tran_det.cpp - Android社区 - https://www.androidos.net.cn/

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

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)
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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
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Redistribution and use in source and binary forms, with or without modification, are permitted without
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This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
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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
----------------------------------------------------------------------------------------------------------- */

#include "tran_det.h"

#include "fram_gen.h"
#include "sbr_ram.h"
#include "sbr_misc.h"

#include "genericStds.h"

#define NORM_QMF_ENERGY 5.684341886080801486968994140625e-14 /* 2^-44 */

/* static FIXP_DBL ABS_THRES = fixMax( FL2FXCONST_DBL(1.28e5 *  NORM_QMF_ENERGY), (FIXP_DBL)1)  Minimum threshold for detecting changes */
#define ABS_THRES ((FIXP_DBL)16)

/*******************************************************************************
 Functionname:  spectralChange
 *******************************************************************************
 \brief   Calculates a measure for the spectral change within the frame

The function says how good it would be to split the frame at the given border
 position into 2 envelopes.

The return value delta_sum is scaled with the factor 1/64

\return  calculated value
*******************************************************************************/
static FIXP_DBL spectralChange(FIXP_DBL Energies[NUMBER_TIME_SLOTS_2304][MAX_FREQ_COEFFS],
                               INT *scaleEnergies,
                               FIXP_DBL EnergyTotal,
                               INT nSfb,
                               INT start,
                               INT border,
                               INT stop)
{
  INT i,j;
  INT len1,len2;
  FIXP_DBL delta,tmp0,tmp1,tmp2;
  FIXP_DBL accu1,accu2,delta_sum,result;

FDK_ASSERT(scaleEnergies[0] >= 0);

/* equal for aac (would be not equal for mp3) */
  len1 = border-start;
  len2 = stop-border;

/* prefer borders near the middle of the frame */
  FIXP_DBL   pos_weight;
  pos_weight = FL2FXCONST_DBL(0.5f) - (len1*GetInvInt(len1+len2));
  pos_weight = /*FL2FXCONST_DBL(1.0)*/ (FIXP_DBL)MAXVAL_DBL - (fMult(pos_weight, pos_weight)<<2);

delta_sum = FL2FXCONST_DBL(0.0f);

/* Sum up energies of all QMF-timeslots for both halfs */
  for (j=0; j<nSfb; j++) {
    #define NRG_SCALE  3
    /* init with some energy to prevent division by zero
       and to prevent splitting for very low levels */
    accu1 = ((FL2FXCONST_DBL((1.0e6*NORM_QMF_ENERGY*8.0/32))) << fixMin(scaleEnergies[0],25))>>NRG_SCALE;  /* complex init for compare with original version */
    accu2 = ((FL2FXCONST_DBL((1.0e6*NORM_QMF_ENERGY*8.0/32))) << fixMin(scaleEnergies[0],25))>>NRG_SCALE;  /* can be simplified in dsp implementation */

/* Sum up energies in first half */
    for (i=start; i<border; i++) {
      accu1 += (Energies[i][j]>>NRG_SCALE);
    }

/* Sum up energies in second half */
    for (i=border; i<stop; i++) {
      accu2 += (Energies[i][j]>>NRG_SCALE);
    }

/* Energy change in current band */
    tmp0 = CalcLdData(accu2);
    tmp1 = CalcLdData(accu1);
    tmp2 = (tmp0 - tmp1 + CalcLdData(len1)-CalcLdData(len2));
    delta = fixp_abs(fMult(tmp2, FL2FXCONST_DBL(0.6931471806f)));

/* Weighting with amplitude ratio of this band */
    result = (EnergyTotal == FL2FXCONST_DBL(0.0f))
            ? FL2FXCONST_DBL(0.f)
            : FDKsbrEnc_LSI_divide_scale_fract( (accu1+accu2),
                                      (EnergyTotal>>NRG_SCALE)+(FIXP_DBL)1,
                                      (FIXP_DBL)MAXVAL_DBL >> fixMin(scaleEnergies[0],(DFRACT_BITS-1)) );

delta_sum += (FIXP_DBL)(fMult(sqrtFixp(result), delta));
  }

return fMult(delta_sum, pos_weight);
}

/*******************************************************************************
 Functionname:  addLowbandEnergies
 *******************************************************************************
 \brief   Calculates total lowband energy

