  */
1810   hSbrElement->CmonData.xOverFreq = hSbrElement->sbrConfigData.xOverFreq;
1811   hSbrElement->CmonData.dynBwEnabled = (params->dynBwSupported && params->dynBwEnabled);
1812   hSbrElement->CmonData.dynXOverFreqEnc = FDKsbrEnc_SbrGetXOverFreq( hSbrElement, hSbrElement->CmonData.xOverFreq);
1813   for ( i = 0; i < 5; i++ )
1814       hSbrElement->dynXOverFreqDelay[i] = hSbrElement->CmonData.dynXOverFreqEnc;
1815   hSbrElement->CmonData.sbrNumChannels  = hSbrElement->sbrConfigData.nChannels;
1816   hSbrElement->sbrConfigData.dynXOverFreq = hSbrElement->CmonData.xOverFreq;
1817 
1818   /* Update Bandwith to be passed to the core encoder */
1819   *coreBandWith = hSbrElement->CmonData.xOverFreq;
1820 
1821   return(0);
1822  }
1823 
sbrEncoder_GetInBufferSize(int noChannels)1824 INT sbrEncoder_GetInBufferSize(int noChannels)
1825 {
1826   INT temp;
1827 
1828   temp = (2048);
1829   temp += 1024 + MAX_SAMPLE_DELAY;
1830   temp *= noChannels;
1831   temp *= sizeof(INT_PCM);
1832   return temp;
1833 }
1834 
1835 /*
1836  * Encode Dummy SBR payload frames to fill the delay lines.
1837  */
1838 static
FDKsbrEnc_DelayCompensation(HANDLE_SBR_ENCODER hEnvEnc,INT_PCM * timeBuffer)1839 INT FDKsbrEnc_DelayCompensation (
1840                                   HANDLE_SBR_ENCODER hEnvEnc,
1841                                   INT_PCM *timeBuffer
1842                                  )
1843 {
1844     int n, el;
1845 
1846     for (n=hEnvEnc->nBitstrDelay; n>0; n--)
1847     {
1848       for (el=0; el<hEnvEnc->noElements; el++)
1849       {
1850         if (FDKsbrEnc_EnvEncodeFrame(
1851                                      hEnvEnc,
1852                                      el,
1853                                      timeBuffer + hEnvEnc->downsampledOffset,
1854                                      hEnvEnc->sbrElement[el]->sbrConfigData.nChannels,
1855                                      NULL,
1856                                      NULL,
1857                                      1
1858                                     ))
1859           return -1;
1860       }
1861       sbrEncoder_UpdateBuffers(hEnvEnc, timeBuffer);
1862     }
1863 	  return 0;
1864 }
1865 
sbrEncoder_LimitBitRate(UINT bitRate,UINT numChannels,UINT coreSampleRate,AUDIO_OBJECT_TYPE aot)1866 UINT sbrEncoder_LimitBitRate(UINT bitRate, UINT numChannels, UINT coreSampleRate, AUDIO_OBJECT_TYPE aot)
1867 {
1868   UINT newBitRate;
1869   INT index;
1870 
1871   FDK_ASSERT(numChannels > 0 && numChannels <= 2);
1872   if (aot == AOT_PS) {
1873     if (numChannels == 2) {
1874       index = getPsTuningTableIndex(bitRate, &newBitRate);
1875       if (index == INVALID_TABLE_IDX) {
1876         bitRate = newBitRate;
1877       }
1878       /* Set numChannels to 1 because for PS we need a SBR SCE (mono) element. */
1879       numChannels = 1;
1880     } else {
1881       return 0;
1882     }
1883   }
1884   index = getSbrTuningTableIndex(bitRate, numChannels, coreSampleRate, aot, &newBitRate);
1885   if (index != INVALID_TABLE_IDX) {
1886     newBitRate = bitRate;
1887   }
1888 
1889   return newBitRate;
1890 }
1891 
sbrEncoder_IsSingleRatePossible(AUDIO_OBJECT_TYPE aot)1892 UINT sbrEncoder_IsSingleRatePossible(AUDIO_OBJECT_TYPE aot)
1893 {
1894   UINT isPossible=(AOT_PS==aot)?0:1;
1895   return isPossible;
1896 }
1897 
sbrEncoder_Init(HANDLE_SBR_ENCODER hSbrEncoder,SBR_ELEMENT_INFO elInfo[(8)],int noElements,INT_PCM * inputBuffer,INT * coreBandwidth,INT * inputBufferOffset,INT * numChannels,INT * coreSampleRate,UINT * downSampleFactor,INT * frameLength,AUDIO_OBJECT_TYPE aot,int * delay,int transformFactor,const int headerPeriod,ULONG statesInitFlag)1898 INT sbrEncoder_Init(
