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 /*!
85   \file
86   \brief  Sbr decoder
87   This module provides the actual decoder implementation. The SBR data (side information) is already
88   decoded. Only three functions are provided:
89 
90   \li 1.) createSbrDec(): One time initialization
91   \li 2.) resetSbrDec(): Called by sbr_Apply() when the information contained in an SBR_HEADER_ELEMENT requires a reset
92   and recalculation of important SBR structures.
93   \li 3.) sbr_dec(): The actual decoder. Calls the different tools such as filterbanks, lppTransposer(), and calculateSbrEnvelope()
94   [the envelope adjuster].
95 
96   \sa sbr_dec(), \ref documentationOverview
97 */
98 
99 #include "sbr_dec.h"
100 
101 #include "sbr_ram.h"
102 #include "env_extr.h"
103 #include "env_calc.h"
104 #include "scale.h"
105 
106 #include "genericStds.h"
107 
108 #include "sbrdec_drc.h"
109 
110 
111 
assignLcTimeSlots(HANDLE_SBR_DEC hSbrDec,FIXP_DBL ** QmfBufferReal,int noCols)112 static void assignLcTimeSlots( HANDLE_SBR_DEC hSbrDec,                     /*!< handle to Decoder channel */
113                                FIXP_DBL  **QmfBufferReal,
114                                int noCols )
115 {
116   int slot, i;
117   FIXP_DBL  *ptr;
118 
119   /* Number of QMF timeslots in the overlap buffer: */
120   ptr = hSbrDec->pSbrOverlapBuffer;
121   for(slot=0; slot<hSbrDec->LppTrans.pSettings->overlap; slot++) {
122     QmfBufferReal[slot] = ptr; ptr += (64);
123   }
124 
125   /* Assign timeslots to Workbuffer1 */
126   ptr = hSbrDec->WorkBuffer1;
127   for(i=0; i<noCols; i++) {
128     QmfBufferReal[slot] = ptr; ptr += (64);
129     slot++;
130   }
131 }
132 
133 
assignHqTimeSlots(HANDLE_SBR_DEC hSbrDec,FIXP_DBL ** QmfBufferReal,FIXP_DBL ** QmfBufferImag,int noCols)134 static void assignHqTimeSlots( HANDLE_SBR_DEC hSbrDec,                     /*!< handle to Decoder channel */
135                                FIXP_DBL  **QmfBufferReal,
136                                FIXP_DBL  **QmfBufferImag,
137                                int noCols )
138 {
139   FIXP_DBL  *ptr;
140   int slot;
141 
142   /* Number of QMF timeslots in one half of a frame (size of Workbuffer1 or 2): */
143   int halflen = (noCols >> 1) + hSbrDec->LppTrans.pSettings->overlap;
144   int totCols = noCols + hSbrDec->LppTrans.pSettings->overlap;
145 
146   /* Number of QMF timeslots in the overlap buffer: */
147   ptr = hSbrDec->pSbrOverlapBuffer;
148   for(slot=0; slot<hSbrDec->LppTrans.pSettings->overlap; slot++) {
149     QmfBufferReal[slot] = ptr; ptr += (64);
150     QmfBufferImag[slot] = ptr; ptr += (64);
151   }
152 
153   /* Assign first half of timeslots to Workbuffer1 */
154   ptr = hSbrDec->WorkBuffer1;
155   for(; slot<halflen; slot++) {
156     QmfBufferReal[slot] = ptr; ptr += (64);
157     QmfBufferImag[slot] = ptr; ptr += (64);
158   }
159 
160   /* Assign second half of timeslots to Workbuffer2 */
161   ptr = hSbrDec->WorkBuffer2;
162   for(; slot<totCols; slot++) {
163     QmfBufferReal[slot] = ptr; ptr += (64);
164     QmfBufferImag[slot] = ptr; ptr += (64);
165   }
166 }
167 
168 
assignTimeSlots(HANDLE_SBR_DEC hSbrDec,int noCols,int useLP)169 static void assignTimeSlots( HANDLE_SBR_DEC hSbrDec,                     /*!< handle to Decoder channel */
170                              int noCols,
171                              int useLP )
172 {
173  /* assign qmf time slots */
174   hSbrDec->useLP = useLP;
175   if (useLP) {
176     hSbrDec->SynthesisQMF.flags |= QMF_FLAG_LP;
177     hSbrDec->AnalysiscQMF.flags |= QMF_FLAG_LP;
178   } else {
179     hSbrDec->SynthesisQMF.flags &= ~QMF_FLAG_LP;
180     hSbrDec->AnalysiscQMF.flags &= ~QMF_FLAG_LP;
181   }
182   if (!useLP)
183     assignHqTimeSlots( hSbrDec, hSbrDec->QmfBufferReal, hSbrDec->QmfBufferImag, noCols );
184   else
185   {
186     assignLcTimeSlots( hSbrDec, hSbrDec->QmfBufferReal, noCols );
187   }
188 }
189 
changeQmfType(HANDLE_SBR_DEC hSbrDec,int useLdTimeAlign)190 static void changeQmfType( HANDLE_SBR_DEC hSbrDec,                     /*!< handle to Decoder channel */
191                            int useLdTimeAlign )
192 {
193   UINT synQmfFlags = hSbrDec->SynthesisQMF.flags;
194   UINT anaQmfFlags = hSbrDec->AnalysiscQMF.flags;
195   int  resetSynQmf = 0;
196   int  resetAnaQmf = 0;
197 
198   /* assign qmf type */
199   if (useLdTimeAlign) {
200     if (synQmfFlags & QMF_FLAG_CLDFB) {
201       /* change the type to MPSLD */
202       synQmfFlags &= ~QMF_FLAG_CLDFB;
203       synQmfFlags |=  QMF_FLAG_MPSLDFB;
204       resetSynQmf = 1;
205     }
206     if (anaQmfFlags & QMF_FLAG_CLDFB) {
207       /* change the type to MPSLD */
