path: root/fdk-aac/libDRCdec/src/drcGainDec_process.cpp

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

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----------------------------------------------------------------------------- */

/************************* MPEG-D DRC decoder library **************************

   Author(s):

   Description:

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

#include "drcDec_types.h"
#include "drcDec_gainDecoder.h"
#include "drcGainDec_process.h"

#define E_TGAINSTEP 12

static DRC_ERROR _prepareLnbIndex(ACTIVE_DRC* pActiveDrc,
                                  const int channelOffset,
                                  const int drcChannelOffset,
                                  const int numChannelsProcessed,
                                  const int lnbPointer) {
  int g, c;
  DRC_INSTRUCTIONS_UNI_DRC* pInst = pActiveDrc->pInst;

  /* channelOffset: start index of physical channels
     numChannelsProcessed: number of processed channels, physical channels and
     DRC channels channelOffset + drcChannelOffset: start index of DRC channels,
        i.e. the channel order referenced in pInst.sequenceIndex */

  /* sanity checks */
  if ((channelOffset + numChannelsProcessed) > 8) return DE_NOT_OK;

  if ((channelOffset + drcChannelOffset + numChannelsProcessed) > 8)
    return DE_NOT_OK;

  if ((channelOffset + drcChannelOffset) < 0) return DE_NOT_OK;

  /* prepare lnbIndexForChannel, a map of indices from each channel to its
   * corresponding linearNodeBuffer instance */
  for (c = channelOffset; c < channelOffset + numChannelsProcessed; c++) {
    if (pInst->drcSetId > 0) {
      int drcChannel = c + drcChannelOffset;
      /* fallback for configuration with more physical channels than DRC
         channels: reuse DRC gain of first channel. This is necessary for HE-AAC
         mono with stereo output */
      if (drcChannel >= pInst->drcChannelCount) drcChannel = 0;
      g = pActiveDrc->channelGroupForChannel[drcChannel];
      if ((g >= 0) && !pActiveDrc->channelGroupIsParametricDrc[g]) {
        pActiveDrc->lnbIndexForChannel[c][lnbPointer] =
            pActiveDrc->activeDrcOffset + pActiveDrc->gainElementForGroup[g];
      }
    }
  }

  return DE_OK;
}

static DRC_ERROR _interpolateDrcGain(
    const GAIN_INTERPOLATION_TYPE gainInterpolationType,
    const SHORT timePrev,  /* time0 */
    const SHORT tGainStep, /* time1 - time0 */
    const SHORT start, const SHORT stop, const SHORT stepsize,
    const FIXP_DBL gainLeft, const FIXP_DBL gainRight, const FIXP_DBL slopeLeft,
    const FIXP_DBL slopeRight, FIXP_DBL* buffer) {
  int n, n_buf;
  int start_modulo, start_offset;

  if (tGainStep < 0) {
    return DE_NOT_OK;
  }
  if (tGainStep == 0) {
    return DE_OK;
  }

  /* get start index offset and buffer index for downsampled interpolation */
  /* start_modulo = (start+timePrev)%stepsize; */ /* stepsize is a power of 2 */
  start_modulo = (start + timePrev) & (stepsize - 1);
  start_offset = (start_modulo ? stepsize - start_modulo : 0);
  /* n_buf = (start + timePrev + start_offset)/stepsize; */
  n_buf = (start + timePrev + start_offset) >> (15 - fixnormz_S(stepsize));

  { /* gainInterpolationType == GIT_LINEAR */
    LONG a;
    /* runs = ceil((stop - start - start_offset)/stepsize). This works for
     * stepsize = 2^N only. */
    INT runs = (INT)(stop - start - start_offset + stepsize - 1) >>
               (30 - CountLeadingBits(stepsize));
    INT n_min = fMin(
        fMin(CntLeadingZeros(gainRight), CntLeadingZeros(gainLeft)) - 1, 8);
    a = (LONG)((gainRight << n_min) - (gainLeft << n_min)) / tGainStep;
    LONG a_step = a * stepsize;
    n = start + start_offset;
    a = a * n + (LONG)(gainLeft << n_min);
    buffer += n_buf;
#if defined(FUNCTION_interpolateDrcGain_func1)
    interpolateDrcGain_func1(buffer, a, a_step, n_min, runs);
#else
    a -= a_step;
    n_min = 8 - n_min;
    for (int i = 0; i < runs; i++) {
      a += a_step;
      buffer[i] = fMultDiv2(buffer[i], (FIXP_DBL)a) << n_min;
    }
#endif /* defined(FUNCTION_interpolateDrcGain_func1) */
  }
  return DE_OK;
}