1899         HANDLE_SBR_ENCODER   hSbrEncoder,
1900         SBR_ELEMENT_INFO     elInfo[(8)],
1901         int                  noElements,
1902         INT_PCM             *inputBuffer,
1903         INT                 *coreBandwidth,
1904         INT                 *inputBufferOffset,
1905         INT                 *numChannels,
1906         INT                 *coreSampleRate,
1907         UINT                *downSampleFactor,
1908         INT                 *frameLength,
1909         AUDIO_OBJECT_TYPE    aot,
1910         int                 *delay,
1911         int                  transformFactor,
1912         const int            headerPeriod,
1913         ULONG                statesInitFlag
1914         )
1915 {
1916     HANDLE_ERROR_INFO errorInfo = noError;
1917     sbrConfiguration sbrConfig[(8)];
1918     INT error = 0;
1919     INT lowestBandwidth;
1920     /* Save input parameters */
1921     INT inputSampleRate = *coreSampleRate;
1922     int coreFrameLength = *frameLength;
1923     int inputBandWidth = *coreBandwidth;
1924     int inputChannels = *numChannels;
1925 
1926     int downsampledOffset = 0;
1927     int sbrOffset = 0;
1928     int downsamplerDelay = 0;
1929     int timeDomainDownsample = 0;
1930     int nBitstrDelay = 0;
1931     int highestSbrStartFreq, highestSbrStopFreq;
1932     int lowDelay = 0;
1933     int usePs = 0;
1934 
1935     /* check whether SBR setting is available for the current encoder configuration (bitrate, samplerate) */
1936     if (!sbrEncoder_IsSingleRatePossible(aot)) {
1937       *downSampleFactor = 2;
1938     }
1939 
1940 
1941 
1942     if ( (aot==AOT_PS) ) {
1943         usePs = 1;
1944     }
1945     if ( (aot==AOT_ER_AAC_ELD) ) {
1946         lowDelay = 1;
1947     }
1948     else if ( (aot==AOT_ER_AAC_LD) ) {
1949         error = 1;
1950         goto bail;
1951     }
1952 
1953     /* Parametric Stereo */
1954     if ( usePs ) {
1955       if ( *numChannels == 2 && noElements == 1) {
1956         /* Override Element type in case of Parametric stereo */
1957         elInfo[0].elType = ID_SCE;
1958         elInfo[0].fParametricStereo = 1;
1959         elInfo[0].nChannelsInEl = 1;
1960         /* core encoder gets downmixed mono signal */
1961         *numChannels  = 1;
1962       } else {
1963         error = 1;
1964         goto bail;
1965       }
1966     } /* usePs */
1967 
1968     /* set the core's sample rate */
1969     switch (*downSampleFactor) {
1970     case 1:
1971       *coreSampleRate = inputSampleRate;
1972       break;
1973     case 2:
1974       *coreSampleRate = inputSampleRate>>1;
1975       break;
1976     default:
1977       *coreSampleRate = inputSampleRate>>1;
1978       return 0; /* return error */
1979     }
1980 
1981     /* check whether SBR setting is available for the current encoder configuration (bitrate, coreSampleRate) */
1982     {
1983       int delayDiff = 0;
1984       int el, coreEl;
1985 
1986       /* Check if every element config is feasible */
1987       for (coreEl=0; coreEl<noElements; coreEl++)
1988       {
1989         /* SBR only handles SCE and CPE's */
1990         if (elInfo[coreEl].elType != ID_SCE && elInfo[coreEl].elType != ID_CPE) {
1991           continue;
1992         }
1993         /* check if desired configuration is available */
1994         if ( !FDKsbrEnc_IsSbrSettingAvail (elInfo[coreEl].bitRate, 0, elInfo[coreEl].nChannelsInEl, inputSampleRate, *coreSampleRate, aot) )
1995         {
1996             error = 1;
1997             goto bail;
1998         }
1999       }
2000 
2001       /* Determine Delay balancing and new encoder delay */
2002       if (lowDelay) {
2003         {
