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|
/******************************** MPEG Audio Encoder **************************
(C) Copyright Fraunhofer IIS (2010)
All Rights Reserved
Please be advised that this software and/or program delivery is
Confidential Information of Fraunhofer and subject to and covered by the
Fraunhofer IIS Software Evaluation Agreement
between Google Inc. and Fraunhofer
effective and in full force since March 1, 2012.
You may use this software and/or program only under the terms and
conditions described in the above mentioned Fraunhofer IIS Software
Evaluation Agreement. Any other and/or further use requires a separate agreement.
This software and/or program is protected by copyright law and international
treaties. Any reproduction or distribution of this software and/or program,
or any portion of it, may result in severe civil and criminal penalties, and
will be prosecuted to the maximum extent possible under law.
$Id$
Initial author: A. Horndasch (code originally from lwr) / Josef Hoepfl (FDK)
contents/description: intensity stereo processing
******************************************************************************/
#include "intensity.h"
#include "interface.h"
#include "psy_configuration.h"
#include "psy_const.h"
#include "qc_main.h"
#include "bit_cnt.h"
/* only set an IS seed it left/right channel correlation is above IS_CORR_THRESH */
#define IS_CORR_THRESH FL2FXCONST_DBL(0.95f)
/* when expanding the IS region to more SFBs only accept an error that is
* not more than IS_TOTAL_ERROR_THRESH overall and
* not more than IS_LOCAL_ERROR_THRESH for the current SFB */
#define IS_TOTAL_ERROR_THRESH FL2FXCONST_DBL(0.04f)
#define IS_LOCAL_ERROR_THRESH FL2FXCONST_DBL(0.01f)
/* the maximum allowed change of the intensity direction (unit: IS scale) - scaled with factor 0.25 - */
#define IS_DIRECTION_DEVIATION_THRESH_SF 2
#define IS_DIRECTION_DEVIATION_THRESH FL2FXCONST_DBL(2.0f/(1<<IS_DIRECTION_DEVIATION_THRESH_SF))
/* IS regions need to have a minimal percentage of the overall loudness, e.g. 0.06 == 6% */
#define IS_REGION_MIN_LOUDNESS FL2FXCONST_DBL(0.1f)
/* only perform IS if IS_MIN_SFBS neighboring SFBs can be processed */
#define IS_MIN_SFBS 6
/* only do IS if
* if IS_LEFT_RIGHT_RATIO_THRESH < sfbEnergyLeft[sfb]/sfbEnergyRight[sfb] < 1 / IS_LEFT_RIGHT_RATIO_THRESH
* -> no IS if the panning angle is not far from the middle, MS will do */
/* this is equivalent to a scale of +/-1.02914634566 */
#define IS_LEFT_RIGHT_RATIO_THRESH FL2FXCONST_DBL(0.7f)
/* scalefactor of realScale */
#define REAL_SCALE_SF 1
/* scalefactor overallLoudness */
#define OVERALL_LOUDNESS_SF 6
/* scalefactor for sum over max samples per goup */
#define MAX_SFB_PER_GROUP_SF 6
/* scalefactor for sum of mdct spectrum */