208       anaQmfFlags &= ~QMF_FLAG_CLDFB;
209       anaQmfFlags |=  QMF_FLAG_MPSLDFB;
210       resetAnaQmf = 1;
211     }
212   } else {
213     if (synQmfFlags & QMF_FLAG_MPSLDFB) {
214       /* change the type to CLDFB */
215       synQmfFlags &= ~QMF_FLAG_MPSLDFB;
216       synQmfFlags |=  QMF_FLAG_CLDFB;
217       resetSynQmf = 1;
218     }
219     if (anaQmfFlags & QMF_FLAG_MPSLDFB) {
220       /* change the type to CLDFB */
221       anaQmfFlags &= ~QMF_FLAG_MPSLDFB;
222       anaQmfFlags |=  QMF_FLAG_CLDFB;
223       resetAnaQmf = 1;
224     }
225   }
226 
227   if (resetAnaQmf) {
228     QMF_FILTER_BANK prvAnaQmf;
229     int  qmfErr;
230 
231     /* Store current configuration */
232     FDKmemcpy(&prvAnaQmf, &hSbrDec->AnalysiscQMF, sizeof(QMF_FILTER_BANK));
233 
234     /* Reset analysis QMF */
235     qmfErr = qmfInitAnalysisFilterBank (
236            &hSbrDec->AnalysiscQMF,
237             hSbrDec->anaQmfStates,
238             hSbrDec->AnalysiscQMF.no_col,
239             hSbrDec->AnalysiscQMF.lsb,
240             hSbrDec->AnalysiscQMF.usb,
241             hSbrDec->AnalysiscQMF.no_channels,
242             anaQmfFlags | QMF_FLAG_KEEP_STATES
243             );
244 
245     if (qmfErr != 0) {
246       /* Restore old configuration of analysis QMF */
247       FDKmemcpy(&hSbrDec->AnalysiscQMF, &prvAnaQmf, sizeof(QMF_FILTER_BANK));
248     }
249   }
250 
251   if (resetSynQmf) {
252     QMF_FILTER_BANK prvSynQmf;
253     int  qmfErr;
254 
255     /* Store current configuration */
256     FDKmemcpy(&prvSynQmf, &hSbrDec->SynthesisQMF, sizeof(QMF_FILTER_BANK));
257 
258     /* Reset synthesis QMF */
259     qmfErr = qmfInitSynthesisFilterBank (
260            &hSbrDec->SynthesisQMF,
261             hSbrDec->pSynQmfStates,
262             hSbrDec->SynthesisQMF.no_col,
263             hSbrDec->SynthesisQMF.lsb,
264             hSbrDec->SynthesisQMF.usb,
265             hSbrDec->SynthesisQMF.no_channels,
266             synQmfFlags | QMF_FLAG_KEEP_STATES
267             );
268 
269     if (qmfErr != 0) {
270       /* Restore old configuration of synthesis QMF */
271       FDKmemcpy(&hSbrDec->SynthesisQMF, &prvSynQmf, sizeof(QMF_FILTER_BANK));
272     }
273   }
274 }
275 
276 
277 /*!
278   \brief      SBR decoder core function for one channel
279 
280   \image html  BufferMgmtDetailed-1632.png
281 
282   Besides the filter states of the QMF filter bank and the LPC-states of
283   the LPP-Transposer, processing is mainly based on four buffers:
284   #timeIn, #timeOut, #WorkBuffer2 and #OverlapBuffer. The #WorkBuffer2
285   is reused for all channels and might be used by the core decoder, a
286   static overlap buffer is required for each channel. Du to in-place
287   processing, #timeIn and #timeOut point to identical locations.
288 
289   The spectral data is organized in so-called slots, each slot
290   containing 64 bands of complex data. The number of slots per frame is
291   dependend on the frame size. For mp3PRO, there are 18 slots per frame
292   and 6 slots per #OverlapBuffer. It is not necessary to have the slots
293   in located consecutive address ranges.
294 
295   To optimize memory usage and to minimize the number of memory
296   accesses, the memory management is organized as follows (Slot numbers
297   based on mp3PRO):
298 
299   1.) Input time domain signal is located in #timeIn, the last slots
300   (0..5) of the spectral data of the previous frame are located in the
301   #OverlapBuffer. In addition, #frameData of the current frame resides
302   in the upper part of #timeIn.
303 
304   2.) During the cplxAnalysisQmfFiltering(), 32 samples from #timeIn are transformed
305   into a slot of up to 32 complex spectral low band values at a
306   time. The first spectral slot -- nr. 6 -- is written at slot number
307   zero of #WorkBuffer2. #WorkBuffer2 will be completely filled with
308   spectral data.
309 
310   3.) LPP-Transposition in lppTransposer() is processed on 24 slots. During the
311   transposition, the high band part of the spectral data is replicated
312   based on the low band data.
313 
314   Envelope Adjustment is processed on the high band part of the spectral
315   data only by calculateSbrEnvelope().
316 
317   4.) The cplxSynthesisQmfFiltering() creates 64 time domain samples out
318   of a slot of 64 complex spectral values at a time. The first 6 slots
319   in #timeOut are filled from the results of spectral slots 0..5 in the
320   #OverlapBuffer. The consecutive slots in timeOut are now filled with
321   the results of spectral slots 6..17.
322 
323   5.) The preprocessed slots 18..23 have to be stored in the
324   #OverlapBuffer.