static DRC_ERROR _processNodeSegments(
    const int frameSize, const GAIN_INTERPOLATION_TYPE gainInterpolationType,
    const int nNodes, const NODE_LIN* pNodeLin, const int offset,
    const SHORT stepsize,
    const NODE_LIN nodePrevious, /* the last node of the previous frame */
    const FIXP_DBL channelGain, FIXP_DBL* buffer) {
  DRC_ERROR err = DE_OK;
  SHORT timePrev, duration, start, stop, time;
  int n;
  FIXP_DBL gainLin = FL2FXCONST_DBL(1.0f / (float)(1 << 7)), gainLinPrev;
  FIXP_DBL slopeLin = (FIXP_DBL)0, slopeLinPrev = (FIXP_DBL)0;

  timePrev = nodePrevious.time + offset;
  gainLinPrev = nodePrevious.gainLin;
  for (n = 0; n < nNodes; n++) {
    time = pNodeLin[n].time + offset;
    duration = time - timePrev;
    gainLin = pNodeLin[n].gainLin;
    if (channelGain != FL2FXCONST_DBL(1.0f / (float)(1 << 8)))
      gainLin =
          SATURATE_LEFT_SHIFT(fMultDiv2(gainLin, channelGain), 9, DFRACT_BITS);

    if ((timePrev >= (frameSize - 1)) ||
        (time < 0)) { /* This segment (between previous and current node) lies
                         outside of this audio frame */
      timePrev = time;
      gainLinPrev = gainLin;
      slopeLinPrev = slopeLin;
      continue;
    }

    /* start and stop are the boundaries of the region of this segment that lie
       within this audio frame. Their values are relative to the beginning of
       this segment. stop is the first sample that isn't processed any more. */
    start = fMax(-timePrev, 1);
    stop = fMin(time, (SHORT)(frameSize - 1)) - timePrev + 1;

    err = _interpolateDrcGain(gainInterpolationType, timePrev, duration, start,
                              stop, stepsize, gainLinPrev, gainLin,
                              slopeLinPrev, slopeLin, buffer);
    if (err) return err;

    timePrev = time;
    gainLinPrev = gainLin;
  }
  return err;
}

/* process DRC on time-domain signal */
DRC_ERROR
processDrcTime(HANDLE_DRC_GAIN_DECODER hGainDec, const int activeDrcIndex,
               const int delaySamples, const int channelOffset,
               const int drcChannelOffset, const int numChannelsProcessed,
               const int timeDataChannelOffset, FIXP_DBL* deinterleavedAudio) {
  DRC_ERROR err = DE_OK;
  int c, b, i;
  ACTIVE_DRC* pActiveDrc = &(hGainDec->activeDrc[activeDrcIndex]);
  DRC_GAIN_BUFFERS* pDrcGainBuffers = &(hGainDec->drcGainBuffers);
  int lnbPointer = pDrcGainBuffers->lnbPointer, lnbIx;
  LINEAR_NODE_BUFFER* pLinearNodeBuffer = pDrcGainBuffers->linearNodeBuffer;
  LINEAR_NODE_BUFFER* pDummyLnb = &(pDrcGainBuffers->dummyLnb);
  int offset = 0;

  if (hGainDec->delayMode == DM_REGULAR_DELAY) {
    offset = hGainDec->frameSize;
  }

  if ((delaySamples + offset) >
      (NUM_LNB_FRAMES - 2) *
          hGainDec->frameSize) /* if delaySamples is too big, NUM_LNB_FRAMES
                                  should be increased */
    return DE_NOT_OK;

  err = _prepareLnbIndex(pActiveDrc, channelOffset, drcChannelOffset,
                         numChannelsProcessed, lnbPointer);
  if (err) return err;

  deinterleavedAudio +=
      channelOffset * timeDataChannelOffset; /* apply channelOffset */