2004         delayDiff = (*delay * *downSampleFactor) + DELAY_ELD2SBR(coreFrameLength,*downSampleFactor);
2005         *delay = DELAY_ELDSBR(coreFrameLength,*downSampleFactor);
2006         }
2007       }
2008       else if (usePs) {
2009         delayDiff = (*delay * *downSampleFactor) + DELAY_AAC2PS(coreFrameLength,*downSampleFactor);
2010         *delay = DELAY_PS(coreFrameLength,*downSampleFactor);
2011       }
2012       else {
2013         delayDiff = DELAY_AAC2SBR(coreFrameLength,*downSampleFactor);
2014         delayDiff += (*delay * *downSampleFactor);
2015         *delay = DELAY_SBR(coreFrameLength,*downSampleFactor);
2016       }
2017 
2018       if (!usePs) {
2019           timeDomainDownsample = *downSampleFactor-1;  /* activate time domain downsampler when downSampleFactor is != 1 */
2020       }
2021 
2022 
2023       /* Take care about downsampled data bound to the SBR path */
2024       if (!timeDomainDownsample && delayDiff > 0) {
2025         /*
2026          * We must tweak the balancing into a situation where the downsampled path
2027          * is the one to be delayed, because delaying the QMF domain input, also delays
2028          * the downsampled audio, counteracting to the purpose of delay balancing.
2029          */
2030         while ( delayDiff > 0 )
2031         {
2032           /* Encoder delay increases */
2033           {
2034             *delay += coreFrameLength * *downSampleFactor;
2035             /* Add one frame delay to SBR path */
2036             delayDiff -= coreFrameLength * *downSampleFactor;
2037           }
2038           nBitstrDelay += 1;
2039         }
2040       } else
2041       {
2042         *delay += fixp_abs(delayDiff);
2043       }
2044 
2045       if (delayDiff < 0) {
2046         /* Delay AAC data */
2047         delayDiff = -delayDiff;
2048         /* Multiply downsampled offset by AAC core channels. Divide by 2 because of half samplerate of downsampled data. */
2049         FDK_ASSERT(*downSampleFactor>0 && *downSampleFactor<=2);
2050         downsampledOffset = (delayDiff*(*numChannels))>>(*downSampleFactor-1);
2051         sbrOffset = 0;
2052       } else {
2053         /* Delay SBR input */
2054         if ( delayDiff > (int)coreFrameLength * (int)*downSampleFactor )
2055         {
2056           /* Do bitstream frame-wise delay balancing if we have more than SBR framelength samples delay difference */
2057           delayDiff -= coreFrameLength * *downSampleFactor;
2058           nBitstrDelay = 1;
2059         }
2060         /* Multiply input offset by input channels */
2061         sbrOffset = delayDiff*(*numChannels);
2062         downsampledOffset = 0;
2063       }
2064       hSbrEncoder->nBitstrDelay            = nBitstrDelay;
2065       hSbrEncoder->nChannels               = *numChannels;
2066       hSbrEncoder->frameSize               = coreFrameLength * *downSampleFactor;
2067       hSbrEncoder->fTimeDomainDownsampling = timeDomainDownsample;
2068       hSbrEncoder->downSampleFactor        = *downSampleFactor;
2069       hSbrEncoder->estimateBitrate         = 0;
2070       hSbrEncoder->inputDataDelay          = 0;
2071 
2072 
2073       /* Open SBR elements */
2074       el = -1;
2075       highestSbrStartFreq = highestSbrStopFreq = 0;
2076       lowestBandwidth = 99999;
2077 
2078       /* Loop through each core encoder element and get a matching SBR element config */
2079       for (coreEl=0; coreEl<noElements; coreEl++)
2080       {
2081         /* SBR only handles SCE and CPE's */
2082         if (elInfo[coreEl].elType == ID_SCE || elInfo[coreEl].elType == ID_CPE) {
2083           el++;
2084         } else {
2085           continue;
2086         }
2087 