325 
326 */
327 
328 void
sbr_dec(HANDLE_SBR_DEC hSbrDec,INT_PCM * timeIn,INT_PCM * timeOut,HANDLE_SBR_DEC hSbrDecRight,INT_PCM * timeOutRight,const int strideIn,const int strideOut,HANDLE_SBR_HEADER_DATA hHeaderData,HANDLE_SBR_FRAME_DATA hFrameData,HANDLE_SBR_PREV_FRAME_DATA hPrevFrameData,const int applyProcessing,HANDLE_PS_DEC h_ps_d,const UINT flags,const int codecFrameSize)329 sbr_dec ( HANDLE_SBR_DEC hSbrDec,            /*!< handle to Decoder channel */
330           INT_PCM *timeIn,                   /*!< pointer to input time signal */
331           INT_PCM *timeOut,                  /*!< pointer to output time signal */
332           HANDLE_SBR_DEC hSbrDecRight,       /*!< handle to Decoder channel right */
333           INT_PCM *timeOutRight,             /*!< pointer to output time signal */
334           const int strideIn,                /*!< Time data traversal strideIn */
335           const int strideOut,               /*!< Time data traversal strideOut */
336           HANDLE_SBR_HEADER_DATA hHeaderData,/*!< Static control data */
337           HANDLE_SBR_FRAME_DATA hFrameData,  /*!< Control data of current frame */
338           HANDLE_SBR_PREV_FRAME_DATA hPrevFrameData,  /*!< Some control data of last frame */
339           const int applyProcessing,         /*!< Flag for SBR operation */
340           HANDLE_PS_DEC h_ps_d,
341           const UINT flags,
342           const int codecFrameSize
343          )
344 {
345   int i, slot, reserve;
346   int saveLbScale;
347   int ov_len;
348   int lastSlotOffs;
349   FIXP_DBL maxVal;
350 
351   /* 1+1/3 frames of spectral data: */
352   FIXP_DBL **QmfBufferReal = hSbrDec->QmfBufferReal;
353   FIXP_DBL **QmfBufferImag = hSbrDec->QmfBufferImag;
354 
355  /* Number of QMF timeslots in the overlap buffer: */
356  ov_len = hSbrDec->LppTrans.pSettings->overlap;
357 
358  /* Number of QMF slots per frame */
359   int noCols = hHeaderData->numberTimeSlots * hHeaderData->timeStep;
360 
361  /* assign qmf time slots */
362   if ( ((flags & SBRDEC_LOW_POWER ) ? 1 : 0) != ((hSbrDec->SynthesisQMF.flags & QMF_FLAG_LP) ? 1 : 0) ) {
363     assignTimeSlots( hSbrDec, hHeaderData->numberTimeSlots * hHeaderData->timeStep, flags & SBRDEC_LOW_POWER);
364   }
365 
366   if (flags & SBRDEC_ELD_GRID) {
367     /* Choose the right low delay filter bank */
368     changeQmfType( hSbrDec, (flags & SBRDEC_LD_MPS_QMF) ? 1 : 0 );
369 
370     /* If the LD-MPS QMF is not available delay the signal by (96-48*ldSbrSamplingRate)
371      * samples according to ISO/IEC 14496-3:2009/FDAM 2:2010(E) chapter 4.5.2.13. */
372     if ( (flags & SBRDEC_LD_MPS_QMF)
373       && (hSbrDec->AnalysiscQMF.flags & QMF_FLAG_CLDFB) )
374     {
375       INT_PCM *pDlyBuf = hSbrDec->coreDelayBuf;  /* DLYBUF */
376       int smpl, delay = 96 >> (!(flags & SBRDEC_DOWNSAMPLE) ? 1 : 0);
377       /* Create TMPBUF */
378       C_AALLOC_SCRATCH_START(pcmTemp, INT_PCM, (96));
379       /* Copy delay samples from INBUF to TMPBUF */
380       for (smpl = 0; smpl < delay; smpl += 1) {
381         pcmTemp[smpl] = timeIn[(codecFrameSize-delay+smpl)*strideIn];
382       }
383       /* Move input signal remainder to the very end of INBUF */
384       for (smpl = (codecFrameSize-delay-1)*strideIn; smpl >= 0; smpl -= strideIn) {
385         timeIn[smpl+delay] = timeIn[smpl];
386       }
387       /* Copy delayed samples from last frame from DLYBUF to the very beginning of INBUF */
388       for (smpl = 0; smpl < delay; smpl += 1) {
389         timeIn[smpl*strideIn] = pDlyBuf[smpl];
390       }
391       /* Copy TMPBUF to DLYBUF */
392       FDKmemcpy(pDlyBuf, pcmTemp, delay*sizeof(INT_PCM));
393       /* Destory TMPBUF */
394       C_AALLOC_SCRATCH_END(pcmTemp, INT_PCM, (96));
395     }
396   }
397 
398   /*
399     low band codec signal subband filtering
400    */
401 
402   {
403     C_AALLOC_SCRATCH_START(qmfTemp, FIXP_DBL, 2*(64));
404 
405     qmfAnalysisFiltering( &hSbrDec->AnalysiscQMF,
406                            QmfBufferReal + ov_len,
407                            QmfBufferImag + ov_len,
408                           &hSbrDec->sbrScaleFactor,
409                            timeIn,
410                            strideIn,
411                            qmfTemp
412                          );
413 
414     C_AALLOC_SCRATCH_END(qmfTemp, FIXP_DBL, 2*(64));
415   }
416 
417   /*
418     Clear upper half of spectrum
419   */
420   {
421     int nAnalysisBands = hHeaderData->numberOfAnalysisBands;
422 
423     if (! (flags & SBRDEC_LOW_POWER)) {
424       for (slot = ov_len; slot < noCols+ov_len; slot++) {
425         FDKmemclear(&QmfBufferReal[slot][nAnalysisBands],((64)-nAnalysisBands)*sizeof(FIXP_DBL));
426         FDKmemclear(&QmfBufferImag[slot][nAnalysisBands],((64)-nAnalysisBands)*sizeof(FIXP_DBL));
427       }
428     } else
429     for (slot = ov_len; slot < noCols+ov_len; slot++) {
430       FDKmemclear(&QmfBufferReal[slot][nAnalysisBands],((64)-nAnalysisBands)*sizeof(FIXP_DBL));
431     }
432   }
433 
434 
435 
436   /*
437     Shift spectral data left to gain accuracy in transposer and adjustor
438   */
439   maxVal = maxSubbandSample( QmfBufferReal,
440                             (flags & SBRDEC_LOW_POWER) ? NULL : QmfBufferImag,
441                              0,
442                              hSbrDec->AnalysiscQMF.lsb,
443                              ov_len,
444                              noCols+ov_len );
445 
446   reserve = fixMax(0,CntLeadingZeros(maxVal)-1) ;
447   reserve = fixMin(reserve,DFRACT_BITS-1-hSbrDec->sbrScaleFactor.lb_scale);
448 
449   /* If all data is zero, lb_scale could become too large */
450   rescaleSubbandSamples( QmfBufferReal,
451                          (flags & SBRDEC_LOW_POWER) ? NULL : QmfBufferImag,
452                          0,
453                          hSbrDec->AnalysiscQMF.lsb,
454                          ov_len,
455                          noCols+ov_len,
456                          reserve);
457 
458   hSbrDec->sbrScaleFactor.lb_scale += reserve;
459 
460   /*
461     save low band scale, wavecoding or parametric stereo may modify it
462   */
463   saveLbScale = hSbrDec->sbrScaleFactor.lb_scale;
464 
465 
466   if (applyProcessing)
467   {
468     UCHAR * borders = hFrameData->frameInfo.borders;
469     lastSlotOffs =  borders[hFrameData->frameInfo.nEnvelopes] - hHeaderData->numberTimeSlots;
470 
471     FIXP_DBL degreeAlias[(64)];
472 
473     /* The transposer will override most values in degreeAlias[].