  /* signal processing loop */
  for (c = channelOffset; c < channelOffset + numChannelsProcessed; c++) {
    if (activeDrcIndex == hGainDec->channelGainActiveDrcIndex)
      pDrcGainBuffers->channelGain[c][lnbPointer] = hGainDec->channelGain[c];

    b = 0;
    {
      LINEAR_NODE_BUFFER *pLnb, *pLnbPrevious;
      NODE_LIN nodePrevious;
      int lnbPointerDiff;
      FIXP_DBL channelGain;
      /* get pointer to oldest linearNodes */
      lnbIx = lnbPointer + 1 - NUM_LNB_FRAMES;
      while (lnbIx < 0) lnbIx += NUM_LNB_FRAMES;

      if (activeDrcIndex == hGainDec->channelGainActiveDrcIndex)
        channelGain = pDrcGainBuffers->channelGain[c][lnbIx];
      else
        channelGain = FL2FXCONST_DBL(1.0f / (float)(1 << 8));

      /* Loop over all node buffers in linearNodeBuffer.
         All nodes which are not relevant for the current frame are sorted out
         inside _processNodeSegments. */
      for (i = 0; i < NUM_LNB_FRAMES - 1; i++) {
        /* Prepare previous node */
        if (pActiveDrc->lnbIndexForChannel[c][lnbIx] >= 0)
          pLnbPrevious = &(
              pLinearNodeBuffer[pActiveDrc->lnbIndexForChannel[c][lnbIx] + b]);
        else
          pLnbPrevious = pDummyLnb;
        nodePrevious =
            pLnbPrevious->linearNode[lnbIx][pLnbPrevious->nNodes[lnbIx] - 1];
        nodePrevious.time -= hGainDec->frameSize;
        if (channelGain != FL2FXCONST_DBL(1.0f / (float)(1 << 8)))
          nodePrevious.gainLin = SATURATE_LEFT_SHIFT(
              fMultDiv2(nodePrevious.gainLin,
                        pDrcGainBuffers->channelGain[c][lnbIx]),
              9, DFRACT_BITS);

        /* Prepare current linearNodeBuffer instance */
        lnbIx++;
        if (lnbIx >= NUM_LNB_FRAMES) lnbIx = 0;

        /* if lnbIndexForChannel changes over time, use the old indices for
         * smooth transitions */
        if (pActiveDrc->lnbIndexForChannel[c][lnbIx] >= 0)
          pLnb = &(
              pLinearNodeBuffer[pActiveDrc->lnbIndexForChannel[c][lnbIx] + b]);
        else /* lnbIndexForChannel = -1 means "no DRC processing", due to
                drcInstructionsIndex < 0, drcSetId < 0 or channel group < 0 */
          pLnb = pDummyLnb;

        if (activeDrcIndex == hGainDec->channelGainActiveDrcIndex)
          channelGain = pDrcGainBuffers->channelGain[c][lnbIx];

        /* number of frames of offset with respect to lnbPointer */
        lnbPointerDiff = i - (NUM_LNB_FRAMES - 2);

        err = _processNodeSegments(
            hGainDec->frameSize, pLnb->gainInterpolationType,
            pLnb->nNodes[lnbIx], pLnb->linearNode[lnbIx],
            lnbPointerDiff * hGainDec->frameSize + delaySamples + offset, 1,
            nodePrevious, channelGain, deinterleavedAudio);
        if (err) return err;
      }
      deinterleavedAudio += timeDataChannelOffset; /* proceed to next channel */
    }
  }
  return DE_OK;
}

