xref: /external/aac/libAACdec/src/aacdec_pns.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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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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Attention: Audio and Multimedia Departments - FDK AAC LL
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----------------------------------------------------------------------------------------------------------- */

/*****************************  MPEG-4 AAC Decoder  **************************

   Author(s):   Josef Hoepfl
   Description: perceptual noise substitution tool

******************************************************************************/

#include "aacdec_pns.h"


#include "aac_ram.h"
#include "aac_rom.h"
#include "channelinfo.h"
#include "block.h"
#include "FDK_bitstream.h"

#include "genericStds.h"


#define NOISE_OFFSET 90           /* cf. ISO 14496-3 p. 175 */

/*!
  \brief Reset InterChannel and PNS data

  The function resets the InterChannel and PNS data
*/
void CPns_ResetData(
    CPnsData *pPnsData,
    CPnsInterChannelData *pPnsInterChannelData
    )
{
  /* Assign pointer always, since pPnsData is not persistent data */
  pPnsData->pPnsInterChannelData = pPnsInterChannelData;
  pPnsData->PnsActive = 0;
  pPnsData->CurrentEnergy = 0;

  FDKmemclear(pPnsData->pnsUsed,(8*16)*sizeof(UCHAR));
  FDKmemclear(pPnsInterChannelData->correlated,(8*16)*sizeof(UCHAR));
}

/*!
  \brief Initialize PNS data

  The function initializes the PNS data
*/
void CPns_InitPns(
    CPnsData *pPnsData,
    CPnsInterChannelData *pPnsInterChannelData,
    INT* currentSeed, INT* randomSeed)
{
  /* save pointer to inter channel data */
  pPnsData->pPnsInterChannelData = pPnsInterChannelData;

  /* use pointer because seed has to be
     same, left and right channel ! */
  pPnsData->currentSeed = currentSeed;
  pPnsData->randomSeed  = randomSeed;
}

/*!
  \brief Indicates if PNS is used

  The function returns a value indicating whether PNS is used or not
  acordding to the noise energy

  \return  PNS used
*/
int CPns_IsPnsUsed (const CPnsData *pPnsData,
                    const int group,
                    const int band)
{
  unsigned pns_band = group*16+band;

  return pPnsData->pnsUsed[pns_band] & (UCHAR)1;
}

/*!
  \brief Set correlation

  The function activates the noise correlation between the channel pair
*/
void CPns_SetCorrelation(CPnsData *pPnsData,
                         const int group,
                         const int band,
                         const int outofphase)
{
  CPnsInterChannelData *pInterChannelData = pPnsData->pPnsInterChannelData;
  unsigned pns_band = group*16+band;

  pInterChannelData->correlated[pns_band] = (outofphase) ? 3 : 1;
}

/*!
  \brief Indicates if correlation is used

  The function indicates if the noise correlation between the channel pair
  is activated

  \return  PNS is correlated
*/
static
int CPns_IsCorrelated(const CPnsData *pPnsData,
                      const int group,
                      const int band)
{
  CPnsInterChannelData *pInterChannelData = pPnsData->pPnsInterChannelData;
  unsigned pns_band = group*16+band;

  return (pInterChannelData->correlated[pns_band] & 0x01) ? 1 : 0;
}

/*!
  \brief Indicates if correlated out of phase mode is used.

  The function indicates if the noise correlation between the channel pair
  is activated in out-of-phase mode.

  \return  PNS is out-of-phase
*/
static
int CPns_IsOutOfPhase(const CPnsData *pPnsData,
                      const int group,
                      const int band)
{
  CPnsInterChannelData *pInterChannelData = pPnsData->pPnsInterChannelData;
  unsigned pns_band = group*16+band;

  return (pInterChannelData->correlated[pns_band] & 0x02) ? 1 : 0;
}

/*!
  \brief Read PNS information

  The function reads the PNS information from the bitstream
*/
void CPns_Read (CPnsData *pPnsData,
                HANDLE_FDK_BITSTREAM bs,
                const CodeBookDescription *hcb,
                SHORT *pScaleFactor,
                UCHAR global_gain,
                int band,
                int group /* = 0 */)
{
  int delta ;
  UINT pns_band = group*16+band;

  if (pPnsData->PnsActive) {
    /* Next PNS band case */
    delta = CBlock_DecodeHuffmanWord (bs, hcb) - 60;
  } else {
    /* First PNS band case */
    int noiseStartValue = FDKreadBits(bs,9);

    delta = noiseStartValue - 256 ;
    pPnsData->PnsActive = 1;
    pPnsData->CurrentEnergy = global_gain - NOISE_OFFSET;
  }

  pPnsData->CurrentEnergy += delta ;
  pScaleFactor[pns_band] = pPnsData->CurrentEnergy;

  pPnsData->pnsUsed[pns_band] = 1;
}


/**
 * \brief Generate a vector of noise of given length. The noise values are
 *        scaled in order to yield a noise energy of 1.0
 * \param spec pointer to were the noise values will be written to.
 * \param size amount of noise values to be generated.
 * \param pRandomState pointer to the state of the random generator being used.
 * \return exponent of generated noise vector.
 */
static int GenerateRandomVector (FIXP_DBL *RESTRICT spec,
                                  int size,
                                  int *pRandomState)
{
  int i, invNrg_e = 0, nrg_e = 0;
  FIXP_DBL invNrg_m, nrg_m = FL2FXCONST_DBL(0.0f) ;
  FIXP_DBL *RESTRICT ptr = spec;
  int randomState = *pRandomState;