474        The array needs to be cleared at least from lowSubband to highSubband before. */
475     if (flags & SBRDEC_LOW_POWER)
476       FDKmemclear(&degreeAlias[hHeaderData->freqBandData.lowSubband], (hHeaderData->freqBandData.highSubband-hHeaderData->freqBandData.lowSubband)*sizeof(FIXP_DBL));
477 
478     /*
479       Inverse filtering of lowband and transposition into the SBR-frequency range
480     */
481 
482     lppTransposer ( &hSbrDec->LppTrans,
483                     &hSbrDec->sbrScaleFactor,
484                     QmfBufferReal,
485                     degreeAlias,                  // only used if useLP = 1
486                     QmfBufferImag,
487                     flags & SBRDEC_LOW_POWER,
488                     hHeaderData->timeStep,
489                     borders[0],
490                     lastSlotOffs,
491                     hHeaderData->freqBandData.nInvfBands,
492                     hFrameData->sbr_invf_mode,
493                     hPrevFrameData->sbr_invf_mode );
494 
495 
496 
497 
498 
499     /*
500       Adjust envelope of current frame.
501     */
502 
503     calculateSbrEnvelope (&hSbrDec->sbrScaleFactor,
504                           &hSbrDec->SbrCalculateEnvelope,
505                           hHeaderData,
506                           hFrameData,
507                           QmfBufferReal,
508                           QmfBufferImag,
509                           flags & SBRDEC_LOW_POWER,
510 
511                           degreeAlias,
512                           flags,
513                           (hHeaderData->frameErrorFlag || hPrevFrameData->frameErrorFlag));
514 
515 
516     /*
517       Update hPrevFrameData (to be used in the next frame)
518     */
519     for (i=0; i<hHeaderData->freqBandData.nInvfBands; i++) {
520       hPrevFrameData->sbr_invf_mode[i] = hFrameData->sbr_invf_mode[i];
521     }
522     hPrevFrameData->coupling = hFrameData->coupling;
523     hPrevFrameData->stopPos = borders[hFrameData->frameInfo.nEnvelopes];
524     hPrevFrameData->ampRes = hFrameData->ampResolutionCurrentFrame;
525   }
526   else {
527     /* Reset hb_scale if no highband is present, because hb_scale is considered in the QMF-synthesis */
528     hSbrDec->sbrScaleFactor.hb_scale = saveLbScale;
529   }
530 
531 
532   for (i=0; i<LPC_ORDER; i++){
533     /*
534       Store the unmodified qmf Slots values (required for LPC filtering)
535     */
536     if (! (flags & SBRDEC_LOW_POWER)) {
537       FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesReal[i], QmfBufferReal[noCols-LPC_ORDER+i], hSbrDec->AnalysiscQMF.lsb*sizeof(FIXP_DBL));
538       FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesImag[i], QmfBufferImag[noCols-LPC_ORDER+i], hSbrDec->AnalysiscQMF.lsb*sizeof(FIXP_DBL));
539     } else
540     FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesReal[i], QmfBufferReal[noCols-LPC_ORDER+i], hSbrDec->AnalysiscQMF.lsb*sizeof(FIXP_DBL));