The return value nrgTotal is scaled by the factor (1/32.0)

\return  total energy in the lowband
*******************************************************************************/
static FIXP_DBL addLowbandEnergies(FIXP_DBL **Energies,
                                   int       *scaleEnergies,
                                   int        YBufferWriteOffset,
                                   int        nrgSzShift,
                                   int        tran_off,
                                   UCHAR     *freqBandTable,
                                   int        slots)
{
  FIXP_DBL nrgTotal;
  FIXP_DBL accu1 = FL2FXCONST_DBL(0.0f);
  FIXP_DBL accu2 = FL2FXCONST_DBL(0.0f);
  int tran_offdiv2 = tran_off>>nrgSzShift;
  int ts,k;

/* Sum up lowband energy from one frame at offset tran_off */
  for (ts=tran_offdiv2; ts<YBufferWriteOffset; ts++) {
    for (k = 0; k < freqBandTable[0]; k++) {
      accu1 += Energies[ts][k] >> 6;
    }
  }
  for (; ts<tran_offdiv2+(slots>>nrgSzShift); ts++) {
    for (k = 0; k < freqBandTable[0]; k++) {
      accu2 += Energies[ts][k] >> 6;
    }
  }

nrgTotal = ( (accu1 >> fixMin(scaleEnergies[0],(DFRACT_BITS-1)))
           +   (accu2 >> fixMin(scaleEnergies[1],(DFRACT_BITS-1))) ) << (2);

return(nrgTotal);
}

/*******************************************************************************
 Functionname:  addHighbandEnergies
 *******************************************************************************
 \brief   Add highband energies

Highband energies are mapped to an array with smaller dimension:
 Its time resolution is only 1 SBR-timeslot and its frequency resolution
 is 1 SBR-band. Therefore the data to be fed into the spectralChange
 function is reduced.

The values EnergiesM are scaled by the factor (1/32.0) and scaleEnergies[0]
 The return value nrgTotal is scaled by the factor (1/32.0)

\return  total energy in the highband
*******************************************************************************/

static FIXP_DBL addHighbandEnergies(FIXP_DBL **RESTRICT Energies, /*!< input */
                                    INT       *scaleEnergies,
                                    FIXP_DBL   EnergiesM[NUMBER_TIME_SLOTS_2304][MAX_FREQ_COEFFS], /*!< Combined output */
                                    UCHAR     *RESTRICT freqBandTable,
                                    INT        nSfb,
                                    INT        sbrSlots,
                                    INT        timeStep)
{
  INT i,j,k,slotIn,slotOut,scale;
  INT li,ui;
  FIXP_DBL nrgTotal;
  FIXP_DBL accu = FL2FXCONST_DBL(0.0f);

/* Combine QMF-timeslots to SBR-timeslots,
     combine QMF-bands to SBR-bands,
     combine Left and Right channel */
  for (slotOut=0; slotOut<sbrSlots; slotOut++) {
    slotIn = 2*slotOut;

for (j=0; j<nSfb; j++) {
      accu = FL2FXCONST_DBL(0.0f);

li = freqBandTable[j];
      ui = freqBandTable[j + 1];

for (k=li; k<ui; k++) {
        for (i=0; i<timeStep; i++) {
         accu += (Energies[(slotIn+i)>>1][k] >> 5);
        }
      }
      EnergiesM[slotOut][j] = accu;
    }
  }

scale = fixMin(8,scaleEnergies[0]);      /* scale energies down before add up */

if ((scaleEnergies[0]-1) > (DFRACT_BITS-1) )
    nrgTotal = FL2FXCONST_DBL(0.0f);
  else {
    /* Now add all energies */
    accu = FL2FXCONST_DBL(0.0f);
    for (slotOut=0; slotOut<sbrSlots; slotOut++) {
      for (j=0; j<nSfb; j++) {
        accu += (EnergiesM[slotOut][j] >> scale);
      }
    }
    nrgTotal = accu >> (scaleEnergies[0]-scale);
  }

return(nrgTotal);
}

/*******************************************************************************
 Functionname:  FDKsbrEnc_frameSplitter
 *******************************************************************************
 \brief   Decides if a FIXFIX-frame shall be splitted into 2 envelopes

