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/* -----------------------------------------------------------------------------------------------------------
Software License for The Fraunhofer FDK AAC Codec Library for Android
� Copyright 1995 - 2013 Fraunhofer-Gesellschaft zur F�rderung der angewandten Forschung e.V.
All rights reserved.
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)
may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
individually for the purpose of encoding or decoding bit streams in products that are compliant with
the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
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
applications information and documentation.
2. COPYRIGHT LICENSE
Redistribution and use in source and binary forms, with or without modification, are permitted without
payment of copyright license fees provided that you satisfy the following conditions:
You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
your modifications thereto in source code form.
You must retain the complete text of this software license in the documentation and/or other materials
provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form.
You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
modifications thereto to recipients of copies in binary form.
The name of Fraunhofer may not be used to endorse or promote products derived from this library without
prior written permission.
You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec
software or your modifications thereto.
Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software
and the date of any change. For modified versions of the FDK AAC Codec, the term
"Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term
"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."
3. NO PATENT LICENSE
NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer,
ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
respect to this software.
You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
by appropriate patent licenses.
4. DISCLAIMER
This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages,
including but not limited to procurement of substitute goods or services; loss of use, data, or profits,
or business interruption, however caused and on any theory of liability, whether in contract, strict
liability, or tort (including negligence), arising in any way out of the use of this software, even if
advised of the possibility of such damage.
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 "mh_det.h"
#include "sbr_ram.h"
#include "sbr_misc.h"
#include "genericStds.h"
#define SFM_SHIFT 2 /* Attention: SFM_SCALE depends on SFM_SHIFT */
#define SFM_SCALE (MAXVAL_DBL >> SFM_SHIFT) /* 1.0 >> SFM_SHIFT */
/*!< Detector Parameters for AAC core codec. */
static const DETECTOR_PARAMETERS_MH paramsAac = {
9, /*!< deltaTime */
{
FL2FXCONST_DBL(20.0f*RELAXATION_FLOAT), /*!< thresHoldDiff */
FL2FXCONST_DBL(1.26f*RELAXATION_FLOAT), /*!< thresHoldDiffGuide */
FL2FXCONST_DBL(15.0f*RELAXATION_FLOAT), /*!< thresHoldTone */
FL2FXCONST_DBL((1.0f/15.0f)*RELAXATION_FLOAT), /*!< invThresHoldTone */
FL2FXCONST_DBL(1.26f*RELAXATION_FLOAT), /*!< thresHoldToneGuide */
FL2FXCONST_DBL(0.3f)>>SFM_SHIFT, /*!< sfmThresSbr */
FL2FXCONST_DBL(0.1f)>>SFM_SHIFT, /*!< sfmThresOrig */
FL2FXCONST_DBL(0.3f), /*!< decayGuideOrig */
FL2FXCONST_DBL(0.5f), /*!< decayGuideDiff */
FL2FXCONST_DBL(-0.000112993269), /* LD64(FL2FXCONST_DBL(0.995f)) */ /*!< derivThresMaxLD64 */
FL2FXCONST_DBL(-0.000112993269), /* LD64(FL2FXCONST_DBL(0.995f)) */ /*!< derivThresBelowLD64 */
FL2FXCONST_DBL(-0.005030126483f) /* LD64(FL2FXCONST_DBL(0.8f)) */ /*!< derivThresAboveLD64 */
},
50 /*!< maxComp */
};
/*!< Detector Parameters for AAC LD core codec. */
static const DETECTOR_PARAMETERS_MH paramsAacLd = {
16, /*!< Delta time. */
{
FL2FXCONST_DBL(25.0f*RELAXATION_FLOAT), /*!< thresHoldDiff */
FL2FXCONST_DBL(1.26f*RELAXATION_FLOAT), /*!< tresHoldDiffGuide */
FL2FXCONST_DBL(15.0f*RELAXATION_FLOAT), /*!< thresHoldTone */
FL2FXCONST_DBL((1.0f/15.0f)*RELAXATION_FLOAT), /*!< invThresHoldTone */
FL2FXCONST_DBL(1.26f*RELAXATION_FLOAT), /*!< thresHoldToneGuide */
FL2FXCONST_DBL(0.3f)>>SFM_SHIFT, /*!< sfmThresSbr */
FL2FXCONST_DBL(0.1f)>>SFM_SHIFT, /*!< sfmThresOrig */
FL2FXCONST_DBL(0.3f), /*!< decayGuideOrig */
FL2FXCONST_DBL(0.2f), /*!< decayGuideDiff */
FL2FXCONST_DBL(-0.000112993269), /* LD64(FL2FXCONST_DBL(0.995f)) */ /*!< derivThresMaxLD64 */
FL2FXCONST_DBL(-0.000112993269), /* LD64(FL2FXCONST_DBL(0.995f)) */ /*!< derivThresBelowLD64 */
FL2FXCONST_DBL(-0.005030126483f) /* LD64(FL2FXCONST_DBL(0.8f)) */ /*!< derivThresAboveLD64 */
},
50 /*!< maxComp */
};
/**************************************************************************/
/*!