541   }
542 
543   /*
544     Synthesis subband filtering.
545   */
546 
547   if ( ! (flags & SBRDEC_PS_DECODED) ) {
548 
549     {
550       int outScalefactor = 0;
551 
552       if (h_ps_d != NULL) {
553         h_ps_d->procFrameBased = 1;  /* we here do frame based processing */
554       }
555 
556 
557       sbrDecoder_drcApply(&hSbrDec->sbrDrcChannel,
558                            QmfBufferReal,
559                            (flags & SBRDEC_LOW_POWER) ? NULL : QmfBufferImag,
560                            hSbrDec->SynthesisQMF.no_col,
561                           &outScalefactor
562                           );
563 
564 
565 
566       qmfChangeOutScalefactor(&hSbrDec->SynthesisQMF, outScalefactor );
567 
568       {
569         C_AALLOC_SCRATCH_START(qmfTemp, FIXP_DBL, 2*(64));
570 
571         qmfSynthesisFiltering( &hSbrDec->SynthesisQMF,
572                                 QmfBufferReal,
573                                 (flags & SBRDEC_LOW_POWER) ? NULL : QmfBufferImag,
574                                &hSbrDec->sbrScaleFactor,
575                                 hSbrDec->LppTrans.pSettings->overlap,
576                                 timeOut,
577                                 strideOut,
578                                 qmfTemp);
579 
580         C_AALLOC_SCRATCH_END(qmfTemp, FIXP_DBL, 2*(64));
581       }
582 
583     }
584 
585   } else { /* (flags & SBRDEC_PS_DECODED) */
586     INT i, sdiff, outScalefactor, scaleFactorLowBand, scaleFactorHighBand;
587     SCHAR scaleFactorLowBand_ov, scaleFactorLowBand_no_ov;
588 
589     HANDLE_QMF_FILTER_BANK synQmf      = &hSbrDec->SynthesisQMF;
590     HANDLE_QMF_FILTER_BANK synQmfRight = &hSbrDecRight->SynthesisQMF;
591 
592     /* adapt scaling */
593     sdiff = hSbrDec->sbrScaleFactor.lb_scale - reserve;                  /* Scaling difference         */
594     scaleFactorHighBand   = sdiff - hSbrDec->sbrScaleFactor.hb_scale;    /* Scale of current high band */
595     scaleFactorLowBand_ov = sdiff - hSbrDec->sbrScaleFactor.ov_lb_scale; /* Scale of low band overlapping QMF data */
596     scaleFactorLowBand_no_ov = sdiff - hSbrDec->sbrScaleFactor.lb_scale; /* Scale of low band current QMF data     */
597     outScalefactor  = 0;                                                 /* Initial output scale */
598 
599     if (h_ps_d->procFrameBased == 1)    /* If we have switched from frame to slot based processing copy filter states */
600     { /* procFrameBased will be unset later */
601       /* copy filter states from left to right */
602       FDKmemcpy(synQmfRight->FilterStates, synQmf->FilterStates, ((640)-(64))*sizeof(FIXP_QSS));
603     }
604 
605     /* scale ALL qmf vales ( real and imag ) of mono / left channel to the
606        same scale factor ( ov_lb_sf, lb_sf and hq_sf )                      */
607     scalFilterBankValues( h_ps_d,                             /* parametric stereo decoder handle     */
608                           QmfBufferReal,                      /* qmf filterbank values                */
609                           QmfBufferImag,                      /* qmf filterbank values                */
610                           synQmf->lsb,                        /* sbr start subband                    */
611                           hSbrDec->sbrScaleFactor.ov_lb_scale,
612                           hSbrDec->sbrScaleFactor.lb_scale,
613                          &scaleFactorLowBand_ov,              /* adapt scaling values */
614                          &scaleFactorLowBand_no_ov,           /* adapt scaling values */
615                           hSbrDec->sbrScaleFactor.hb_scale,   /* current frame ( highband ) */
616                          &scaleFactorHighBand,
617                           synQmf->no_col);
618 
619     /* use the same synthese qmf values for left and right channel */
620     synQmfRight->no_col = synQmf->no_col;
621     synQmfRight->lsb    = synQmf->lsb;
622     synQmfRight->usb    = synQmf->usb;
623 
624     int env=0;
625 
626       outScalefactor += (SCAL_HEADROOM+1); /* psDiffScale! */
627 
628     {
629       C_AALLOC_SCRATCH_START(pWorkBuffer, FIXP_DBL, 2*(64));
630 
631       int maxShift = 0;
632 
633       if (hSbrDec->sbrDrcChannel.enable != 0) {
634         if (hSbrDec->sbrDrcChannel.prevFact_exp > maxShift) {
635           maxShift = hSbrDec->sbrDrcChannel.prevFact_exp;
636         }
637         if (hSbrDec->sbrDrcChannel.currFact_exp > maxShift) {
638           maxShift = hSbrDec->sbrDrcChannel.currFact_exp;
639         }
640         if (hSbrDec->sbrDrcChannel.nextFact_exp > maxShift) {
641           maxShift = hSbrDec->sbrDrcChannel.nextFact_exp;
642         }
643       }
644 
645       /* copy DRC data to right channel (with PS both channels use the same DRC gains) */
646       FDKmemcpy(&hSbrDecRight->sbrDrcChannel, &hSbrDec->sbrDrcChannel, sizeof(SBRDEC_DRC_CHANNEL));
647 
648       for (i = 0; i < synQmf->no_col; i++) {  /* ----- no_col loop ----- */
649 
650         INT outScalefactorR, outScalefactorL;
651         outScalefactorR = outScalefactorL = outScalefactor;
652 
653         /* qmf timeslot of right channel */
654         FIXP_DBL* rQmfReal = pWorkBuffer;
655         FIXP_DBL* rQmfImag = pWorkBuffer + 64;
656 
657 
658         {
659           if ( i == h_ps_d->bsData[h_ps_d->processSlot].mpeg.aEnvStartStop[env] ) {
660             initSlotBasedRotation( h_ps_d, env, hHeaderData->freqBandData.highSubband );
661             env++;
662           }
663 
664           ApplyPsSlot( h_ps_d,                   /* parametric stereo decoder handle  */
665                       (QmfBufferReal + i),       /* one timeslot of left/mono channel */
666                       (QmfBufferImag + i),       /* one timeslot of left/mono channel */
667                        rQmfReal,                 /* one timeslot or right channel     */
668                        rQmfImag);                /* one timeslot or right channel     */
669         }
670 
671 
672         scaleFactorLowBand = (i<(6)) ? scaleFactorLowBand_ov : scaleFactorLowBand_no_ov;
673 
674 
675         sbrDecoder_drcApplySlot ( /* right channel */
676                                  &hSbrDecRight->sbrDrcChannel,
677                                   rQmfReal,
678                                   rQmfImag,
679                                   i,
680                                   synQmfRight->no_col,
681                                   maxShift
682                                 );
683 
684         outScalefactorR += maxShift;
685 
686         sbrDecoder_drcApplySlot ( /* left channel */
687                                  &hSbrDec->sbrDrcChannel,
688                                  *(QmfBufferReal + i),
689                                  *(QmfBufferImag + i),
690                                   i,
691                                   synQmf->no_col,
692                                   maxShift
693                                 );
694 
695         outScalefactorL += maxShift;
696 
697 
698         /* scale filter states for left and right channel */
699         qmfChangeOutScalefactor( synQmf, outScalefactorL );
700         qmfChangeOutScalefactor( synQmfRight, outScalefactorR );
701 
702         {
703 
704           qmfSynthesisFilteringSlot( synQmfRight,
705                                      rQmfReal,                /* QMF real buffer */
706                                      rQmfImag,                /* QMF imag buffer */
707                                      scaleFactorLowBand,
708                                      scaleFactorHighBand,
709                                      timeOutRight+(i*synQmf->no_channels*strideOut),
710                                      strideOut,
711                                      pWorkBuffer);
712 
713           qmfSynthesisFilteringSlot( synQmf,
714                                    *(QmfBufferReal + i),      /* QMF real buffer */
715                                    *(QmfBufferImag + i),      /* QMF imag buffer */
716                                      scaleFactorLowBand,
717                                      scaleFactorHighBand,
718                                      timeOut+(i*synQmf->no_channels*strideOut),
719                                      strideOut,
720                                      pWorkBuffer);
721 
722         }
723       } /* no_col loop  i  */
724 
725       /* scale back (6) timeslots look ahead for hybrid filterbank to original value */
726       rescalFilterBankValues( h_ps_d,
727                               QmfBufferReal,
728                               QmfBufferImag,
729                               synQmf->lsb,
730                               synQmf->no_col );
731 
732       C_AALLOC_SCRATCH_END(pWorkBuffer, FIXP_DBL, 2*(64));
733     }
734   }
735 
736   sbrDecoder_drcUpdateChannel( &hSbrDec->sbrDrcChannel );
737 
738 
739   /*
740     Update overlap buffer
741     Even bands above usb are copied to avoid outdated spectral data in case
742     the stop frequency raises.