#define MDCT_SPEC_SF 6
typedef struct
{
FIXP_DBL corr_thresh; /*!< Only set an IS seed it left/right channel correlation is above corr_thresh */
FIXP_DBL total_error_thresh; /*!< When expanding the IS region to more SFBs only accept an error that is
not more than 'total_error_thresh' overall. */
FIXP_DBL local_error_thresh; /*!< When expanding the IS region to more SFBs only accept an error that is
not more than 'local_error_thresh' for the current SFB. */
FIXP_DBL direction_deviation_thresh; /*!< The maximum allowed change of the intensity direction (unit: IS scale) */
FIXP_DBL is_region_min_loudness; /*!< IS regions need to have a minimal percentage of the overall loudness, e.g. 0.06 == 6% */
INT min_is_sfbs; /*!< Only perform IS if 'min_is_sfbs' neighboring SFBs can be processed */
FIXP_DBL left_right_ratio_threshold; /*!< No IS if the panning angle is not far from the middle, MS will do */
} INTENSITY_PARAMETERS;
/*****************************************************************************
functionname: calcSfbMaxScale
description: Calc max value in scalefactor band
input: *mdctSpectrum
l1
l2
output: none
returns: scalefactor
*****************************************************************************/
static INT
calcSfbMaxScale(const FIXP_DBL *mdctSpectrum,
const INT l1,
const INT l2)
{
INT i;
INT sfbMaxScale;
FIXP_DBL maxSpc;
maxSpc = FL2FXCONST_DBL(0.0);
for (i=l1; i<l2; i++) {
FIXP_DBL tmp = fixp_abs((FIXP_DBL)mdctSpectrum[i]);
maxSpc = fixMax(maxSpc, tmp);
}
sfbMaxScale = (maxSpc==FL2FXCONST_DBL(0.0)) ? (DFRACT_BITS-2) : CntLeadingZeros(maxSpc)-1;
return sfbMaxScale;
}
/*****************************************************************************
functionname: FDKaacEnc_initIsParams
description: Initialization of intensity parameters
input: isParams
output: isParams
returns: none
*****************************************************************************/
static void
FDKaacEnc_initIsParams(INTENSITY_PARAMETERS *isParams)
{
isParams->corr_thresh = IS_CORR_THRESH;
isParams->total_error_thresh = IS_TOTAL_ERROR_THRESH;
isParams->local_error_thresh = IS_LOCAL_ERROR_THRESH;
isParams->direction_deviation_thresh = IS_DIRECTION_DEVIATION_THRESH;
isParams->is_region_min_loudness = IS_REGION_MIN_LOUDNESS;
isParams->min_is_sfbs = IS_MIN_SFBS;
isParams->left_right_ratio_threshold = IS_LEFT_RIGHT_RATIO_THRESH;
}
/*****************************************************************************
functionname: FDKaacEnc_prepareIntensityDecision
description: Prepares intensity decision
input: sfbEnergyLeft
sfbEnergyRight
sfbEnergyLdDataLeft
sfbEnergyLdDataRight
mdctSpectrumLeft
sfbEnergyLdDataRight
isParams
output: hrrErr scale: none
isMask scale: none
realScale scale: LD_DATA_SHIFT + REAL_SCALE_SF
normSfbLoudness scale: none