If no transient has been detected before, the frame can still be splitted
 into 2 envelopes.
*******************************************************************************/
void
FDKsbrEnc_frameSplitter(FIXP_DBL **Energies,
                        INT *scaleEnergies,
                        HANDLE_SBR_TRANSIENT_DETECTOR h_sbrTransientDetector,
                        UCHAR *freqBandTable,
                        UCHAR *tran_vector,
                        int YBufferWriteOffset,
                        int YBufferSzShift,
                        int nSfb,
                        int timeStep,
                        int no_cols)
{
  if (tran_vector[1]==0) /* no transient was detected */
  {
    FIXP_DBL delta;
    FIXP_DBL EnergiesM[NUMBER_TIME_SLOTS_2304][MAX_FREQ_COEFFS];
    FIXP_DBL EnergyTotal,newLowbandEnergy,newHighbandEnergy;
    INT border;
    INT sbrSlots = fMultI(GetInvInt(timeStep),no_cols);

FDK_ASSERT( sbrSlots * timeStep == no_cols );

/*
      Get Lowband-energy over a range of 2 frames (Look half a frame back and ahead).
    */
    newLowbandEnergy = addLowbandEnergies(Energies,
                                          scaleEnergies,
                                          YBufferWriteOffset,
                                          YBufferSzShift,
                                          h_sbrTransientDetector->tran_off,
                                          freqBandTable,
                                          no_cols);

newHighbandEnergy = addHighbandEnergies(Energies,
                                            scaleEnergies,
                                            EnergiesM,
                                            freqBandTable,
                                            nSfb,
                                            sbrSlots,
                                            timeStep);

if ( h_sbrTransientDetector->frameShift != 0 ) {
      if (tran_vector[1]==0)
        tran_vector[0] = 0;
    } else
    {
      /* prevLowBandEnergy: Corresponds to 1 frame, starting with half a frame look-behind
         newLowbandEnergy:  Corresponds to 1 frame, starting in the middle of the current frame */
      EnergyTotal = (newLowbandEnergy + h_sbrTransientDetector->prevLowBandEnergy) >> 1;
      EnergyTotal += newHighbandEnergy;
      /* The below border should specify the same position as the middle border
         of a FIXFIX-frame with 2 envelopes. */
      border = (sbrSlots+1) >> 1;

delta = spectralChange(EnergiesM,
                             scaleEnergies,
                             EnergyTotal,
                             nSfb,
                             0,
                             border,
                             sbrSlots);

if (delta > (h_sbrTransientDetector->split_thr >> LD_DATA_SHIFT)) /* delta scaled by 1/64 */
        tran_vector[0] = 1; /* Set flag for splitting */
      else
        tran_vector[0] = 0;
    }

/* Update prevLowBandEnergy */
    h_sbrTransientDetector->prevLowBandEnergy = newLowbandEnergy;
    h_sbrTransientDetector->prevHighBandEnergy = newHighbandEnergy;
  }
}

/*
 * Calculate transient energy threshold for each QMF band
 */
static void
calculateThresholds(FIXP_DBL **RESTRICT Energies,
                    INT       *RESTRICT scaleEnergies,
                    FIXP_DBL  *RESTRICT thresholds,
                    int        YBufferWriteOffset,
                    int        YBufferSzShift,
                    int        noCols,
                    int        noRows,
                    int        tran_off)
{
  FIXP_DBL mean_val,std_val,temp;
  FIXP_DBL i_noCols;
  FIXP_DBL i_noCols1;
  FIXP_DBL accu,accu0,accu1;
  int scaleFactor0,scaleFactor1,commonScale;
  int i,j;

i_noCols  = GetInvInt(noCols + tran_off ) << YBufferSzShift;
  i_noCols1 = GetInvInt(noCols + tran_off - 1) << YBufferSzShift;

/* calc minimum scale of energies of previous and current frame */
  commonScale = fixMin(scaleEnergies[0],scaleEnergies[1]);

/* calc scalefactors to adapt energies to common scale */
  scaleFactor0 = fixMin((scaleEnergies[0]-commonScale), (DFRACT_BITS-1));
  scaleFactor1 = fixMin((scaleEnergies[1]-commonScale), (DFRACT_BITS-1));

FDK_ASSERT((scaleFactor0 >= 0) && (scaleFactor1 >= 0));