\brief Calculates the difference in tonality between original and SBR
for a given time and frequency region.
The values for pDiffMapped2Scfb are scaled by RELAXATION
\return none.
*/
/**************************************************************************/
static void diff(FIXP_DBL *RESTRICT pTonalityOrig,
FIXP_DBL *pDiffMapped2Scfb,
const UCHAR *RESTRICT pFreqBandTable,
INT nScfb,
SCHAR *indexVector)
{
UCHAR i, ll, lu, k;
FIXP_DBL maxValOrig, maxValSbr, tmp;
INT scale;
for(i=0; i < nScfb; i++){
ll = pFreqBandTable[i];
lu = pFreqBandTable[i+1];
maxValOrig = FL2FXCONST_DBL(0.0f);
maxValSbr = FL2FXCONST_DBL(0.0f);
for(k=ll;k<lu;k++){
maxValOrig = fixMax(maxValOrig, pTonalityOrig[k]);
maxValSbr = fixMax(maxValSbr, pTonalityOrig[indexVector[k]]);
}
if ((maxValSbr >= RELAXATION)) {
tmp = fDivNorm(maxValOrig, maxValSbr, &scale);
pDiffMapped2Scfb[i] = scaleValue(fMult(tmp,RELAXATION_FRACT), fixMax(-(DFRACT_BITS-1),(scale-RELAXATION_SHIFT)));
}
else {
pDiffMapped2Scfb[i] = maxValOrig;
}
}
}
/**************************************************************************/
/*!
\brief Calculates a flatness measure of the tonality measures.
Calculation of the power function and using scalefactor for basis:
Using log2:
z = (2^k * x)^y;
z' = CalcLd(z) = y*CalcLd(x) + y*k;
z = CalcInvLd(z');
Using ld64:
z = (2^k * x)^y;
z' = CalcLd64(z) = y*CalcLd64(x)/64 + y*k/64;
z = CalcInvLd64(z');
The values pSfmOrigVec and pSfmSbrVec are scaled by the factor 1/4.0
\return none.