returns: none
*****************************************************************************/
static void
FDKaacEnc_prepareIntensityDecision(const FIXP_DBL *sfbEnergyLeft,
const FIXP_DBL *sfbEnergyRight,
const FIXP_DBL *sfbEnergyLdDataLeft,
const FIXP_DBL *sfbEnergyLdDataRight,
const FIXP_DBL *mdctSpectrumLeft,
const FIXP_DBL *mdctSpectrumRight,
const INTENSITY_PARAMETERS *isParams,
FIXP_DBL *hrrErr,
INT *isMask,
FIXP_DBL *realScale,
FIXP_DBL *normSfbLoudness,
const INT sfbCnt,
const INT sfbPerGroup,
const INT maxSfbPerGroup,
const INT *sfbOffset)
{
INT j,sfb,sfboffs;
INT grpCounter;
/* temporary variables to compute loudness */
FIXP_DBL overallLoudness[MAX_NO_OF_GROUPS];
/* temporary variables to compute correlation */
FIXP_DBL channelCorr[MAX_GROUPED_SFB];
FIXP_DBL ml, mr;
FIXP_DBL prod_lr;
FIXP_DBL square_l, square_r;
FIXP_DBL tmp_l, tmp_r;
FIXP_DBL inv_n;
FDKmemclear(channelCorr, MAX_GROUPED_SFB*sizeof(FIXP_DBL));
FDKmemclear(normSfbLoudness, MAX_GROUPED_SFB*sizeof(FIXP_DBL));
FDKmemclear(overallLoudness, MAX_NO_OF_GROUPS*sizeof(FIXP_DBL));
FDKmemclear(realScale, MAX_GROUPED_SFB*sizeof(FIXP_DBL));
for (grpCounter = 0, sfboffs = 0; sfboffs < sfbCnt; sfboffs += sfbPerGroup, grpCounter++) {
overallLoudness[grpCounter] = FL2FXCONST_DBL(0.0f);
for (sfb = 0; sfb < maxSfbPerGroup; sfb++) {
INT sL,sR,s;
FIXP_DBL isValue = sfbEnergyLdDataLeft[sfb+sfboffs]-sfbEnergyLdDataRight[sfb+sfboffs];
/* delimitate intensity scale value to representable range */
realScale[sfb + sfboffs] = fixMin(FL2FXCONST_DBL(60.f/(1<<(REAL_SCALE_SF+LD_DATA_SHIFT))), fixMax(FL2FXCONST_DBL(-60.f/(1<<(REAL_SCALE_SF+LD_DATA_SHIFT))), isValue));
sL = fixMax(0,(CntLeadingZeros(sfbEnergyLeft[sfb + sfboffs])-1));
sR = fixMax(0,(CntLeadingZeros(sfbEnergyRight[sfb + sfboffs])-1));
s = (fixMin(sL,sR)>>2)<<2;
normSfbLoudness[sfb + sfboffs] = sqrtFixp(sqrtFixp(((sfbEnergyLeft[sfb + sfboffs]<<s) >> 1) + ((sfbEnergyRight[sfb + sfboffs]<<s) >> 1))) >> (s>>2);
overallLoudness[grpCounter] += normSfbLoudness[sfb + sfboffs] >> OVERALL_LOUDNESS_SF;
/* don't do intensity if
* - panning angle is too close to the middle or
* - one channel is non-existent or
* - if it is dual mono */
if( (sfbEnergyLeft[sfb + sfboffs] >= fMult(isParams->left_right_ratio_threshold,sfbEnergyRight[sfb + sfboffs]))
&& (fMult(isParams->left_right_ratio_threshold,sfbEnergyLeft[sfb + sfboffs]) <= sfbEnergyRight[sfb + sfboffs]) ) {
/* this will prevent post processing from considering this SFB for merging */
hrrErr[sfb + sfboffs] = FL2FXCONST_DBL(1.0/8.0);
}
}
}
for (grpCounter = 0, sfboffs = 0; sfboffs < sfbCnt; sfboffs += sfbPerGroup, grpCounter++) {
INT invOverallLoudnessSF;
FIXP_DBL invOverallLoudness;
if (overallLoudness[grpCounter] == FL2FXCONST_DBL(0.0)) {
invOverallLoudness = FL2FXCONST_DBL(0.0);
