path: root/libAACdec/src/rvlcconceal.cpp

/* -----------------------------------------------------------------------------------------------------------
Software License for The Fraunhofer FDK AAC Codec Library for Android

© Copyright  1995 - 2012 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
  All rights reserved.

 1.    INTRODUCTION
The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements
the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio.
This FDK AAC Codec software is intended to be used on a wide variety of Android devices.

AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual
audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by
independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part
of the MPEG specifications.

Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer)
may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
individually for the purpose of encoding or decoding bit streams in products that are compliant with
the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
software may already be covered under those patent licenses when it is used for those licensed purposes only.

Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality,
are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional
applications information and documentation.

2.    COPYRIGHT LICENSE

Redistribution and use in source and binary forms, with or without modification, are permitted without
payment of copyright license fees provided that you satisfy the following conditions:

You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
your modifications thereto in source code form.

You must retain the complete text of this software license in the documentation and/or other materials
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You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
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The name of Fraunhofer may not be used to endorse or promote products derived from this library without
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"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."

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ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
respect to this software.

You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
by appropriate patent licenses.

4.    DISCLAIMER

This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
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5.    CONTACT INFORMATION

Fraunhofer Institute for Integrated Circuits IIS
Attention: Audio and Multimedia Departments - FDK AAC LL
Am Wolfsmantel 33
91058 Erlangen, Germany

www.iis.fraunhofer.de/amm
amm-info@iis.fraunhofer.de
----------------------------------------------------------------------------------------------------------- */

/*!
  \file
  \brief  rvlc concealment
  \author Josef Hoepfl
*/

#include "rvlcconceal.h"


#include "block.h"
#include "rvlc.h"

/*---------------------------------------------------------------------------------------------
  function:      calcRefValFwd

  description:   The function determines the scalefactor which is closed to the scalefactorband
                 conceal_min. The same is done for intensity data and noise energies.
-----------------------------------------------------------------------------------------------
  output:        - reference value scf
                 - reference value internsity data
                 - reference value noise energy
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

static
void calcRefValFwd (CErRvlcInfo *pRvlc,
                    CAacDecoderChannelInfo *pAacDecoderChannelInfo,
                    int *refIsFwd,
                    int *refNrgFwd,
                    int *refScfFwd)
{
  int band,bnds,group,startBand;
  int idIs,idNrg,idScf;
  int conceal_min,conceal_group_min;
  int MaximumScaleFactorBands;


  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence)
    MaximumScaleFactorBands = 16;
  else
    MaximumScaleFactorBands = 64;

  conceal_min = pRvlc->conceal_min % MaximumScaleFactorBands;
  conceal_group_min = pRvlc->conceal_min / MaximumScaleFactorBands;

  /* calculate first reference value for approach in forward direction */
  idIs = idNrg = idScf = 1;

  /* set reference values */
  *refIsFwd = - SF_OFFSET;
  *refNrgFwd = pAacDecoderChannelInfo->pDynData->RawDataInfo.GlobalGain - SF_OFFSET - 90 - 256;
  *refScfFwd = pAacDecoderChannelInfo->pDynData->RawDataInfo.GlobalGain - SF_OFFSET;

  startBand = conceal_min-1;
  for (group=conceal_group_min; group >= 0; group--) {
    for (band=startBand; band >= 0; band--) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          break;
        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          if (idIs) {
            *refIsFwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
            idIs=0; /* reference value has been set */
          }
          break;
        case NOISE_HCB:
          if (idNrg) {
            *refNrgFwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
            idNrg=0; /* reference value has been set */
          }
          break ;
        default:
          if (idScf) {
            *refScfFwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
            idScf=0; /* reference value has been set */
          }
          break;
      }
    }
    startBand = pRvlc->maxSfbTransmitted-1;
  }

}

/*---------------------------------------------------------------------------------------------
  function:      calcRefValBwd

  description:   The function determines the scalefactor which is closed to the scalefactorband
                 conceal_max. The same is done for intensity data and noise energies.
-----------------------------------------------------------------------------------------------
  output:        - reference value scf
                 - reference value internsity data
                 - reference value noise energy
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

static
void calcRefValBwd (CErRvlcInfo *pRvlc,
                    CAacDecoderChannelInfo *pAacDecoderChannelInfo,
                    int *refIsBwd,
                    int *refNrgBwd,
                    int *refScfBwd)
{
  int band,bnds,group,startBand;
  int idIs,idNrg,idScf;
  int conceal_max,conceal_group_max;
  int MaximumScaleFactorBands;