2088         /* Set parametric Stereo Flag. */
2089         if (usePs) {
2090           elInfo[coreEl].fParametricStereo = 1;
2091         } else {
2092           elInfo[coreEl].fParametricStereo = 0;
2093         }
2094 
2095         /*
2096          * Init sbrConfig structure
2097          */
2098         if ( ! FDKsbrEnc_InitializeSbrDefaults ( &sbrConfig[el],
2099                                                  *downSampleFactor,
2100                                                   coreFrameLength,
2101                                                   IS_LOWDELAY(aot)
2102                                                   ) )
2103         {
2104           error = 1;
2105           goto bail;
2106         }
2107 
2108         /*
2109          * Modify sbrConfig structure according to Element parameters
2110          */
2111         if ( ! FDKsbrEnc_AdjustSbrSettings (&sbrConfig[el],
2112                                              elInfo[coreEl].bitRate,
2113                                              elInfo[coreEl].nChannelsInEl,
2114                                             *coreSampleRate,
2115                                              inputSampleRate,
2116                                              transformFactor,
2117                                              24000,
2118                                              0,
2119                                              0,     /* useSpeechConfig */
2120                                              0,     /* lcsMode */
2121                                              usePs, /* bParametricStereo */
2122                                              aot) )
2123         {
2124           error = 1;
2125           goto bail;
2126         }
2127 
2128         /* Find common frequency border for all SBR elements */
2129         highestSbrStartFreq = fixMax(highestSbrStartFreq, sbrConfig[el].startFreq);
2130         highestSbrStopFreq = fixMax(highestSbrStopFreq, sbrConfig[el].stopFreq);
2131 
2132       } /* first element loop */
2133 
2134       /* Set element count (can be less than core encoder element count) */
2135       hSbrEncoder->noElements = el+1;
2136 
2137       FDKsbrEnc_Reallocate(hSbrEncoder,
2138                            elInfo,
2139                            noElements);
2140 
2141       for (el=0; el<hSbrEncoder->noElements; el++) {
2142 
2143         int bandwidth = *coreBandwidth;
2144 
2145         /* Use lowest common bandwidth */
2146         sbrConfig[el].startFreq = highestSbrStartFreq;
2147         sbrConfig[el].stopFreq = highestSbrStopFreq;
2148 
2149         /* initialize SBR element, and get core bandwidth */
2150         error = FDKsbrEnc_EnvInit(hSbrEncoder->sbrElement[el],
2151                                   &sbrConfig[el],
2152                                   &bandwidth,
2153                                    aot,
2154                                    nBitstrDelay,
2155                                    el,
2156                                    headerPeriod,
2157                                    statesInitFlag,
2158                                    hSbrEncoder->fTimeDomainDownsampling
2159                                   ,hSbrEncoder->dynamicRam
2160                                   );
2161 
2162         if (error != 0) {
2163           error = 2;
2164           goto bail;
2165         }
2166 
2167         /* Get lowest core encoder bandwidth to be returned later. */
2168         lowestBandwidth = fixMin(lowestBandwidth, bandwidth);
2169 
2170       } /* second element loop */
2171 
2172       /* Initialize a downsampler for each channel in each SBR element */
2173       if (hSbrEncoder->fTimeDomainDownsampling)