invOverallLoudnessSF = 0;
}
else {
invOverallLoudness = fDivNorm((FIXP_DBL)MAXVAL_DBL, overallLoudness[grpCounter],&invOverallLoudnessSF);
invOverallLoudnessSF = invOverallLoudnessSF - OVERALL_LOUDNESS_SF + 1; /* +1: compensate fMultDiv2() in subsequent loop */
}
invOverallLoudnessSF = fixMin(fixMax(invOverallLoudnessSF,-(DFRACT_BITS-1)),DFRACT_BITS-1);
for (sfb = 0; sfb < maxSfbPerGroup; sfb++) {
FIXP_DBL tmp;
tmp = fMultDiv2((normSfbLoudness[sfb + sfboffs]>>OVERALL_LOUDNESS_SF)<<OVERALL_LOUDNESS_SF,invOverallLoudness);
normSfbLoudness[sfb + sfboffs] = scaleValue(tmp, invOverallLoudnessSF);
channelCorr[sfb + sfboffs] = FL2FXCONST_DBL(0.0f);
FDK_ASSERT(50 >= 49);
/* max width of scalefactorband is 96; width's are always even */
/* inv_n is scaled with factor 2 to compensate fMultDiv2() in subsequent loops */
inv_n = GetInvInt((sfbOffset[sfb + sfboffs + 1] - sfbOffset[sfb + sfboffs])>>1);
if (inv_n > FL2FXCONST_DBL(0.0f)) {
INT s,sL,sR;
/* correlation := Pearson's product-moment coefficient */
/* compute correlation between channels and check if it is over threshold */
ml = FL2FXCONST_DBL(0.0f);
mr = FL2FXCONST_DBL(0.0f);
prod_lr = FL2FXCONST_DBL(0.0f);
square_l = FL2FXCONST_DBL(0.0f);
square_r = FL2FXCONST_DBL(0.0f);
sL = calcSfbMaxScale(mdctSpectrumLeft,sfbOffset[sfb+sfboffs],sfbOffset[sfb+sfboffs+1]);
sR = calcSfbMaxScale(mdctSpectrumRight,sfbOffset[sfb+sfboffs],sfbOffset[sfb+sfboffs+1]);
s = fixMin(sL,sR);
for (j = sfbOffset[sfb + sfboffs]; j < sfbOffset[sfb + sfboffs + 1]; j++) {
ml += fMultDiv2((mdctSpectrumLeft[j] << s),inv_n); // scaled with mdctScale - s + inv_n
mr += fMultDiv2((mdctSpectrumRight[j] << s),inv_n); // scaled with mdctScale - s + inv_n
}
ml = fMultDiv2(ml,inv_n); // scaled with mdctScale - s + inv_n
mr = fMultDiv2(mr,inv_n); // scaled with mdctScale - s + inv_n
for (j = sfbOffset[sfb + sfboffs]; j < sfbOffset[sfb + sfboffs + 1]; j++) {
tmp_l = fMultDiv2((mdctSpectrumLeft[j] << s),inv_n) - ml; // scaled with mdctScale - s + inv_n
tmp_r = fMultDiv2((mdctSpectrumRight[j] << s),inv_n) - mr; // scaled with mdctScale - s + inv_n
prod_lr += fMultDiv2(tmp_l,tmp_r); // scaled with 2*(mdctScale - s + inv_n) + 1
square_l += fPow2Div2(tmp_l); // scaled with 2*(mdctScale - s + inv_n) + 1
square_r += fPow2Div2(tmp_r); // scaled with 2*(mdctScale - s + inv_n) + 1
}
prod_lr = prod_lr << 1; // scaled with 2*(mdctScale - s + inv_n)
square_l = square_l << 1; // scaled with 2*(mdctScale - s + inv_n)
square_r = square_r << 1; // scaled with 2*(mdctScale - s + inv_n)
if (square_l > FL2FXCONST_DBL(0.0f) && square_r > FL2FXCONST_DBL(0.0f)) {
INT channelCorrSF = 0;
/* local scaling of square_l and square_r is compensated after sqrt calculation */
sL = fixMax(0,(CntLeadingZeros(square_l)-1));
sR = fixMax(0,(CntLeadingZeros(square_r)-1));
