xref: /external/aac/libAACenc/src/ms_stereo.cpp

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

 Copyright  1995 - 2013 Fraunhofer-Gesellschaft zur Frderung der angewandten Forschung e.V.
  All rights reserved.

 1.    INTRODUCTION
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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.

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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
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5.    CONTACT INFORMATION

Fraunhofer Institute for Integrated Circuits IIS
Attention: Audio and Multimedia Departments - FDK AAC LL
Am Wolfsmantel 33
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www.iis.fraunhofer.de/amm
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----------------------------------------------------------------------------------------------------------- */

/******************************** MPEG Audio Encoder **************************

   Initial author:       M.Werner
   contents/description: MS stereo processing

******************************************************************************/
#include "ms_stereo.h"

#include "psy_const.h"

/* static const float scaleMinThres = 1.0f; */ /* 0.75f for 3db boost */

void FDKaacEnc_MsStereoProcessing(PSY_DATA   *RESTRICT psyData[(2)],
                        PSY_OUT_CHANNEL* psyOutChannel[2],
                        const INT  *isBook,
                        INT        *msDigest,       /* output */
                        INT        *msMask,         /* output */
                        const INT   sfbCnt,
                        const INT   sfbPerGroup,
                        const INT   maxSfbPerGroup,
                        const INT  *sfbOffset)
{
    FIXP_DBL        *sfbEnergyLeft = psyData[0]->sfbEnergy.Long;                       /* modified where msMask==1 */
    FIXP_DBL        *sfbEnergyRight = psyData[1]->sfbEnergy.Long;                      /* modified where msMask==1 */
    const FIXP_DBL  *sfbEnergyMid = psyData[0]->sfbEnergyMS.Long;
    const FIXP_DBL  *sfbEnergySide = psyData[1]->sfbEnergyMS.Long;
    FIXP_DBL        *sfbThresholdLeft = psyData[0]->sfbThreshold.Long;                 /* modified where msMask==1 */
    FIXP_DBL        *sfbThresholdRight = psyData[1]->sfbThreshold.Long;                /* modified where msMask==1 */

    FIXP_DBL        *sfbSpreadEnLeft = psyData[0]->sfbSpreadEnergy.Long;
    FIXP_DBL        *sfbSpreadEnRight = psyData[1]->sfbSpreadEnergy.Long;

    FIXP_DBL        *sfbEnergyLeftLdData = psyOutChannel[0]->sfbEnergyLdData;        /* modified where msMask==1 */
    FIXP_DBL        *sfbEnergyRightLdData = psyOutChannel[1]->sfbEnergyLdData;       /* modified where msMask==1 */
    FIXP_DBL        *sfbEnergyMidLdData = psyData[0]->sfbEnergyMSLdData;
    FIXP_DBL        *sfbEnergySideLdData = psyData[1]->sfbEnergyMSLdData;
    FIXP_DBL        *sfbThresholdLeftLdData = psyOutChannel[0]->sfbThresholdLdData;  /* modified where msMask==1 */
    FIXP_DBL        *sfbThresholdRightLdData = psyOutChannel[1]->sfbThresholdLdData; /* modified where msMask==1 */

    FIXP_DBL        *mdctSpectrumLeft = psyData[0]->mdctSpectrum;                      /* modified where msMask==1 */
    FIXP_DBL        *mdctSpectrumRight = psyData[1]->mdctSpectrum;                     /* modified where msMask==1 */

    INT             sfb,sfboffs, j;           /* loop counters         */
    FIXP_DBL        pnlrLdData, pnmsLdData;
    FIXP_DBL        minThresholdLdData;
    FIXP_DBL        minThreshold;
    INT             useMS;

    INT             msMaskTrueSomewhere = 0;  /* to determine msDigest */
    INT             numMsMaskFalse = 0;       /* number of non-intensity bands where L/R coding is used */

    for(sfb=0; sfb<sfbCnt; sfb+=sfbPerGroup) {
      for(sfboffs=0;sfboffs<maxSfbPerGroup;sfboffs++) {

        if ( (isBook==NULL) ? 1 : (isBook[sfb+sfboffs] == 0) ) {
          FIXP_DBL tmp;

/*
          minThreshold=min(sfbThresholdLeft[sfb+sfboffs], sfbThresholdRight[sfb+sfboffs])*scaleMinThres;
          pnlr = (sfbThresholdLeft[sfb+sfboffs]/
                 max(sfbEnergyLeft[sfb+sfboffs],sfbThresholdLeft[sfb+sfboffs]))*
                 (sfbThresholdRight[sfb+sfboffs]/
                 max(sfbEnergyRight[sfb+sfboffs],sfbThresholdRight[sfb+sfboffs]));
          pnms = (minThreshold/max(sfbEnergyMid[sfb+sfboffs],minThreshold))*
                 (minThreshold/max(sfbEnergySide[sfb+sfboffs],minThreshold));
          useMS = (pnms > pnlr);
*/

          /* we assume that scaleMinThres == 1.0f and we can drop it */
          minThresholdLdData = fixMin(sfbThresholdLeftLdData[sfb+sfboffs], sfbThresholdRightLdData[sfb+sfboffs]);

          /* pnlrLdData = sfbThresholdLeftLdData[sfb+sfboffs] -
                        max(sfbEnergyLeftLdData[sfb+sfboffs], sfbThresholdLeftLdData[sfb+sfboffs]) +
                        sfbThresholdRightLdData[sfb+sfboffs] -
                        max(sfbEnergyRightLdData[sfb+sfboffs], sfbThresholdRightLdData[sfb+sfboffs]); */
          tmp = fixMax(sfbEnergyLeftLdData[sfb+sfboffs], sfbThresholdLeftLdData[sfb+sfboffs]);
          pnlrLdData = (sfbThresholdLeftLdData[sfb+sfboffs]>>1) - (tmp>>1);
          pnlrLdData = pnlrLdData + (sfbThresholdRightLdData[sfb+sfboffs]>>1);
          tmp = fixMax(sfbEnergyRightLdData[sfb+sfboffs], sfbThresholdRightLdData[sfb+sfboffs]);
          pnlrLdData = pnlrLdData - (tmp>>1);