*/
/**************************************************************************/
static void calculateFlatnessMeasure(FIXP_DBL *pQuotaBuffer,
SCHAR *indexVector,
FIXP_DBL *pSfmOrigVec,
FIXP_DBL *pSfmSbrVec,
const UCHAR *pFreqBandTable,
INT nSfb)
{
INT i,j;
FIXP_DBL invBands,tmp1,tmp2;
INT shiftFac0,shiftFacSum0;
INT shiftFac1,shiftFacSum1;
FIXP_DBL accu;
for(i=0;i<nSfb;i++)
{
INT ll = pFreqBandTable[i];
INT lu = pFreqBandTable[i+1];
pSfmOrigVec[i] = (FIXP_DBL)(MAXVAL_DBL>>2);
pSfmSbrVec[i] = (FIXP_DBL)(MAXVAL_DBL>>2);
if(lu - ll > 1){
FIXP_DBL amOrig,amTransp,gmOrig,gmTransp,sfmOrig,sfmTransp;
invBands = GetInvInt(lu-ll);
shiftFacSum0 = 0;
shiftFacSum1 = 0;
amOrig = amTransp = FL2FXCONST_DBL(0.0f);
gmOrig = gmTransp = (FIXP_DBL)MAXVAL_DBL;
for(j= ll; j<lu; j++) {
sfmOrig = pQuotaBuffer[j];
sfmTransp = pQuotaBuffer[indexVector[j]];
amOrig += fMult(sfmOrig, invBands);
amTransp += fMult(sfmTransp, invBands);
shiftFac0 = CountLeadingBits(sfmOrig);
shiftFac1 = CountLeadingBits(sfmTransp);
gmOrig = fMult(gmOrig, sfmOrig<<shiftFac0);
gmTransp = fMult(gmTransp, sfmTransp<<shiftFac1);
shiftFacSum0 += shiftFac0;
shiftFacSum1 += shiftFac1;
}
if (gmOrig > FL2FXCONST_DBL(0.0f)) {
tmp1 = CalcLdData(gmOrig); /* CalcLd64(x)/64 */
tmp1 = fMult(invBands, tmp1); /* y*CalcLd64(x)/64 */
/* y*k/64 */
accu = (FIXP_DBL)-shiftFacSum0 << (DFRACT_BITS-1-8);
tmp2 = fMultDiv2(invBands, accu) << (2+1);
tmp2 = tmp1 + tmp2; /* y*CalcLd64(x)/64 + y*k/64 */
gmOrig = CalcInvLdData(tmp2); /* CalcInvLd64(z'); */
}
else {
gmOrig = FL2FXCONST_DBL(0.0f);
}
if (gmTransp > FL2FXCONST_DBL(0.0f)) {
tmp1 = CalcLdData(gmTransp); /* CalcLd64(x)/64 */
tmp1 = fMult(invBands, tmp1); /* y*CalcLd64(x)/64 */
/* y*k/64 */
accu = (FIXP_DBL)-shiftFacSum1 << (DFRACT_BITS-1-8);
tmp2 = fMultDiv2(invBands, accu) << (2+1);
tmp2 = tmp1 + tmp2; /* y*CalcLd64(x)/64 + y*k/64 */
gmTransp = CalcInvLdData(tmp2); /* CalcInvLd64(z'); */
}
else {
gmTransp = FL2FXCONST_DBL(0.0f);
}
if ( amOrig != FL2FXCONST_DBL(0.0f) )
pSfmOrigVec[i] = FDKsbrEnc_LSI_divide_scale_fract(gmOrig,amOrig,SFM_SCALE);
if ( amTransp != FL2FXCONST_DBL(0.0f) )
pSfmSbrVec[i] = FDKsbrEnc_LSI_divide_scale_fract(gmTransp,amTransp,SFM_SCALE);
}
}
}
/**************************************************************************/
/*!
\brief Calculates the input to the missing harmonics detection.
\return none.
*/
/**************************************************************************/
static void calculateDetectorInput(FIXP_DBL **RESTRICT pQuotaBuffer, /*!< Pointer to tonality matrix. */
SCHAR *RESTRICT indexVector,
FIXP_DBL **RESTRICT tonalityDiff,
FIXP_DBL **RESTRICT pSfmOrig,
FIXP_DBL **RESTRICT pSfmSbr,
const UCHAR *freqBandTable,
INT nSfb,
INT noEstPerFrame,
INT move)
{
INT est;
/*
New estimate.
*/
for (est=0; est < noEstPerFrame; est++) {
diff(pQuotaBuffer[est+move],
tonalityDiff[est+move],
freqBandTable,
nSfb,
indexVector);
calculateFlatnessMeasure(pQuotaBuffer[est+ move],
indexVector,
pSfmOrig[est + move],
pSfmSbr[est + move],
freqBandTable,
nSfb);
}
}
/**************************************************************************/
/*!
\brief Checks that the detection is not due to a LP filter
This function determines if a newly detected missing harmonics is not
in fact just a low-pass filtere input signal. If so, the detection is
removed.
\return none.