743   */
744 
745   if (hSbrDec->LppTrans.pSettings->overlap > 0)
746   {
747     if (! (flags & SBRDEC_LOW_POWER)) {
748       for ( i=0; i<hSbrDec->LppTrans.pSettings->overlap; i++ ) {
749         FDKmemcpy(QmfBufferReal[i], QmfBufferReal[i+noCols], (64)*sizeof(FIXP_DBL));
750         FDKmemcpy(QmfBufferImag[i], QmfBufferImag[i+noCols], (64)*sizeof(FIXP_DBL));
751       }
752     } else
753       for ( i=0; i<hSbrDec->LppTrans.pSettings->overlap; i++ ) {
754         FDKmemcpy(QmfBufferReal[i], QmfBufferReal[i+noCols], (64)*sizeof(FIXP_DBL));
755       }
756   }
757 
758   hSbrDec->sbrScaleFactor.ov_lb_scale = saveLbScale;
759 
760   /* Save current frame status */
761   hPrevFrameData->frameErrorFlag = hHeaderData->frameErrorFlag;
762 
763 } // sbr_dec()
764 
765 
766 /*!
767   \brief     Creates sbr decoder structure
768   \return    errorCode, 0 if successful
769 */
770 SBR_ERROR
createSbrDec(SBR_CHANNEL * hSbrChannel,HANDLE_SBR_HEADER_DATA hHeaderData,TRANSPOSER_SETTINGS * pSettings,const int downsampleFac,const UINT qmfFlags,const UINT flags,const int overlap,int chan)771 createSbrDec (SBR_CHANNEL * hSbrChannel,
772               HANDLE_SBR_HEADER_DATA hHeaderData, /*!< Static control data */
773               TRANSPOSER_SETTINGS *pSettings,
774               const int     downsampleFac,        /*!< Downsampling factor */
775               const UINT    qmfFlags,             /*!< flags -> 1: HQ/LP selector, 2: CLDFB */
776               const UINT    flags,
777               const int     overlap,
778               int           chan)                 /*!< Channel for which to assign buffers etc. */
779 
780 {
781   SBR_ERROR err = SBRDEC_OK;
782   int timeSlots = hHeaderData->numberTimeSlots;   /* Number of SBR slots per frame */
783   int noCols = timeSlots * hHeaderData->timeStep; /* Number of QMF slots per frame */
784   HANDLE_SBR_DEC hs = &(hSbrChannel->SbrDec);
785 
786   /* Initialize scale factors */
787   hs->sbrScaleFactor.ov_lb_scale  = 0;
788   hs->sbrScaleFactor.ov_hb_scale  = 0;
789   hs->sbrScaleFactor.hb_scale     = 0;
790 
791 
792   /*
793     create envelope calculator
794   */
795   err = createSbrEnvelopeCalc (&hs->SbrCalculateEnvelope,
796                                hHeaderData,
797                                chan,
798                                flags);
799   if (err != SBRDEC_OK) {
800     return err;
801   }
802 
803   /*
804     create QMF filter banks
805   */
806   {
807     int qmfErr;
808     /* Adapted QMF analysis post-twiddles for down-sampled HQ SBR */
809     const UINT downSampledFlag = (flags & SBRDEC_DOWNSAMPLE) ? QMF_FLAG_DOWNSAMPLED : 0;
810 
811     qmfErr = qmfInitAnalysisFilterBank (
812                     &hs->AnalysiscQMF,
813                      hs->anaQmfStates,
814                      noCols,
815                      hHeaderData->freqBandData.lowSubband,
816                      hHeaderData->freqBandData.highSubband,
817                      hHeaderData->numberOfAnalysisBands,
818                      (qmfFlags & (~QMF_FLAG_KEEP_STATES)) | downSampledFlag
819                      );
820     if (qmfErr != 0) {
821       return SBRDEC_UNSUPPORTED_CONFIG;
822     }
823   }
824   if (hs->pSynQmfStates == NULL) {
825     hs->pSynQmfStates = GetRam_sbr_QmfStatesSynthesis(chan);
826     if (hs->pSynQmfStates == NULL)
827       return SBRDEC_MEM_ALLOC_FAILED;
828   }
829 
830   {
831     int qmfErr;
832 
833     qmfErr = qmfInitSynthesisFilterBank (
834            &hs->SynthesisQMF,
835             hs->pSynQmfStates,
836             noCols,
837             hHeaderData->freqBandData.lowSubband,
838             hHeaderData->freqBandData.highSubband,
839             (64) / downsampleFac,
840             qmfFlags & (~QMF_FLAG_KEEP_STATES)
841             );
842 
843     if (qmfErr != 0) {
844       return SBRDEC_UNSUPPORTED_CONFIG;
845     }
846   }
847   initSbrPrevFrameData (&hSbrChannel->prevFrameData, timeSlots);
848 
849   /*
850     create transposer
851   */
852   err = createLppTransposer (&hs->LppTrans,
853                              pSettings,
854                              hHeaderData->freqBandData.lowSubband,
855                              hHeaderData->freqBandData.v_k_master,
856                              hHeaderData->freqBandData.numMaster,
857                              hs->SynthesisQMF.usb,
858                              timeSlots,
859                              hs->AnalysiscQMF.no_col,
860                              hHeaderData->freqBandData.freqBandTableNoise,