2174       {
2175         for (el=0; el<hSbrEncoder->noElements; el++)
2176         {
2177           HANDLE_SBR_ELEMENT hSbrEl = hSbrEncoder->sbrElement[el];
2178           INT Wc, ch;
2179 
2180           /* Calculated required normalized cutoff frequency (Wc = 1.0 -> lowestBandwidth = inputSampleRate/2) */
2181           Wc = (2*lowestBandwidth)*1000 / inputSampleRate;
2182 
2183           for (ch=0; ch<hSbrEl->elInfo.nChannelsInEl; ch++)
2184           {
2185             FDKaacEnc_InitDownsampler (&hSbrEl->sbrChannel[ch]->downSampler, Wc, *downSampleFactor);
2186             FDK_ASSERT (hSbrEl->sbrChannel[ch]->downSampler.delay <=MAX_DS_FILTER_DELAY);
2187           }
2188 
2189           downsamplerDelay = hSbrEl->sbrChannel[0]->downSampler.delay;
2190         } /* third element loop */
2191 
2192         /* lfe */
2193         FDKaacEnc_InitDownsampler (&hSbrEncoder->lfeDownSampler, 0, *downSampleFactor);
2194 
2195         /* Add the resampler additional delay to get the final delay and buffer offset values. */
2196         if (sbrOffset > 0 || downsampledOffset <= ((downsamplerDelay * (*numChannels))>>(*downSampleFactor-1))) {
2197           sbrOffset += (downsamplerDelay - downsampledOffset) * (*numChannels) ;
2198           *delay += downsamplerDelay - downsampledOffset;
2199           downsampledOffset = 0;
2200         } else {
2201           downsampledOffset -= (downsamplerDelay * (*numChannels))>>(*downSampleFactor-1);
2202           sbrOffset = 0;
2203         }
2204 
2205         hSbrEncoder->inputDataDelay = downsamplerDelay;
2206       }
2207 
2208       /* Assign core encoder Bandwidth */
2209       *coreBandwidth = lowestBandwidth;
2210 
2211       /* Estimate sbr bitrate, 2.5 kBit/s per sbr channel */
2212       hSbrEncoder->estimateBitrate += 2500 * (*numChannels);
2213 
2214       /* initialize parametric stereo */
2215       if (usePs)
2216       {
2217         PSENC_CONFIG psEncConfig;
2218         FDK_ASSERT(hSbrEncoder->noElements == 1);
2219         INT psTuningTableIdx = getPsTuningTableIndex(elInfo[0].bitRate, NULL);
2220 
2221         psEncConfig.frameSize           = coreFrameLength; //sbrConfig.sbrFrameSize;
2222         psEncConfig.qmfFilterMode       = 0;
2223         psEncConfig.sbrPsDelay          = 0;
2224 
2225         /* tuning parameters */
2226         if (psTuningTableIdx  != INVALID_TABLE_IDX) {
2227           psEncConfig.nStereoBands           = psTuningTable[psTuningTableIdx].nStereoBands;
2228           psEncConfig.maxEnvelopes           = psTuningTable[psTuningTableIdx].nEnvelopes;
2229           psEncConfig.iidQuantErrorThreshold = (FIXP_DBL)psTuningTable[psTuningTableIdx].iidQuantErrorThreshold;
2230 
2231           /* calculation is not quite linear, increased number of envelopes causes more bits */
2232           /* assume avg. 50 bits per frame for 10 stereo bands / 1 envelope configuration */
2233           hSbrEncoder->estimateBitrate += ( (((*coreSampleRate) * 5 * psEncConfig.nStereoBands * psEncConfig.maxEnvelopes) / hSbrEncoder->frameSize));
2234 
2235         } else {
2236           error = ERROR(CDI, "Invalid ps tuning table index.");
2237           goto bail;
2238         }
2239 
2240         qmfInitSynthesisFilterBank(&hSbrEncoder->qmfSynthesisPS,
2241                                     (FIXP_DBL*)hSbrEncoder->qmfSynthesisPS.FilterStates,
2242                                     hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfSlots,
2243                                     hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfBands>>1,
2244                                     hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfBands>>1,