s = ((sL + sR)>>1)<<1;
sL = fixMin(sL,s);
sR = s-sL;
tmp = fMult(square_l<<sL,square_r<<sR);
tmp = sqrtFixp(tmp);
FDK_ASSERT(tmp > FL2FXCONST_DBL(0.0f));
/* numerator and denominator have the same scaling */
if (prod_lr < FL2FXCONST_DBL(0.0f) ) {
channelCorr[sfb + sfboffs] = -(fDivNorm(-prod_lr,tmp,&channelCorrSF));
}
else {
channelCorr[sfb + sfboffs] = (fDivNorm( prod_lr,tmp,&channelCorrSF));
}
channelCorrSF = fixMin(fixMax(( channelCorrSF + ((sL+sR)>>1)),-(DFRACT_BITS-1)),DFRACT_BITS-1);
if (channelCorrSF < 0) {
channelCorr[sfb + sfboffs] = channelCorr[sfb + sfboffs] >> (-channelCorrSF);
}
else {
/* avoid overflows due to limited computational accuracy */
if ( fAbs(channelCorr[sfb + sfboffs]) > (((FIXP_DBL)MAXVAL_DBL)>>channelCorrSF) ) {
if (channelCorr[sfb + sfboffs] < FL2FXCONST_DBL(0.0f))
channelCorr[sfb + sfboffs] = -(FIXP_DBL) MAXVAL_DBL;
else
channelCorr[sfb + sfboffs] = (FIXP_DBL) MAXVAL_DBL;
}
else {
channelCorr[sfb + sfboffs] = channelCorr[sfb + sfboffs] << channelCorrSF;
}
}
}
}
/* for post processing: hrrErr is the error in terms of (too little) correlation
* weighted with the loudness of the SFB; SFBs with small hrrErr can be merged */
if (hrrErr[sfb + sfboffs] == FL2FXCONST_DBL(1.0/8.0)) {
continue;
}
hrrErr[sfb + sfboffs] = fMultDiv2((FL2FXCONST_DBL(0.25f)-(channelCorr[sfb + sfboffs]>>2)),normSfbLoudness[sfb + sfboffs]);
/* set IS mask/vector to 1, if correlation is high enough */
if (fAbs(channelCorr[sfb + sfboffs]) >= isParams->corr_thresh) {
isMask[sfb + sfboffs] = 1;
}
}
}
}
/*****************************************************************************
functionname: FDKaacEnc_finalizeIntensityDecision
description: Finalizes intensity decision
input: isParams scale: none
hrrErr scale: none
realIsScale scale: LD_DATA_SHIFT + REAL_SCALE_SF
normSfbLoudness scale: none
output: isMask scale: none
returns: none
*****************************************************************************/
static void
FDKaacEnc_finalizeIntensityDecision(const FIXP_DBL *hrrErr,
INT *isMask,
const FIXP_DBL *realIsScale,
const FIXP_DBL *normSfbLoudness,
const INTENSITY_PARAMETERS *isParams,
const INT sfbCnt,
const INT sfbPerGroup,
const INT maxSfbPerGroup)
{
INT sfb,sfboffs, j;
INT startIsSfb = 0;
INT inIsBlock;
INT currentIsSfbCount;
FIXP_DBL overallHrrError;
FIXP_DBL isScaleLast = FL2FXCONST_DBL(0.0f);
FIXP_DBL isRegionLoudness;
for (sfboffs = 0; sfboffs < sfbCnt; sfboffs += sfbPerGroup) {
inIsBlock = 0;
currentIsSfbCount = 0;
overallHrrError = FL2FXCONST_DBL(0.0f);
isRegionLoudness = FL2FXCONST_DBL(0.0f);
for (sfb = 0; sfb < maxSfbPerGroup; sfb++) {
if (isMask[sfboffs + sfb] == 1) {
if (currentIsSfbCount == 0) {
startIsSfb = sfboffs + sfb;
isScaleLast = realIsScale[sfboffs + sfb];
}
inIsBlock = 1;
currentIsSfbCount++;