861                              hHeaderData->freqBandData.nNfb,
862                              hHeaderData->sbrProcSmplRate,
863                              chan,
864                              overlap );
865   if (err != SBRDEC_OK) {
866     return err;
867   }
868 
869   /* The CLDFB does not have overlap */
870   if ((qmfFlags & QMF_FLAG_CLDFB) == 0) {
871     if (hs->pSbrOverlapBuffer == NULL) {
872       hs->pSbrOverlapBuffer = GetRam_sbr_OverlapBuffer(chan);
873       if (hs->pSbrOverlapBuffer == NULL)  {
874         return SBRDEC_MEM_ALLOC_FAILED;
875       }
876     } else {
877       /* Clear overlap buffer */
878       FDKmemclear( hs->pSbrOverlapBuffer,
879                    sizeof(FIXP_DBL) * 2 * (6) * (64)
880                  );
881     }
882   }
883 
884   /* Clear input delay line */
885   FDKmemclear(hs->coreDelayBuf, (96)*sizeof(INT_PCM));
886 
887   /* assign qmf time slots */
888   assignTimeSlots( &hSbrChannel->SbrDec, hHeaderData->numberTimeSlots * hHeaderData->timeStep, qmfFlags & QMF_FLAG_LP);
889 
890   return err;
891 }
892 
893 /*!
894   \brief     Delete sbr decoder structure
895   \return    errorCode, 0 if successful
896 */
897 int
deleteSbrDec(SBR_CHANNEL * hSbrChannel)898 deleteSbrDec (SBR_CHANNEL * hSbrChannel)
899 {
900   HANDLE_SBR_DEC hs = &hSbrChannel->SbrDec;
901 
902   deleteSbrEnvelopeCalc (&hs->SbrCalculateEnvelope);
903 
904   /* delete QMF filter states */
905   if (hs->pSynQmfStates != NULL) {
906     FreeRam_sbr_QmfStatesSynthesis(&hs->pSynQmfStates);
907   }
908 
909 
910   if (hs->pSbrOverlapBuffer != NULL) {
911     FreeRam_sbr_OverlapBuffer(&hs->pSbrOverlapBuffer);
912   }
913 
914   return 0;
915 }
916 
917 
918 /*!
919   \brief     resets sbr decoder structure
920   \return    errorCode, 0 if successful
921 */
922 SBR_ERROR
resetSbrDec(HANDLE_SBR_DEC hSbrDec,HANDLE_SBR_HEADER_DATA hHeaderData,HANDLE_SBR_PREV_FRAME_DATA hPrevFrameData,const int useLP,const int downsampleFac)923 resetSbrDec (HANDLE_SBR_DEC hSbrDec,
924              HANDLE_SBR_HEADER_DATA hHeaderData,
925              HANDLE_SBR_PREV_FRAME_DATA hPrevFrameData,
926              const int useLP,
927              const int downsampleFac
928              )
929 {
930   SBR_ERROR sbrError = SBRDEC_OK;
931 
932   int old_lsb = hSbrDec->SynthesisQMF.lsb;
933   int new_lsb = hHeaderData->freqBandData.lowSubband;
934   int l, startBand, stopBand, startSlot, size;
935 
936   int source_scale, target_scale, delta_scale, target_lsb, target_usb, reserve;
937   FIXP_DBL maxVal;
938 
939   /* overlapBuffer point to first (6) slots */
940   FIXP_DBL  **OverlapBufferReal = hSbrDec->QmfBufferReal;
941   FIXP_DBL  **OverlapBufferImag = hSbrDec->QmfBufferImag;
942 
943   /* assign qmf time slots */
944   assignTimeSlots( hSbrDec, hHeaderData->numberTimeSlots * hHeaderData->timeStep, useLP);
945 
946 
947 
948   resetSbrEnvelopeCalc (&hSbrDec->SbrCalculateEnvelope);
949 
950   hSbrDec->SynthesisQMF.lsb = hHeaderData->freqBandData.lowSubband;
951   hSbrDec->SynthesisQMF.usb = fixMin((INT)hSbrDec->SynthesisQMF.no_channels, (INT)hHeaderData->freqBandData.highSubband);
952 
953   hSbrDec->AnalysiscQMF.lsb = hSbrDec->SynthesisQMF.lsb;
954   hSbrDec->AnalysiscQMF.usb = hSbrDec->SynthesisQMF.usb;
955 
956 
957   /*
958     The following initialization of spectral data in the overlap buffer
959     is required for dynamic x-over or a change of the start-freq for 2 reasons:
960 
961     1. If the lowband gets _wider_, unadjusted data would remain
962 
963     2. If the lowband becomes _smaller_, the highest bands of the old lowband
964        must be cleared because the whitening would be affected
965   */
966   startBand = old_lsb;
967   stopBand  = new_lsb;
968   startSlot = hHeaderData->timeStep * (hPrevFrameData->stopPos - hHeaderData->numberTimeSlots);
969   size      = fixMax(0,stopBand-startBand);
970 
971   /* keep already adjusted data in the x-over-area */
972   if (!useLP) {
973     for (l=startSlot; l<hSbrDec->LppTrans.pSettings->overlap; l++) {
974       FDKmemclear(&OverlapBufferReal[l][startBand], size*sizeof(FIXP_DBL));
975       FDKmemclear(&OverlapBufferImag[l][startBand], size*sizeof(FIXP_DBL));
976     }
977   } else
978   for (l=startSlot; l<hSbrDec->LppTrans.pSettings->overlap ; l++) {
979     FDKmemclear(&OverlapBufferReal[l][startBand], size*sizeof(FIXP_DBL));
980   }
981 
982 
983   /*
984     reset LPC filter states
985   */
986   startBand = fixMin(old_lsb,new_lsb);
987   stopBand  = fixMax(old_lsb,new_lsb);
988   size      = fixMax(0,stopBand-startBand);