2245                                     hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfBands>>1,
2246                                     (statesInitFlag) ? 0 : QMF_FLAG_KEEP_STATES);
2247 
2248         if(errorInfo == noError){
2249           /* update delay */
2250           psEncConfig.sbrPsDelay = FDKsbrEnc_GetEnvEstDelay(&hSbrEncoder->sbrElement[0]->sbrChannel[0]->hEnvChannel.sbrExtractEnvelope);
2251 
2252           if(noError != (errorInfo = PSEnc_Init( hSbrEncoder->hParametricStereo,
2253                                                 &psEncConfig,
2254                                                  hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfSlots,
2255                                                  hSbrEncoder->sbrElement[0]->sbrConfigData.noQmfBands
2256                                                 ,hSbrEncoder->dynamicRam
2257                                                  )))
2258           {
2259             errorInfo = handBack(errorInfo);
2260           }
2261         }
2262 
2263         /* QMF analysis + Hybrid analysis + Hybrid synthesis + QMF synthesis + downsampled input buffer delay */
2264         hSbrEncoder->inputDataDelay = (64*10/2) + (6*64) +  (0) + (64*10/2-64+1) + ((*downSampleFactor)*downsampledOffset);
2265       }
2266 
2267       hSbrEncoder->downsampledOffset = downsampledOffset;
2268       {
2269         hSbrEncoder->downmixSize = coreFrameLength*(*numChannels);
2270       }
2271 
2272       hSbrEncoder->bufferOffset = sbrOffset;
2273       /* Delay Compensation: fill bitstream delay buffer with zero input signal */
2274       if ( hSbrEncoder->nBitstrDelay > 0 )
2275       {
2276         error = FDKsbrEnc_DelayCompensation (hSbrEncoder, inputBuffer);
2277         if (error != 0)
2278           goto bail;
2279       }
2280 
2281       /* Set Output frame length */
2282       *frameLength = coreFrameLength * *downSampleFactor;
2283       /* Input buffer offset */
2284       *inputBufferOffset = fixMax(sbrOffset, downsampledOffset);
2285 
2286 
2287     }
2288 
2289     return error;
2290 
2291 bail:
2292     /* Restore input settings */
2293     *coreSampleRate = inputSampleRate;
2294     *frameLength = coreFrameLength;
2295     *numChannels = inputChannels;
2296     *coreBandwidth = inputBandWidth;
2297 
2298     return error;
2299  }
2300 
2301 
2302 INT
sbrEncoder_EncodeFrame(HANDLE_SBR_ENCODER hSbrEncoder,INT_PCM * samples,UINT timeInStride,UINT sbrDataBits[(8)],UCHAR sbrData[(8)][MAX_PAYLOAD_SIZE])2303 sbrEncoder_EncodeFrame(  HANDLE_SBR_ENCODER   hSbrEncoder,
2304                          INT_PCM             *samples,
2305                          UINT                 timeInStride,
2306                          UINT                 sbrDataBits[(8)],
2307                          UCHAR                sbrData[(8)][MAX_PAYLOAD_SIZE]
2308                         )
2309 {
2310   INT error;
2311   int el;
2312 
2313   for (el=0; el<hSbrEncoder->noElements; el++)
2314   {
2315     if (hSbrEncoder->sbrElement[el] != NULL)
2316     {
2317       error = FDKsbrEnc_EnvEncodeFrame(
2318                                         hSbrEncoder,
2319                                         el,
2320                                         samples + hSbrEncoder->downsampledOffset,
2321                                         timeInStride,
2322                                        &sbrDataBits[el],
2323                                         sbrData[el],
2324                                         0
2325                                        );
2326       if (error)
2327         return error;
2328     }
2329   }
2330 
2331   if ( ( hSbrEncoder->lfeChIdx!=-1) && (hSbrEncoder->downSampleFactor > 1) )