  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence)
    MaximumScaleFactorBands = 16;
  else
    MaximumScaleFactorBands = 64;

  conceal_max = pRvlc->conceal_max % MaximumScaleFactorBands;
  conceal_group_max = pRvlc->conceal_max / MaximumScaleFactorBands;

  /* calculate first reference value for approach in backward direction */
  idIs = idNrg = idScf = 1;

  /* set reference values */
  *refIsBwd = pRvlc->dpcm_is_last_position - SF_OFFSET;
  *refNrgBwd = pRvlc->rev_global_gain + pRvlc->dpcm_noise_last_position - SF_OFFSET - 90 - 256 + pRvlc->dpcm_noise_nrg;
  *refScfBwd = pRvlc->rev_global_gain - SF_OFFSET;

  startBand=conceal_max+1;

  /* if needed, re-set reference values */
  for (group=conceal_group_max; group < pRvlc->numWindowGroups; group++) {
    for (band=startBand; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          break;
        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          if (idIs) {
            *refIsBwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
            idIs=0; /* reference value has been set */
          }
          break;
        case NOISE_HCB:
          if (idNrg) {
            *refNrgBwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
            idNrg=0;  /* reference value has been set */
          }
          break ;
        default:
          if (idScf) {
            *refScfBwd = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
            idScf=0; /* reference value has been set */
          }
          break;
      }
    }
    startBand=0;
  }

}


/*---------------------------------------------------------------------------------------------
  function:      BidirectionalEstimation_UseLowerScfOfCurrentFrame

  description:   This approach by means of bidirectional estimation is generally performed when
                 a single bit error has been detected, the bit error can be isolated between
                 'conceal_min' and 'conceal_max' and the 'sf_concealment' flag is not set. The
                 sets of scalefactors decoded in forward and backward direction are compared
                 with each other. The smaller scalefactor will be considered as the correct one
                 respectively. The reconstruction of the scalefactors with this approach archieve
                 good results in audio quality. The strategy must be applied to scalefactors,
                 intensity data and noise energy seperately.
-----------------------------------------------------------------------------------------------
  output:        Concealed scalefactor, noise energy and intensity data between conceal_min and
                 conceal_max
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

void BidirectionalEstimation_UseLowerScfOfCurrentFrame (CAacDecoderChannelInfo *pAacDecoderChannelInfo)
{
  CErRvlcInfo *pRvlc = &pAacDecoderChannelInfo->pComData->overlay.aac.erRvlcInfo;
  int band,bnds,startBand,endBand,group;
  int conceal_min,conceal_max;
  int conceal_group_min,conceal_group_max;
  int MaximumScaleFactorBands;

  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence) {
    MaximumScaleFactorBands = 16;
  }
  else {
    MaximumScaleFactorBands = 64;
  }
  
  /* If an error was detected just in forward or backward direction, set the corresponding border for concealment to a
     appropriate scalefactor band. The border is set to first or last sfb respectively, because the error will possibly 
     not follow directly after the corrupt bit but just after decoding some more (wrong) scalefactors. */
  if (pRvlc->conceal_min == CONCEAL_MIN_INIT)
    pRvlc->conceal_min = 0;

  if (pRvlc->conceal_max == CONCEAL_MAX_INIT)
    pRvlc->conceal_max = (pRvlc->numWindowGroups-1)*16+pRvlc->maxSfbTransmitted-1;

  conceal_min = pRvlc->conceal_min % MaximumScaleFactorBands;
  conceal_group_min = pRvlc->conceal_min / MaximumScaleFactorBands;
  conceal_max = pRvlc->conceal_max % MaximumScaleFactorBands;
  conceal_group_max = pRvlc->conceal_max / MaximumScaleFactorBands;

  if (pRvlc->conceal_min == pRvlc->conceal_max) {

    int refIsFwd,refNrgFwd,refScfFwd;
    int refIsBwd,refNrgBwd,refScfBwd;