overallHrrError += hrrErr[sfboffs + sfb] >> (MAX_SFB_PER_GROUP_SF-3);
isRegionLoudness += normSfbLoudness[sfboffs + sfb] >> MAX_SFB_PER_GROUP_SF;
}
else {
/* based on correlation, IS should not be used
* -> use it anyway, if overall error is below threshold
* and if local error does not exceed threshold
* otherwise: check if there are enough IS SFBs
*/
if (inIsBlock) {
overallHrrError += hrrErr[sfboffs + sfb] >> (MAX_SFB_PER_GROUP_SF-3);
isRegionLoudness += normSfbLoudness[sfboffs + sfb] >> MAX_SFB_PER_GROUP_SF;
if ( (hrrErr[sfboffs + sfb] < (isParams->local_error_thresh>>3)) && (overallHrrError < (isParams->total_error_thresh>>MAX_SFB_PER_GROUP_SF)) ) {
currentIsSfbCount++;
/* overwrite correlation based decision */
isMask[sfboffs + sfb] = 1;
} else {
inIsBlock = 0;
}
}
}
/* check for large direction deviation */
if (inIsBlock) {
if( fAbs(isScaleLast-realIsScale[sfboffs + sfb]) < (isParams->direction_deviation_thresh>>(REAL_SCALE_SF+LD_DATA_SHIFT-IS_DIRECTION_DEVIATION_THRESH_SF)) ) {
isScaleLast = realIsScale[sfboffs + sfb];
}
else{
isMask[sfboffs + sfb] = 0;
inIsBlock = 0;
currentIsSfbCount--;
}
}
if (currentIsSfbCount > 0 && (!inIsBlock || sfb == maxSfbPerGroup - 1)) {
/* not enough SFBs -> do not use IS */
if (currentIsSfbCount < isParams->min_is_sfbs || (isRegionLoudness < isParams->is_region_min_loudness>>MAX_SFB_PER_GROUP_SF)) {
for(j = startIsSfb; j <= sfboffs + sfb; j++) {
isMask[j] = 0;
}
}
currentIsSfbCount = 0;
overallHrrError = FL2FXCONST_DBL(0.0f);
isRegionLoudness = FL2FXCONST_DBL(0.0f);
}
}
}
}
/*****************************************************************************
functionname: FDKaacEnc_IntensityStereoProcessing
description: Intensity stereo processing tool
input: sfbEnergyLeft
sfbEnergyRight
mdctSpectrumLeft
mdctSpectrumRight
sfbThresholdLeft
sfbThresholdRight
sfbSpreadEnLeft
sfbSpreadEnRight
sfbEnergyLdDataLeft
sfbEnergyLdDataRight
output: isBook
isScale
pnsData->pnsFlag
msDigest zeroed from start to sfbCnt
msMask zeroed from start to sfbCnt
mdctSpectrumRight zeroed where isBook!=0
sfbEnergyRight zeroed where isBook!=0
sfbSpreadEnRight zeroed where isBook!=0
sfbThresholdRight zeroed where isBook!=0
sfbEnergyLdDataRight FL2FXCONST_DBL(-1.0) where isBook!=0
sfbThresholdLdDataRight FL2FXCONST_DBL(-0.515625f) where isBook!=0
returns: none
*****************************************************************************/
void FDKaacEnc_IntensityStereoProcessing(
FIXP_DBL *sfbEnergyLeft,
FIXP_DBL *sfbEnergyRight,
FIXP_DBL *mdctSpectrumLeft,
FIXP_DBL *mdctSpectrumRight,
FIXP_DBL *sfbThresholdLeft,
FIXP_DBL *sfbThresholdRight,
FIXP_DBL *sfbThresholdLdDataRight,
FIXP_DBL *sfbSpreadEnLeft,
FIXP_DBL *sfbSpreadEnRight,
FIXP_DBL *sfbEnergyLdDataLeft,
FIXP_DBL *sfbEnergyLdDataRight,
INT *msDigest,