989 
990   FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesReal[0][startBand], size*sizeof(FIXP_DBL));
991   FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesReal[1][startBand], size*sizeof(FIXP_DBL));
992   if (!useLP) {
993     FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesImag[0][startBand], size*sizeof(FIXP_DBL));
994     FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesImag[1][startBand], size*sizeof(FIXP_DBL));
995   }
996 
997 
998   /*
999     Rescale already processed spectral data between old and new x-over frequency.
1000     This must be done because of the separate scalefactors for lowband and highband.
1001   */
1002   startBand = fixMin(old_lsb,new_lsb);
1003   stopBand =  fixMax(old_lsb,new_lsb);
1004 
1005   if (new_lsb > old_lsb) {
1006     /* The x-over-area was part of the highband before and will now belong to the lowband */
1007     source_scale = hSbrDec->sbrScaleFactor.ov_hb_scale;
1008     target_scale = hSbrDec->sbrScaleFactor.ov_lb_scale;
1009     target_lsb   = 0;
1010     target_usb   = old_lsb;
1011   }
1012   else {
1013     /* The x-over-area was part of the lowband before and will now belong to the highband */
1014     source_scale = hSbrDec->sbrScaleFactor.ov_lb_scale;
1015     target_scale = hSbrDec->sbrScaleFactor.ov_hb_scale;
1016     /* jdr: The values old_lsb and old_usb might be wrong because the previous frame might have been "upsamling". */
1017     target_lsb   = hSbrDec->SynthesisQMF.lsb;
1018     target_usb   = hSbrDec->SynthesisQMF.usb;
1019   }
1020 
1021   /* Shift left all samples of the x-over-area as much as possible
1022      An unnecessary coarse scale could cause ov_lb_scale or ov_hb_scale to be
1023      adapted and the accuracy in the next frame would seriously suffer! */
1024 
1025   maxVal = maxSubbandSample( OverlapBufferReal,
1026                              (useLP) ? NULL : OverlapBufferImag,
1027                              startBand,
1028                              stopBand,
1029                              0,
1030                              startSlot);
1031 
1032   reserve = CntLeadingZeros(maxVal)-1;
1033   reserve = fixMin(reserve,DFRACT_BITS-1-source_scale);
1034 
1035   rescaleSubbandSamples( OverlapBufferReal,
1036                          (useLP) ? NULL : OverlapBufferImag,
1037                          startBand,
1038                          stopBand,
1039                          0,
1040                          startSlot,
1041                          reserve);
1042   source_scale += reserve;
1043 
1044   delta_scale = target_scale - source_scale;
1045 
1046   if (delta_scale > 0) { /* x-over-area is dominant */
1047     delta_scale = -delta_scale;
1048     startBand = target_lsb;
1049     stopBand = target_usb;
1050 
1051     if (new_lsb > old_lsb) {
1052       /* The lowband has to be rescaled */
1053       hSbrDec->sbrScaleFactor.ov_lb_scale = source_scale;
1054     }
1055     else {
1056       /* The highband has be be rescaled */
1057       hSbrDec->sbrScaleFactor.ov_hb_scale = source_scale;
1058     }
1059   }
1060 
1061   FDK_ASSERT(startBand <= stopBand);
1062 
1063   if (!useLP) {
1064     for (l=0; l<startSlot; l++) {
1065       scaleValues( OverlapBufferReal[l] + startBand, stopBand-startBand, delta_scale );
1066       scaleValues( OverlapBufferImag[l] + startBand, stopBand-startBand, delta_scale );
1067     }
1068   } else
1069   for (l=0; l<startSlot; l++) {
1070     scaleValues( OverlapBufferReal[l] + startBand, stopBand-startBand, delta_scale );
1071   }
1072 
1073 
1074   /*
1075     Initialize transposer and limiter
1076   */
1077   sbrError = resetLppTransposer (&hSbrDec->LppTrans,
1078                                  hHeaderData->freqBandData.lowSubband,
1079                                  hHeaderData->freqBandData.v_k_master,
1080                                  hHeaderData->freqBandData.numMaster,
1081                                  hHeaderData->freqBandData.freqBandTableNoise,
1082                                  hHeaderData->freqBandData.nNfb,
1083                                  hHeaderData->freqBandData.highSubband,
1084                                  hHeaderData->sbrProcSmplRate);
1085   if (sbrError != SBRDEC_OK)
1086     return sbrError;
1087 
1088   sbrError = ResetLimiterBands ( hHeaderData->freqBandData.limiterBandTable,
1089                                  &hHeaderData->freqBandData.noLimiterBands,
1090                                  hHeaderData->freqBandData.freqBandTable[0],
1091                                  hHeaderData->freqBandData.nSfb[0],
1092                                  hSbrDec->LppTrans.pSettings->patchParam,
1093                                  hSbrDec->LppTrans.pSettings->noOfPatches,
1094                                  hHeaderData->bs_data.limiterBands);
1095 
1096 
1097   return sbrError;
1098 }
1099