#define GEN_NOISE_NRG_SCALE 7

  /* Generate noise and calculate energy. */
  for (i=0; i<size; i++)
  {
    randomState = (1664525L * randomState) + 1013904223L; // Numerical Recipes
    nrg_m = fPow2AddDiv2(nrg_m, (FIXP_DBL)randomState>>GEN_NOISE_NRG_SCALE);
    *ptr++ = (FIXP_DBL)randomState;
  }
  nrg_e = GEN_NOISE_NRG_SCALE*2 + 1;

  /* weight noise with = 1 / sqrt_nrg; */
  invNrg_m = invSqrtNorm2(nrg_m<<1, &invNrg_e);
  invNrg_e += -((nrg_e-1)>>1);

  for (i=size; i--; )
  {
    spec[i] = fMult(spec[i], invNrg_m);
  }

  /* Store random state */
  *pRandomState = randomState;

  return invNrg_e;
}

static void ScaleBand (FIXP_DBL *RESTRICT spec, int size, int scaleFactor, int specScale, int noise_e, int out_of_phase)
{
  int i, shift, sfExponent;
  FIXP_DBL sfMatissa;

  /* Get gain from scale factor value = 2^(scaleFactor * 0.25) */
  sfMatissa = MantissaTable[scaleFactor & 0x03][0];
  /* sfExponent = (scaleFactor >> 2) + ExponentTable[scaleFactor & 0x03][0]; */
  /* Note:  ExponentTable[scaleFactor & 0x03][0] is always 1. */
  sfExponent = (scaleFactor >> 2) + 1;

  if (out_of_phase != 0) {
    sfMatissa = -sfMatissa;
  }

  /* +1 because of fMultDiv2 below. */
  shift = sfExponent - specScale + 1 + noise_e;

  /* Apply gain to noise values */
  if (shift>=0) {
    shift = fixMin( shift, DFRACT_BITS-1 );
    for (i = size ; i-- != 0; ) {
      spec [i] = fMultDiv2 (spec [i], sfMatissa) << shift;
    }
  } else {
    shift = fixMin( -shift, DFRACT_BITS-1 );
    for (i = size ; i-- != 0; ) {
      spec [i] = fMultDiv2 (spec [i], sfMatissa) >> shift;
    }
  }
}


/*!
  \brief Apply PNS

  The function applies PNS (i.e. it generates noise) on the bands
  flagged as noisy bands

*/
void CPns_Apply (const CPnsData *pPnsData,
                 const CIcsInfo *pIcsInfo,
                 SPECTRAL_PTR pSpectrum,
                 const SHORT    *pSpecScale,
                 const SHORT    *pScaleFactor,
                 const SamplingRateInfo *pSamplingRateInfo,
                 const INT granuleLength,
                 const int channel)
{
  if (pPnsData->PnsActive) {
    const short *BandOffsets = GetScaleFactorBandOffsets(pIcsInfo, pSamplingRateInfo);

    int ScaleFactorBandsTransmitted = GetScaleFactorBandsTransmitted(pIcsInfo);

    for (int window = 0, group = 0; group < GetWindowGroups(pIcsInfo); group++) {
      for (int groupwin = 0; groupwin < GetWindowGroupLength(pIcsInfo, group); groupwin++, window++) {
        FIXP_DBL *spectrum = SPEC(pSpectrum, window, granuleLength);

        for (int band = 0 ; band < ScaleFactorBandsTransmitted; band++) {
          if (CPns_IsPnsUsed (pPnsData, group, band)) {
            UINT pns_band = group*16+band;

            int bandWidth = BandOffsets [band + 1] - BandOffsets [band] ;
            int noise_e;

            FDK_ASSERT(bandWidth >= 0);

            if (channel > 0 && CPns_IsCorrelated(pPnsData, group, band))
            {
              noise_e = GenerateRandomVector (spectrum + BandOffsets [band], bandWidth,
                                    &pPnsData->randomSeed [pns_band]) ;
            }
            else
            {
              pPnsData->randomSeed [pns_band] = *pPnsData->currentSeed ;

              noise_e = GenerateRandomVector (spectrum + BandOffsets [band], bandWidth,
                                    pPnsData->currentSeed) ;
            }

            int outOfPhase  = CPns_IsOutOfPhase (pPnsData, group, band);

            ScaleBand (spectrum + BandOffsets [band], bandWidth,
                       pScaleFactor[pns_band],
                       pSpecScale[window], noise_e, outOfPhase) ;
          }
        }
      }
    }
  }
}