/* process DRC on subband-domain signal */
DRC_ERROR
processDrcSubband(HANDLE_DRC_GAIN_DECODER hGainDec, const int activeDrcIndex,
                  const int delaySamples, const int channelOffset,
                  const int drcChannelOffset, const int numChannelsProcessed,
                  const int processSingleTimeslot,
                  FIXP_DBL* deinterleavedAudioReal[],
                  FIXP_DBL* deinterleavedAudioImag[]) {
  DRC_ERROR err = DE_OK;
  int b, c, g, m, m_start, m_stop, s, i;
  FIXP_DBL gainSb;
  DRC_INSTRUCTIONS_UNI_DRC* pInst = hGainDec->activeDrc[activeDrcIndex].pInst;
  DRC_GAIN_BUFFERS* pDrcGainBuffers = &(hGainDec->drcGainBuffers);
  ACTIVE_DRC* pActiveDrc = &(hGainDec->activeDrc[activeDrcIndex]);
  int activeDrcOffset = pActiveDrc->activeDrcOffset;
  int lnbPointer = pDrcGainBuffers->lnbPointer, lnbIx;
  LINEAR_NODE_BUFFER* pLinearNodeBuffer = pDrcGainBuffers->linearNodeBuffer;
  FIXP_DBL(*subbandGains)[4 * 1024 / 256] = hGainDec->subbandGains;
  FIXP_DBL* dummySubbandGains = hGainDec->dummySubbandGains;
  SUBBAND_DOMAIN_MODE subbandDomainMode = hGainDec->subbandDomainSupported;
  int signalIndex = 0;
  int frameSizeSb = 0;
  int nDecoderSubbands;
  SHORT L = 0; /* L: downsampling factor */
  int offset = 0;
  FIXP_DBL *audioReal = NULL, *audioImag = NULL;

  if (hGainDec->delayMode == DM_REGULAR_DELAY) {
    offset = hGainDec->frameSize;
  }

  if ((delaySamples + offset) >
      (NUM_LNB_FRAMES - 2) *
          hGainDec->frameSize) /* if delaySamples is too big, NUM_LNB_FRAMES
                                  should be increased */
    return DE_NOT_OK;

  switch (subbandDomainMode) {
#if ((1024 / 256) >= (4096 / SUBBAND_DOWNSAMPLING_FACTOR_QMF64))
    case SDM_QMF64:
      nDecoderSubbands = SUBBAND_NUM_BANDS_QMF64;
      L = SUBBAND_DOWNSAMPLING_FACTOR_QMF64;
      /* analysisDelay = SUBBAND_ANALYSIS_DELAY_QMF64; */
      break;
    case SDM_QMF71:
      nDecoderSubbands = SUBBAND_NUM_BANDS_QMF71;
      L = SUBBAND_DOWNSAMPLING_FACTOR_QMF71;
      /* analysisDelay = SUBBAND_ANALYSIS_DELAY_QMF71; */
      break;
#else
    case SDM_QMF64:
    case SDM_QMF71:
      /* QMF domain processing is not supported. */
      return DE_NOT_OK;
#endif
    case SDM_STFT256:
      nDecoderSubbands = SUBBAND_NUM_BANDS_STFT256;
      L = SUBBAND_DOWNSAMPLING_FACTOR_STFT256;
      /* analysisDelay = SUBBAND_ANALYSIS_DELAY_STFT256; */
      break;
    default:
      return DE_NOT_OK;
  }

  /* frameSizeSb = hGainDec->frameSize/L; */ /* L is a power of 2 */
  frameSizeSb =
      hGainDec->frameSize >> (15 - fixnormz_S(L)); /* timeslots per frame */

  if ((processSingleTimeslot < 0) || (processSingleTimeslot >= frameSizeSb)) {
    m_start = 0;
    m_stop = frameSizeSb;
  } else {
    m_start = processSingleTimeslot;
    m_stop = m_start + 1;
  }

  err = _prepareLnbIndex(pActiveDrc, channelOffset, drcChannelOffset,
                         numChannelsProcessed, lnbPointer);
  if (err) return err;