    bnds = pRvlc->conceal_min;
    calcRefValFwd(pRvlc,pAacDecoderChannelInfo,&refIsFwd,&refNrgFwd,&refScfFwd);
    calcRefValBwd(pRvlc,pAacDecoderChannelInfo,&refIsBwd,&refNrgBwd,&refScfBwd);

    switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
      case ZERO_HCB:
        break;
      case INTENSITY_HCB:
      case INTENSITY_HCB2:
        if (refIsFwd < refIsBwd) 
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refIsFwd;
        else
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refIsBwd;
        break;
      case NOISE_HCB:
        if (refNrgFwd < refNrgBwd)
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refNrgFwd;
        else
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refNrgBwd;
        break;
      default:
        if (refScfFwd < refScfBwd)
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refScfFwd;
        else 
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = refScfBwd;
        break;
    }
  }
  else {
    pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[pRvlc->conceal_max] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[pRvlc->conceal_max];
    pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[pRvlc->conceal_min] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[pRvlc->conceal_min];

    /* consider the smaller of the forward and backward decoded value as the correct one */  
    startBand = conceal_min;      
    if (conceal_group_min == conceal_group_max)   
      endBand = conceal_max;      
    else          
      endBand = pRvlc->maxSfbTransmitted-1;       

    for (group=conceal_group_min; group <= conceal_group_max; group++) {  
      for (band=startBand; band <= endBand; band++) {  
        bnds = 16*group+band;  
        if (pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds] < pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds])  
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
        else
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
      }  
      startBand = 0;   
      if ((group+1) == conceal_group_max)  
        endBand = conceal_max;  
    }  
  }

  /* now copy all data to the output buffer which needs not to be concealed */
  if (conceal_group_min == 0) 
    endBand = conceal_min;    
  else        
    endBand = pRvlc->maxSfbTransmitted;     
  for (group=0; group <= conceal_group_min; group++) {
    for (band=0; band < endBand; band++) {
      bnds = 16*group+band;
      pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
    }
    if ((group+1) == conceal_group_min) 
      endBand = conceal_min;    
  }

  startBand = conceal_max+1;    
  for (group=conceal_group_max; group < pRvlc->numWindowGroups; group++) {
    for (band=startBand; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
    }
    startBand = 0;
  }
}

/*---------------------------------------------------------------------------------------------
  function:      BidirectionalEstimation_UseScfOfPrevFrameAsReference

  description:   This approach by means of bidirectional estimation is generally performed when
                 a single bit error has been detected, the bit error can be isolated between 
                 'conceal_min' and 'conceal_max', the 'sf_concealment' flag is set and the 
                 previous frame has the same block type as the current frame. The scalefactor 
                 decoded in forward and backward direction and the scalefactor of the previous 
                 frame are compared with each other. The smaller scalefactor will be considered 
                 as the correct one. At this the codebook of the previous and current frame must 
                 be of the same set (scf, nrg, is) in each scalefactorband. Otherwise the 
                 scalefactor of the previous frame is not considered in the minimum calculation. 
                 The reconstruction of the scalefactors with this approach archieve good results 
                 in audio quality. The strategy must be applied to scalefactors, intensity data 
                 and noise energy seperately.
-----------------------------------------------------------------------------------------------
  output:        Concealed scalefactor, noise energy and intensity data between conceal_min and 
                 conceal_max
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

void BidirectionalEstimation_UseScfOfPrevFrameAsReference (
        CAacDecoderChannelInfo *pAacDecoderChannelInfo,
        CAacDecoderStaticChannelInfo *pAacDecoderStaticChannelInfo
        )
{
  CErRvlcInfo *pRvlc = &pAacDecoderChannelInfo->pComData->overlay.aac.erRvlcInfo;
  int band,bnds,startBand,endBand,group;
  int conceal_min,conceal_max;
  int conceal_group_min,conceal_group_max;
  int MaximumScaleFactorBands;
  int commonMin;

  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence) {
    MaximumScaleFactorBands = 16;
  }
  else {
    MaximumScaleFactorBands = 64;
  }