          /* pnmsLdData = minThresholdLdData - max(sfbEnergyMidLdData[sfb+sfboffs], minThresholdLdData) +
                        minThresholdLdData - max(sfbEnergySideLdData[sfb+sfboffs], minThresholdLdData); */
          tmp = fixMax(sfbEnergyMidLdData[sfb+sfboffs], minThresholdLdData);
          pnmsLdData = minThresholdLdData - (tmp>>1);
          tmp = fixMax(sfbEnergySideLdData[sfb+sfboffs], minThresholdLdData);
          pnmsLdData = pnmsLdData - (tmp>>1);
          useMS = (pnmsLdData > (pnlrLdData));


          if (useMS) {
            msMask[sfb+sfboffs] = 1;
            msMaskTrueSomewhere = 1;
            for(j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
              FIXP_DBL specL, specR;
              specL = mdctSpectrumLeft[j]>>1;
              specR = mdctSpectrumRight[j]>>1;
              mdctSpectrumLeft[j] = specL + specR;
              mdctSpectrumRight[j] = specL - specR;
            }
            minThreshold = fixMin(sfbThresholdLeft[sfb+sfboffs], sfbThresholdRight[sfb+sfboffs]);
            sfbThresholdLeft[sfb+sfboffs] = sfbThresholdRight[sfb+sfboffs] = minThreshold;
            sfbThresholdLeftLdData[sfb+sfboffs] = sfbThresholdRightLdData[sfb+sfboffs] = minThresholdLdData;
            sfbEnergyLeft[sfb+sfboffs] = sfbEnergyMid[sfb+sfboffs];
            sfbEnergyRight[sfb+sfboffs] = sfbEnergySide[sfb+sfboffs];
            sfbEnergyLeftLdData[sfb+sfboffs] = sfbEnergyMidLdData[sfb+sfboffs];
            sfbEnergyRightLdData[sfb+sfboffs] = sfbEnergySideLdData[sfb+sfboffs];

            sfbSpreadEnLeft[sfb+sfboffs] = sfbSpreadEnRight[sfb+sfboffs] =
                     fixMin( sfbSpreadEnLeft[sfb+sfboffs],
                             sfbSpreadEnRight[sfb+sfboffs] ) >> 1;

          }
          else {
            msMask[sfb+sfboffs] = 0;
            numMsMaskFalse++;
          } /* useMS */
        } /* isBook */
        else {
          /* keep mDigest from IS module */
          if (msMask[sfb+sfboffs]) {
            msMaskTrueSomewhere = 1;
          }
          /* prohibit MS_MASK_ALL in combination with IS */
          numMsMaskFalse = 9;
        } /* isBook */
      } /* sfboffs */
    } /* sfb */


    if(msMaskTrueSomewhere == 1) {
      if ((numMsMaskFalse == 0) || ((numMsMaskFalse < maxSfbPerGroup) && (numMsMaskFalse < 9))) {
        *msDigest = SI_MS_MASK_ALL;
        /* loop through M/S bands; if msMask==0, set it to 1 and apply M/S */
        for (sfb = 0; sfb < sfbCnt; sfb += sfbPerGroup) {
          for (sfboffs = 0; sfboffs < maxSfbPerGroup; sfboffs++) {
            if (( (isBook == NULL) ? 1 : (isBook[sfb+sfboffs] == 0) ) && (msMask[sfb+sfboffs] == 0)) {
              msMask[sfb+sfboffs] = 1;
              /* apply M/S coding */
              for(j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
                FIXP_DBL specL, specR;
                specL = mdctSpectrumLeft[j]>>1;
                specR = mdctSpectrumRight[j]>>1;
                mdctSpectrumLeft[j] = specL + specR;
                mdctSpectrumRight[j] = specL - specR;
              }
              minThreshold = fixMin(sfbThresholdLeft[sfb+sfboffs], sfbThresholdRight[sfb+sfboffs]);
              sfbThresholdLeft[sfb+sfboffs] = sfbThresholdRight[sfb+sfboffs] = minThreshold;
              minThresholdLdData = fixMin(sfbThresholdLeftLdData[sfb+sfboffs], sfbThresholdRightLdData[sfb+sfboffs]);
              sfbThresholdLeftLdData[sfb+sfboffs] = sfbThresholdRightLdData[sfb+sfboffs] = minThresholdLdData;
              sfbEnergyLeft[sfb+sfboffs] = sfbEnergyMid[sfb+sfboffs];
              sfbEnergyRight[sfb+sfboffs] = sfbEnergySide[sfb+sfboffs];
              sfbEnergyLeftLdData[sfb+sfboffs] = sfbEnergyMidLdData[sfb+sfboffs];
              sfbEnergyRightLdData[sfb+sfboffs] = sfbEnergySideLdData[sfb+sfboffs];

              sfbSpreadEnLeft[sfb+sfboffs] = sfbSpreadEnRight[sfb+sfboffs] =
                       fixMin( sfbSpreadEnLeft[sfb+sfboffs],
                               sfbSpreadEnRight[sfb+sfboffs] ) >> 1;
            }
          }
        }
      } else {
        *msDigest = SI_MS_MASK_SOME;
      }
    } else {
      *msDigest = SI_MS_MASK_NONE;
    }
}