INT *msMask,
const INT sfbCnt,
const INT sfbPerGroup,
const INT maxSfbPerGroup,
const INT *sfbOffset,
const INT allowIS,
INT *isBook,
INT *isScale,
PNS_DATA *RESTRICT pnsData[2]
)
{
INT sfb,sfboffs, j;
FIXP_DBL scale;
FIXP_DBL lr;
FIXP_DBL hrrErr[MAX_GROUPED_SFB];
FIXP_DBL normSfbLoudness[MAX_GROUPED_SFB];
FIXP_DBL realIsScale[MAX_GROUPED_SFB];
INTENSITY_PARAMETERS isParams;
INT isMask[MAX_GROUPED_SFB];
FDKmemclear((void*)isBook,sfbCnt*sizeof(INT));
FDKmemclear((void*)isMask,sfbCnt*sizeof(INT));
FDKmemclear((void*)realIsScale,sfbCnt*sizeof(FIXP_DBL));
FDKmemclear((void*)isScale,sfbCnt*sizeof(INT));
FDKmemclear((void*)hrrErr,sfbCnt*sizeof(FIXP_DBL));
if (!allowIS)
return;
FDKaacEnc_initIsParams(&isParams);
/* compute / set the following values per SFB:
* - left/right ratio between channels
* - normalized loudness
* + loudness == average of energy in channels to 0.25
* + normalization: division by sum of all SFB loudnesses
* - isMask (is set to 0 if channels are the same or one is 0)
*/
FDKaacEnc_prepareIntensityDecision(sfbEnergyLeft,
sfbEnergyRight,
sfbEnergyLdDataLeft,
sfbEnergyLdDataRight,
mdctSpectrumLeft,
mdctSpectrumRight,
&isParams,
hrrErr,
isMask,
realIsScale,
normSfbLoudness,
sfbCnt,
sfbPerGroup,
maxSfbPerGroup,
sfbOffset);
FDKaacEnc_finalizeIntensityDecision(hrrErr,
isMask,
realIsScale,
normSfbLoudness,
&isParams,
sfbCnt,
sfbPerGroup,
maxSfbPerGroup);
for (sfb=0; sfb<sfbCnt; sfb+=sfbPerGroup) {
for (sfboffs=0; sfboffs<maxSfbPerGroup; sfboffs++) {
INT sL, sR;
FIXP_DBL inv_n;
msMask[sfb+sfboffs] = 0;
if (isMask[sfb+sfboffs] == 0) {
continue;
}
if ( (sfbEnergyLeft[sfb+sfboffs] < sfbThresholdLeft[sfb+sfboffs])
&&(fMult(FL2FXCONST_DBL(1.0f/1.5f),sfbEnergyRight[sfb+sfboffs]) > sfbThresholdRight[sfb+sfboffs]) ) {
continue;
}
/* NEW: if there is a big-enough IS region, switch off PNS */
if (pnsData[0]) {
if(pnsData[0]->pnsFlag[sfb+sfboffs]) {
pnsData[0]->pnsFlag[sfb+sfboffs] = 0;
}
if(pnsData[1]->pnsFlag[sfb+sfboffs]) {
pnsData[1]->pnsFlag[sfb+sfboffs] = 0;
}
}
inv_n = GetInvInt((sfbOffset[sfb + sfboffs + 1] - sfbOffset[sfb + sfboffs])>>1); // scaled with 2 to compensate fMultDiv2() in subsequent loop
sL = calcSfbMaxScale(mdctSpectrumLeft,sfbOffset[sfb+sfboffs],sfbOffset[sfb+sfboffs+1]);
sR = calcSfbMaxScale(mdctSpectrumRight,sfbOffset[sfb+sfboffs],sfbOffset[sfb+sfboffs+1]);
lr = FL2FXCONST_DBL(0.0f);
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++)
lr += fMultDiv2(fMultDiv2(mdctSpectrumLeft[j]<<sL,mdctSpectrumRight[j]<<sR),inv_n);
lr = lr<<1;
if (lr < FL2FXCONST_DBL(0.0f)) {
/* This means OUT OF phase intensity stereo, cf. standard */
INT s0, s1, s2;
FIXP_DBL tmp, d, ed = FL2FXCONST_DBL(0.0f);
s0 = fixMin(sL,sR);
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
d = ((mdctSpectrumLeft[j]<<s0)>>1) - ((mdctSpectrumRight[j]<<s0)>>1);