  /* If an error was detected just in forward or backward direction, set the corresponding border for concealment to a
     appropriate scalefactor band. The border is set to first or last sfb respectively, because the error will possibly 
     not follow directly after the corrupt bit but just after decoding some more (wrong) scalefactors. */
  if (pRvlc->conceal_min == CONCEAL_MIN_INIT)
    pRvlc->conceal_min = 0;

  if (pRvlc->conceal_max == CONCEAL_MAX_INIT)
    pRvlc->conceal_max = (pRvlc->numWindowGroups-1)*16+pRvlc->maxSfbTransmitted-1;

  conceal_min = pRvlc->conceal_min % MaximumScaleFactorBands;
  conceal_group_min = pRvlc->conceal_min / MaximumScaleFactorBands;
  conceal_max = pRvlc->conceal_max % MaximumScaleFactorBands;
  conceal_group_max = pRvlc->conceal_max / MaximumScaleFactorBands;

  pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[pRvlc->conceal_max] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[pRvlc->conceal_max];  
  pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[pRvlc->conceal_min] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[pRvlc->conceal_min];  

  /* consider the smaller of the forward and backward decoded value as the correct one */
  startBand = conceal_min;    
  if (conceal_group_min == conceal_group_max) 
    endBand = conceal_max;    
  else        
    endBand = pRvlc->maxSfbTransmitted-1;     

  for (group=conceal_group_min; group <= conceal_group_max; group++) {
    for (band=startBand; band <= endBand; band++) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = 0;
          break;

        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          if ( (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==INTENSITY_HCB) || (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==INTENSITY_HCB2) ) {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          }
          else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
          }
          break;

        case NOISE_HCB:
          if ( (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==NOISE_HCB) ) {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          } else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
          }
          break;

        default:
          if (   (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=ZERO_HCB)
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=NOISE_HCB)
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=INTENSITY_HCB) 
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=INTENSITY_HCB2) )
          {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds], pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          } else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
          }
          break;
      }
    }
    startBand = 0; 
    if ((group+1) == conceal_group_max)
      endBand = conceal_max;
  }

  /* now copy all data to the output buffer which needs not to be concealed */
  if (conceal_group_min == 0) 
    endBand = conceal_min;    
  else        
    endBand = pRvlc->maxSfbTransmitted;     
  for (group=0; group <= conceal_group_min; group++) {
    for (band=0; band < endBand; band++) {
      bnds = 16*group+band;
      pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
    }
    if ((group+1) == conceal_group_min) 
      endBand = conceal_min;    
  }

  startBand = conceal_max+1;    
  for (group=conceal_group_max; group < pRvlc->numWindowGroups; group++) {
    for (band=startBand; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
    }
    startBand = 0;
  }
}

/*---------------------------------------------------------------------------------------------
  function:      StatisticalEstimation

  description:   This approach by means of statistical estimation is generally performed when 
                 both the start value and the end value are different and no further errors have 
                 been detected. Considering the forward and backward decoded scalefactors, the 
                 set with the lower scalefactors in sum will be considered as the correct one. 
                 The scalefactors are differentially encoded. Normally it would reach to compare 
                 one pair of the forward and backward decoded scalefactors to specify the lower 
                 set. But having detected no further errors does not necessarily mean the absence
                 of errors. Therefore all scalefactors decoded in forward and backward direction 
                 are summed up seperately. The set with the lower sum will be used. The strategy 
                 must be applied to scalefactors, intensity data and noise energy seperately.
-----------------------------------------------------------------------------------------------
  output:        Concealed scalefactor, noise energy and intensity data
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

void StatisticalEstimation (CAacDecoderChannelInfo *pAacDecoderChannelInfo)
{
  CErRvlcInfo *pRvlc = &pAacDecoderChannelInfo->pComData->overlay.aac.erRvlcInfo;
  int band,bnds,group;
  int sumIsFwd,sumIsBwd;            /* sum of intensity data forward/backward */
  int sumNrgFwd,sumNrgBwd;          /* sum of noise energy data forward/backward */
  int sumScfFwd,sumScfBwd;          /* sum of scalefactor data forward/backward */
  int useIsFwd,useNrgFwd,useScfFwd; /* the flags signals the elements which are used for the final result */
  int MaximumScaleFactorBands;