/* calculate standard deviation in every subband */
  for (i=0; i<noRows; i++)
  {
    int startEnergy = (tran_off>>YBufferSzShift);
    int endEnergy = ((noCols>>YBufferSzShift)+tran_off);
    int shift;

/* calculate mean value over decimated energy values (downsampled by 2). */
    accu0 = accu1 = FL2FXCONST_DBL(0.0f);

for (j=startEnergy; j<YBufferWriteOffset; j++)
      accu0 += fMult(Energies[j][i], i_noCols);
    for (; j<endEnergy; j++)
      accu1 += fMult(Energies[j][i], i_noCols);

mean_val = (accu0 >> scaleFactor0) + (accu1 >> scaleFactor1);  /* average */
    shift    = fixMax(0,CountLeadingBits(mean_val)-6);             /* -6 to keep room for accumulating upto N = 24 values */

/* calculate standard deviation */
    accu = FL2FXCONST_DBL(0.0f);

/* summe { ((mean_val-nrg)^2) * i_noCols1 } */
    for (j=startEnergy; j<YBufferWriteOffset; j++) {
      temp = ((FIXP_DBL)mean_val - ((FIXP_DBL)Energies[j][i] >> scaleFactor0))<<shift;
      temp = fPow2(temp);
      temp = fMult(temp, i_noCols1);
      accu += temp;
    }
    for (; j<endEnergy; j++) {
      temp = ((FIXP_DBL)mean_val - ((FIXP_DBL)Energies[j][i] >> scaleFactor1))<<shift;
      temp = fPow2(temp);
      temp = fMult(temp, i_noCols1);
      accu += temp;
    }

std_val = sqrtFixp(accu)>>shift;     /* standard deviation */

/*
    Take new threshold as average of calculated standard deviation ratio
    and old threshold if greater than absolute threshold
    */
    temp = ( commonScale<=(DFRACT_BITS-1) )
            ? fMult(FL2FXCONST_DBL(0.66f), thresholds[i]) + (fMult(FL2FXCONST_DBL(0.34f), std_val) >> commonScale)
            : (FIXP_DBL) 0;

thresholds[i] = fixMax(ABS_THRES,temp);

FDK_ASSERT(commonScale >= 0);
  }
}

/*
 * Calculate transient levels for each QMF time slot.
 */
static void
extractTransientCandidates(FIXP_DBL  **RESTRICT Energies,
                           INT        *RESTRICT scaleEnergies,
                           FIXP_DBL   *RESTRICT thresholds,
                           FIXP_DBL   *RESTRICT transients,
                           int         YBufferWriteOffset,
                           int         YBufferSzShift,
                           int         noCols,
                           int         start_band,
                           int         stop_band,
                           int         tran_off,
                           int         addPrevSamples)
{
  FIXP_DBL i_thres;
  C_ALLOC_SCRATCH_START(EnergiesTemp, FIXP_DBL, 2*QMF_MAX_TIME_SLOTS);
  FIXP_DBL *RESTRICT pEnergiesTemp = EnergiesTemp;
  int tmpScaleEnergies0, tmpScaleEnergies1;
  int endCond;
  int startEnerg,endEnerg;
  int i,j,jIndex,jpBM;

tmpScaleEnergies0 = scaleEnergies[0];
  tmpScaleEnergies1 = scaleEnergies[1];

/* Scale value for first energies, upto YBufferWriteOffset */
  tmpScaleEnergies0 = fixMin(tmpScaleEnergies0, MAX_SHIFT_DBL);
  /* Scale value for first energies, from YBufferWriteOffset upwards */
  tmpScaleEnergies1 = fixMin(tmpScaleEnergies1, MAX_SHIFT_DBL);

FDK_ASSERT((tmpScaleEnergies0 >= 0) && (tmpScaleEnergies1 >= 0));

/* Keep addPrevSamples extra previous transient candidates. */
  FDKmemmove(transients, transients + noCols - addPrevSamples, (tran_off+addPrevSamples) * sizeof (FIXP_DBL));
  FDKmemclear(transients + tran_off + addPrevSamples, noCols * sizeof (FIXP_DBL));

endCond = noCols; /* Amount of new transient values to be calculated. */
  startEnerg = (tran_off-3)>>YBufferSzShift; /* >>YBufferSzShift because of amount of energy values. -3 because of neighbors being watched. */
  endEnerg = ((noCols+ (YBufferWriteOffset<<YBufferSzShift))-1)>>YBufferSzShift; /* YBufferSzShift shifts because of half energy values. */