ed += fMultDiv2(d,d)>>(MDCT_SPEC_SF-1);
}
msMask[sfb+sfboffs] = 1;
tmp = fDivNorm(sfbEnergyLeft[sfb+sfboffs],ed,&s1);
s2 = (s1) + (2*s0) - 2 - MDCT_SPEC_SF;
if (s2 & 1) {
tmp = tmp>>1;
s2 = s2+1;
}
s2 = (s2>>1) + 1; // +1 compensate fMultDiv2() in subsequent loop
s2 = fixMin(fixMax(s2,-(DFRACT_BITS-1)),(DFRACT_BITS-1));
scale = sqrtFixp(tmp);
if (s2 < 0) {
s2 = -s2;
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
mdctSpectrumLeft[j] = (fMultDiv2(mdctSpectrumLeft[j],scale) - fMultDiv2(mdctSpectrumRight[j],scale)) >> s2;
mdctSpectrumRight[j] = FL2FXCONST_DBL(0.0f);
}
}
else {
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
mdctSpectrumLeft[j] = (fMultDiv2(mdctSpectrumLeft[j],scale) - fMultDiv2(mdctSpectrumRight[j],scale)) << s2;
mdctSpectrumRight[j] = FL2FXCONST_DBL(0.0f);
}
}
}
else {
/* This means IN phase intensity stereo, cf. standard */
INT s0,s1,s2;
FIXP_DBL tmp, s, es = FL2FXCONST_DBL(0.0f);
s0 = fixMin(sL,sR);
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
s = ((mdctSpectrumLeft[j]<<s0)>>1) + ((mdctSpectrumRight[j]<<s0)>>1);
es += fMultDiv2(s,s)>>(MDCT_SPEC_SF-1); // scaled 2*(mdctScale - s0 + 1) + MDCT_SPEC_SF
}
msMask[sfb+sfboffs] = 0;
tmp = fDivNorm(sfbEnergyLeft[sfb+sfboffs],es,&s1);
s2 = (s1) + (2*s0) - 2 - MDCT_SPEC_SF;
if (s2 & 1) {
tmp = tmp>>1;
s2 = s2 + 1;
}
s2 = (s2>>1) + 1; // +1 compensate fMultDiv2() in subsequent loop
s2 = fixMin(fixMax(s2,-(DFRACT_BITS-1)),(DFRACT_BITS-1));
scale = sqrtFixp(tmp);
if (s2 < 0) {
s2 = -s2;
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
mdctSpectrumLeft[j] = (fMultDiv2(mdctSpectrumLeft[j],scale) + fMultDiv2(mdctSpectrumRight[j],scale)) >> s2;
mdctSpectrumRight[j] = FL2FXCONST_DBL(0.0f);
}
}
else {
for (j=sfbOffset[sfb+sfboffs]; j<sfbOffset[sfb+sfboffs+1]; j++) {
mdctSpectrumLeft[j] = (fMultDiv2(mdctSpectrumLeft[j],scale) + fMultDiv2(mdctSpectrumRight[j],scale)) << s2;
mdctSpectrumRight[j] = FL2FXCONST_DBL(0.0f);
}
}
}
isBook[sfb+sfboffs] = CODE_BOOK_IS_IN_PHASE_NO;
if ( realIsScale[sfb+sfboffs] < FL2FXCONST_DBL(0.0f) ) {
isScale[sfb+sfboffs] = (INT)(((realIsScale[sfb+sfboffs]>>1)-FL2FXCONST_DBL(0.5f/(1<<(REAL_SCALE_SF+LD_DATA_SHIFT+1))))>>(DFRACT_BITS-1-REAL_SCALE_SF-LD_DATA_SHIFT-1)) + 1;
}
else {
isScale[sfb+sfboffs] = (INT)(((realIsScale[sfb+sfboffs]>>1)+FL2FXCONST_DBL(0.5f/(1<<(REAL_SCALE_SF+LD_DATA_SHIFT+1))))>>(DFRACT_BITS-1-REAL_SCALE_SF-LD_DATA_SHIFT-1));
}
sfbEnergyRight[sfb+sfboffs] = FL2FXCONST_DBL(0.0f);
sfbEnergyLdDataRight[sfb+sfboffs] = FL2FXCONST_DBL(-1.0f);
sfbThresholdRight[sfb+sfboffs] = FL2FXCONST_DBL(0.0f);
sfbThresholdLdDataRight[sfb+sfboffs] = FL2FXCONST_DBL(-0.515625f);
sfbSpreadEnRight[sfb+sfboffs] = FL2FXCONST_DBL(0.0f);
*msDigest = MS_SOME;
}
}
}
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