  if (!pActiveDrc->subbandGainsReady) /* only for the first time per frame that
                                         processDrcSubband is called */
  {
    /* write subbandGains */
    for (g = 0; g < pInst->nDrcChannelGroups; g++) {
      b = 0;
      {
        LINEAR_NODE_BUFFER* pLnb =
            &(pLinearNodeBuffer[activeDrcOffset +
                                pActiveDrc->gainElementForGroup[g] + b]);
        NODE_LIN nodePrevious;
        int lnbPointerDiff;

        for (m = 0; m < frameSizeSb; m++) {
          subbandGains[activeDrcOffset + g][b * frameSizeSb + m] =
              FL2FXCONST_DBL(1.0f / (float)(1 << 7));
        }

        lnbIx = lnbPointer - (NUM_LNB_FRAMES - 1);
        while (lnbIx < 0) lnbIx += NUM_LNB_FRAMES;

        /* Loop over all node buffers in linearNodeBuffer.
           All nodes which are not relevant for the current frame are sorted out
           inside _processNodeSegments. */
        for (i = 0; i < NUM_LNB_FRAMES - 1; i++) {
          /* Prepare previous node */
          nodePrevious = pLnb->linearNode[lnbIx][pLnb->nNodes[lnbIx] - 1];
          nodePrevious.time -= hGainDec->frameSize;

          lnbIx++;
          if (lnbIx >= NUM_LNB_FRAMES) lnbIx = 0;

          /* number of frames of offset with respect to lnbPointer */
          lnbPointerDiff = i - (NUM_LNB_FRAMES - 2);

          err = _processNodeSegments(
              hGainDec->frameSize, pLnb->gainInterpolationType,
              pLnb->nNodes[lnbIx], pLnb->linearNode[lnbIx],
              lnbPointerDiff * hGainDec->frameSize + delaySamples + offset -
                  (L - 1) / 2,
              L, nodePrevious, FL2FXCONST_DBL(1.0f / (float)(1 << 8)),
              &(subbandGains[activeDrcOffset + g][b * frameSizeSb]));
          if (err) return err;
        }
      }
    }
    pActiveDrc->subbandGainsReady = 1;
  }

  for (c = channelOffset; c < channelOffset + numChannelsProcessed; c++) {
    FIXP_DBL* thisSubbandGainsBuffer;
    if (pInst->drcSetId > 0)
      g = pActiveDrc->channelGroupForChannel[c + drcChannelOffset];
    else
      g = -1;

    audioReal = deinterleavedAudioReal[signalIndex];
    if (subbandDomainMode != SDM_STFT256) {
      audioImag = deinterleavedAudioImag[signalIndex];
    }

    if ((g >= 0) && !pActiveDrc->channelGroupIsParametricDrc[g]) {
      thisSubbandGainsBuffer = subbandGains[activeDrcOffset + g];
    } else {
      thisSubbandGainsBuffer = dummySubbandGains;
    }

    for (m = m_start; m < m_stop; m++) {
      INT n_min = 8;
      { /* single-band DRC */
        gainSb = thisSubbandGainsBuffer[m];
        if (activeDrcIndex == hGainDec->channelGainActiveDrcIndex)
          gainSb = SATURATE_LEFT_SHIFT(
              fMultDiv2(gainSb, hGainDec->channelGain[c]), 9, DFRACT_BITS);
        /* normalize gainSb for keeping signal precision */
        n_min = fMin(CntLeadingZeros(gainSb) - 1, n_min);
        gainSb <<= n_min;
        n_min = 8 - n_min;
        if (subbandDomainMode ==
            SDM_STFT256) { /* For STFT filterbank, real and imaginary parts are
                              interleaved. */
          for (s = 0; s < nDecoderSubbands; s++) {
            *audioReal = fMultDiv2(*audioReal, gainSb) << n_min;
            audioReal++;
            *audioReal = fMultDiv2(*audioReal, gainSb) << n_min;
            audioReal++;
          }
        } else {
          for (s = 0; s < nDecoderSubbands; s++) {
            *audioReal = fMultDiv2(*audioReal, gainSb) << n_min;
            audioReal++;
            *audioImag = fMultDiv2(*audioImag, gainSb) << n_min;
            audioImag++;
          }
        }
      }
    }
    signalIndex++;
  }
  return DE_OK;
}