  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence)
    MaximumScaleFactorBands = 16;
  else
    MaximumScaleFactorBands = 64;

  sumIsFwd = sumIsBwd = sumNrgFwd = sumNrgBwd = sumScfFwd = sumScfBwd = 0;
  useIsFwd = useNrgFwd = useScfFwd = 0;

  /* calculate sum of each group (scf,nrg,is) of forward and backward direction */
  for (group=0; group<pRvlc->numWindowGroups; group++) {
    for (band=0; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          break;

        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          sumIsFwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          sumIsBwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break;

        case NOISE_HCB:
          sumNrgFwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          sumNrgBwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break ;

        default:
          sumScfFwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          sumScfBwd += pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break;
      }
    }
  }

  /* find for each group (scf,nrg,is) the correct direction */
  if ( sumIsFwd < sumIsBwd )
    useIsFwd = 1;

  if ( sumNrgFwd < sumNrgBwd )
    useNrgFwd = 1;

  if ( sumScfFwd < sumScfBwd )
    useScfFwd = 1;

  /* conceal each group (scf,nrg,is) */
  for (group=0; group<pRvlc->numWindowGroups; group++) {
    for (band=0; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          break;

        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          if (useIsFwd)
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          else
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break;

        case NOISE_HCB:
          if (useNrgFwd)
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          else
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break ;

        default:
          if (useScfFwd)
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds];
          else
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds];
          break;
      }
    }
  }
}


/*---------------------------------------------------------------------------------------------
  description:   Approach by means of predictive interpolation
                 This approach by means of predictive estimation is generally performed when 
                 the error cannot be isolated between 'conceal_min' and 'conceal_max', the 
                 'sf_concealment' flag is set and the previous frame has the same block type 
                 as the current frame. Check for each scalefactorband if the same type of data 
                 (scalefactor, internsity data, noise energies) is transmitted. If so use the 
                 scalefactor (intensity data, noise energy) in the current frame. Otherwise set 
                 the scalefactor (intensity data, noise energy) for this scalefactorband to zero.
-----------------------------------------------------------------------------------------------
  output:        Concealed scalefactor, noise energy and intensity data
-----------------------------------------------------------------------------------------------
  return:        -
-------------------------------------------------------------------------------------------- */

void PredictiveInterpolation (
        CAacDecoderChannelInfo *pAacDecoderChannelInfo,
        CAacDecoderStaticChannelInfo *pAacDecoderStaticChannelInfo
        )
{
  CErRvlcInfo *pRvlc = &pAacDecoderChannelInfo->pComData->overlay.aac.erRvlcInfo;
  int band,bnds,group;
  int MaximumScaleFactorBands;
  int commonMin;

  if (GetWindowSequence(&pAacDecoderChannelInfo->icsInfo) == EightShortSequence)
    MaximumScaleFactorBands = 16;
  else
    MaximumScaleFactorBands = 64;

  for (group=0; group<pRvlc->numWindowGroups; group++) {
    for (band=0; band < pRvlc->maxSfbTransmitted; band++) {
      bnds = 16*group+band;
      switch (pAacDecoderChannelInfo->pDynData->aCodeBook[bnds]) {
        case ZERO_HCB:
          pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = 0;
          break;

        case INTENSITY_HCB:
        case INTENSITY_HCB2:
          if ( (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==INTENSITY_HCB) || (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==INTENSITY_HCB2) ) {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          }
          else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = -110;
          }
          break;

        case NOISE_HCB:
          if ( (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]==NOISE_HCB) ) {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          }
          else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = -110;
          }
          break;

        default:
          if (   (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=ZERO_HCB)
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=NOISE_HCB) 
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=INTENSITY_HCB) 
              && (pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousCodebook[bnds]!=INTENSITY_HCB2) ) {
            commonMin = FDKmin(pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfFwd[bnds],pAacDecoderChannelInfo->pComData->overlay.aac.aRvlcScfBwd[bnds]);
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = FDKmin(commonMin, pAacDecoderStaticChannelInfo->concealmentInfo.aRvlcPreviousScaleFactor[bnds]);
          }
          else {
            pAacDecoderChannelInfo->pDynData->aScaleFactor[bnds] = 0;
          }
          break;
      }
    }
  }
}