/* Compute differential values with two different weightings in every subband */
  for (i=start_band; i<stop_band; i++)
  {
    FIXP_DBL thres = thresholds[i];

if((LONG)thresholds[i]>=256)
      i_thres = (LONG)( (LONG)MAXVAL_DBL / ((((LONG)thresholds[i]))+1) )<<(32-24);
    else
      i_thres = (LONG)MAXVAL_DBL;

/* Copy one timeslot and de-scale and de-squish */
    if (YBufferSzShift == 1) {
      for(j=startEnerg; j<YBufferWriteOffset; j++) {
        FIXP_DBL tmp = Energies[j][i];
        EnergiesTemp[(j<<1)+1] = EnergiesTemp[j<<1] = tmp>>tmpScaleEnergies0;
      }
      for(; j<=endEnerg; j++) {
        FIXP_DBL tmp = Energies[j][i];
        EnergiesTemp[(j<<1)+1] = EnergiesTemp[j<<1] = tmp>>tmpScaleEnergies1;
      }
    } else {
      for(j=startEnerg; j<YBufferWriteOffset; j++) {
        FIXP_DBL tmp = Energies[j][i];
        EnergiesTemp[j] = tmp>>tmpScaleEnergies0;
      }
      for(; j<=endEnerg; j++) {
        FIXP_DBL tmp = Energies[j][i];
        EnergiesTemp[j] = tmp>>tmpScaleEnergies1;
      }
    }

/* Detect peaks in energy values. */

jIndex = tran_off;
    jpBM = jIndex+addPrevSamples;

for (j=endCond; j--; jIndex++, jpBM++)
    {

FIXP_DBL delta, tran;
      int d;

delta = (FIXP_DBL)0;
      tran  = (FIXP_DBL)0;

for (d=1; d<4; d++) {
        delta += pEnergiesTemp[jIndex+d]; /* R */
        delta -= pEnergiesTemp[jIndex-d]; /* L */
        delta -= thres;

if ( delta > (FIXP_DBL)0 ) {
          tran += fMult(i_thres, delta);
        }
      }
      transients[jpBM] += tran;
    }
  }
  C_ALLOC_SCRATCH_END(EnergiesTemp, FIXP_DBL, 2*QMF_MAX_TIME_SLOTS);
}

void
FDKsbrEnc_transientDetect(HANDLE_SBR_TRANSIENT_DETECTOR h_sbrTran,
                          FIXP_DBL **Energies,
                          INT *scaleEnergies,
                          UCHAR *transient_info,
                          int YBufferWriteOffset,
                          int YBufferSzShift,
                          int timeStep,
                          int frameMiddleBorder)
{
  int no_cols = h_sbrTran->no_cols;
  int qmfStartSample;
  int addPrevSamples;
  int timeStepShift=0;
  int i, cond;

/* Where to start looking for transients in the transient candidate buffer */
  qmfStartSample = timeStep * frameMiddleBorder;
  /* We need to look one value backwards in the transients, so we might need one more previous value. */
  addPrevSamples = (qmfStartSample > 0) ? 0: 1;

switch (timeStep) {
    case 1: timeStepShift = 0; break;
    case 2: timeStepShift = 1; break;
    case 4: timeStepShift = 2; break;
  }

calculateThresholds(Energies,
                      scaleEnergies,
                      h_sbrTran->thresholds,
                      YBufferWriteOffset,
                      YBufferSzShift,
                      h_sbrTran->no_cols,
                      h_sbrTran->no_rows,
                      h_sbrTran->tran_off);

extractTransientCandidates(Energies,
                             scaleEnergies,
                             h_sbrTran->thresholds,
                             h_sbrTran->transients,
                             YBufferWriteOffset,
                             YBufferSzShift,
                             h_sbrTran->no_cols,
                             0,
                             h_sbrTran->no_rows,
                             h_sbrTran->tran_off,
                             addPrevSamples );

transient_info[0] = 0;
  transient_info[1] = 0;
  transient_info[2] = 0;

/* Offset by the amount of additional previous transient candidates being kept. */
  qmfStartSample += addPrevSamples;