2332   {   /* lfe downsampler */
2333       INT nOutSamples;
2334 
2335       FDKaacEnc_Downsample(&hSbrEncoder->lfeDownSampler,
2336                             samples + hSbrEncoder->downsampledOffset + hSbrEncoder->bufferOffset + hSbrEncoder->lfeChIdx,
2337                             hSbrEncoder->frameSize,
2338                             timeInStride,
2339                             samples + hSbrEncoder->downsampledOffset + hSbrEncoder->lfeChIdx,
2340                            &nOutSamples,
2341                             hSbrEncoder->nChannels);
2342 
2343 
2344   }
2345 
2346   return 0;
2347 }
2348 
2349 
sbrEncoder_UpdateBuffers(HANDLE_SBR_ENCODER hSbrEncoder,INT_PCM * timeBuffer)2350 INT sbrEncoder_UpdateBuffers(
2351                             HANDLE_SBR_ENCODER hSbrEncoder,
2352                             INT_PCM *timeBuffer
2353                             )
2354  {
2355     if ( hSbrEncoder->downsampledOffset > 0 ) {
2356       /* Move delayed downsampled data */
2357       FDKmemcpy ( timeBuffer,
2358                   timeBuffer + hSbrEncoder->downmixSize,
2359                   sizeof(INT_PCM) * (hSbrEncoder->downsampledOffset) );
2360     } else {
2361       /* Move delayed input data */
2362       FDKmemcpy ( timeBuffer,
2363         timeBuffer + hSbrEncoder->nChannels * hSbrEncoder->frameSize,
2364                   sizeof(INT_PCM) * hSbrEncoder->bufferOffset );
2365     }
2366     if ( hSbrEncoder->nBitstrDelay > 0  )
2367     {
2368       int el;
2369 
2370       for (el=0; el<hSbrEncoder->noElements; el++)
2371       {
2372         FDKmemmove ( hSbrEncoder->sbrElement[el]->payloadDelayLine[0],
2373                      hSbrEncoder->sbrElement[el]->payloadDelayLine[1],
2374                      sizeof(UCHAR) * (hSbrEncoder->nBitstrDelay*MAX_PAYLOAD_SIZE) );
2375 
2376         FDKmemmove( &hSbrEncoder->sbrElement[el]->payloadDelayLineSize[0],
2377                     &hSbrEncoder->sbrElement[el]->payloadDelayLineSize[1],
2378                     sizeof(UINT) * (hSbrEncoder->nBitstrDelay) );
2379       }
2380     }
2381     return 0;
2382  }
2383 
2384 
sbrEncoder_GetEstimateBitrate(HANDLE_SBR_ENCODER hSbrEncoder)2385 INT sbrEncoder_GetEstimateBitrate(HANDLE_SBR_ENCODER hSbrEncoder)
2386 {
2387   INT estimateBitrate = 0;
2388 
2389   if(hSbrEncoder) {
2390     estimateBitrate += hSbrEncoder->estimateBitrate;
2391   }
2392 
2393   return estimateBitrate;
2394 }
2395 
sbrEncoder_GetInputDataDelay(HANDLE_SBR_ENCODER hSbrEncoder)2396 INT sbrEncoder_GetInputDataDelay(HANDLE_SBR_ENCODER hSbrEncoder)
2397 {
2398   INT delay = -1;
2399 
2400   if(hSbrEncoder) {
2401     delay = hSbrEncoder->inputDataDelay;
2402   }
2403   return delay;
2404 }
2405 
2406 
sbrEncoder_GetLibInfo(LIB_INFO * info)2407 INT sbrEncoder_GetLibInfo( LIB_INFO *info )
2408 {
2409   int i;
2410 
2411   if (info == NULL) {
2412     return -1;
2413   }
2414   /* search for next free tab */
2415   for (i = 0; i < FDK_MODULE_LAST; i++) {
2416     if (info[i].module_id == FDK_NONE) break;
2417   }
2418   if (i == FDK_MODULE_LAST) {
2419     return -1;
2420   }
2421   info += i;
2422 
2423   info->module_id = FDK_SBRENC;
2424   info->version = LIB_VERSION(SBRENCODER_LIB_VL0, SBRENCODER_LIB_VL1, SBRENCODER_LIB_VL2);
2425   LIB_VERSION_STRING(info);
2426 #ifdef __ANDROID__
2427   info->build_date = "";
2428   info->build_time = "";
2429 #else
2430   info->build_date = __DATE__;
2431   info->build_time = __TIME__;
2432 #endif
2433   info->title = "SBR Encoder";
2434 
2435   /* Set flags */
2436   info->flags = 0
2437     | CAPF_SBR_HQ
2438     | CAPF_SBR_PS_MPEG
2439     ;
2440   /* End of flags */
2441 
2442   return 0;
2443 }
2444