/* Check for transients in second granule (pick the last value of subsequent values)  */
  for (i=qmfStartSample; i<qmfStartSample + no_cols; i++) {
    cond =    (h_sbrTran->transients[i] < fMult(FL2FXCONST_DBL(0.9f), h_sbrTran->transients[i - 1]) )
           && (h_sbrTran->transients[i - 1] > h_sbrTran->tran_thr);

if (cond) {
      transient_info[0] = (i - qmfStartSample)>>timeStepShift;
      transient_info[1] = 1;
      break;
    }
  }

if ( h_sbrTran->frameShift != 0) {
      /* transient prediction for LDSBR */
      /* Check for transients in first <frameShift> qmf-slots of second frame */
      for (i=qmfStartSample+no_cols; i<qmfStartSample + no_cols+h_sbrTran->frameShift; i++) {

cond =    (h_sbrTran->transients[i] < fMult(FL2FXCONST_DBL(0.9f), h_sbrTran->transients[i - 1]) )
               && (h_sbrTran->transients[i - 1] > h_sbrTran->tran_thr);

if (cond) {
          int pos = (int) ( (i - qmfStartSample-no_cols) >> timeStepShift );
          if ((pos < 3) && (transient_info[1]==0)) {
            transient_info[2] = 1;
          }
          break;
        }
      }
  }
}

int
FDKsbrEnc_InitSbrTransientDetector(HANDLE_SBR_TRANSIENT_DETECTOR h_sbrTransientDetector,
                                   INT   frameSize,
                                   INT   sampleFreq,
                                   sbrConfigurationPtr params,
                                   int   tran_fc,
                                   int   no_cols,
                                   int   no_rows,
                                   int   YBufferWriteOffset,
                                   int   YBufferSzShift,
                                   int   frameShift,
                                   int   tran_off)
{
    INT totalBitrate = params->codecSettings.standardBitrate * params->codecSettings.nChannels;
    INT codecBitrate = params->codecSettings.bitRate;
    FIXP_DBL bitrateFactor_fix, framedur_fix;
    INT scale_0, scale_1;

FDKmemclear(h_sbrTransientDetector,sizeof(SBR_TRANSIENT_DETECTOR));

h_sbrTransientDetector->frameShift = frameShift;
    h_sbrTransientDetector->tran_off = tran_off;

if(codecBitrate) {
      bitrateFactor_fix = fDivNorm((FIXP_DBL)totalBitrate, (FIXP_DBL)(codecBitrate<<2),&scale_0);
    }
    else {
      bitrateFactor_fix = FL2FXCONST_DBL(1.0/4.0);
      scale_0 = 0;
    }

framedur_fix = fDivNorm(frameSize, sampleFreq);

/* The longer the frames, the more often should the FIXFIX-
    case transmit 2 envelopes instead of 1.
    Frame durations below 10 ms produce the highest threshold
    so that practically always only 1 env is transmitted. */
    FIXP_DBL tmp = framedur_fix - FL2FXCONST_DBL(0.010);

tmp = fixMax(tmp, FL2FXCONST_DBL(0.0001));
    tmp = fDivNorm(FL2FXCONST_DBL(0.000075), fPow2(tmp), &scale_1);

scale_1 = -(scale_1 + scale_0 + 2);

FDK_ASSERT(no_cols <= QMF_MAX_TIME_SLOTS);
    FDK_ASSERT(no_rows <= QMF_CHANNELS);

h_sbrTransientDetector->no_cols = no_cols;
    h_sbrTransientDetector->tran_thr = (FIXP_DBL)((params->tran_thr << (32-24-1)) / no_rows);
    h_sbrTransientDetector->tran_fc = tran_fc;

if (scale_1>=0) {
      h_sbrTransientDetector->split_thr = fMult(tmp, bitrateFactor_fix) >> scale_1;
    }
    else {
      h_sbrTransientDetector->split_thr = fMult(tmp, bitrateFactor_fix) << (-scale_1);
    }

h_sbrTransientDetector->no_rows = no_rows;
    h_sbrTransientDetector->mode = params->tran_det_mode;
    h_sbrTransientDetector->prevLowBandEnergy = FL2FXCONST_DBL(0.0f);

return (0);
}

C++程序 | 702行 | 26.63 KB

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