*/
/**************************************************************************/
static void removeLowPassDetection(UCHAR *RESTRICT pAddHarmSfb,
UCHAR **RESTRICT pDetectionVectors,
INT start,
INT stop,
INT nSfb,
const UCHAR *RESTRICT pFreqBandTable,
FIXP_DBL *RESTRICT pNrgVector,
THRES_HOLDS mhThresh)
{
INT i,est;
INT maxDerivPos = pFreqBandTable[nSfb];
INT numBands = pFreqBandTable[nSfb];
FIXP_DBL nrgLow,nrgHigh;
FIXP_DBL nrgLD64,nrgLowLD64,nrgHighLD64,nrgDiffLD64;
FIXP_DBL valLD64,maxValLD64,maxValAboveLD64;
INT bLPsignal = 0;
maxValLD64 = FL2FXCONST_DBL(-1.0f);
for(i = numBands - 1 - 2; i > pFreqBandTable[0];i--){
nrgLow = pNrgVector[i];
nrgHigh = pNrgVector[i + 2];
if(nrgLow != FL2FXCONST_DBL(0.0f) && nrgLow > nrgHigh){
nrgLowLD64 = CalcLdData(nrgLow>>1);
nrgDiffLD64 = CalcLdData((nrgLow>>1)-(nrgHigh>>1));
valLD64 = nrgDiffLD64-nrgLowLD64;
if(valLD64 > maxValLD64){
maxDerivPos = i;
maxValLD64 = valLD64;
}
if(maxValLD64 > mhThresh.derivThresMaxLD64) {
break;
}
}
}
/* Find the largest "gradient" above. (should be relatively flat, hence we expect a low value
if the signal is LP.*/
maxValAboveLD64 = FL2FXCONST_DBL(-1.0f);
for(i = numBands - 1 - 2; i > maxDerivPos + 2;i--){
nrgLow = pNrgVector[i];
nrgHigh = pNrgVector[i + 2];
if(nrgLow != FL2FXCONST_DBL(0.0f) && nrgLow > nrgHigh){
nrgLowLD64 = CalcLdData(nrgLow>>1);
nrgDiffLD64 = CalcLdData((nrgLow>>1)-(nrgHigh>>1));
valLD64 = nrgDiffLD64-nrgLowLD64;
if(valLD64 > maxValAboveLD64){
maxValAboveLD64 = valLD64;
}
}
else {
if(nrgHigh != FL2FXCONST_DBL(0.0f) && nrgHigh > nrgLow){
nrgHighLD64 = CalcLdData(nrgHigh>>1);
nrgDiffLD64 = CalcLdData((nrgHigh>>1)-(nrgLow>>1));
valLD64 = nrgDiffLD64-nrgHighLD64;
if(valLD64 > maxValAboveLD64){
maxValAboveLD64 = valLD64;
}
}
}
}
if(maxValLD64 > mhThresh.derivThresMaxLD64 && maxValAboveLD64 < mhThresh.derivThresAboveLD64){
bLPsignal = 1;
for(i = maxDerivPos - 1; i > maxDerivPos - 5 && i >= 0 ; i--){
if(pNrgVector[i] != FL2FXCONST_DBL(0.0f) && pNrgVector[i] > pNrgVector[maxDerivPos + 2]){
nrgDiffLD64 = CalcLdData((pNrgVector[i]>>1)-(pNrgVector[maxDerivPos + 2]>>1));
nrgLD64 = CalcLdData(pNrgVector[i]>>1);
valLD64 = nrgDiffLD64-nrgLD64;
if(valLD64 < mhThresh.derivThresBelowLD64) {
bLPsignal = 0;
break;
}
}
else{
bLPsignal = 0;
break;
}
}
}
if(bLPsignal){
for(i=0;i<nSfb;i++){
if(maxDerivPos >= pFreqBandTable[i] && maxDerivPos < pFreqBandTable[i+1])
break;
}
if(pAddHarmSfb[i]){
pAddHarmSfb[i] = 0;
for(est = start; est < stop ; est++){
pDetectionVectors[est][i] = 0;
}
}
}
}
/**************************************************************************/
/*!
\brief Checks if it is allowed to detect a missing tone, that wasn't
detected previously.
\return newDetectionAllowed flag.
*/
/**************************************************************************/
static INT isDetectionOfNewToneAllowed(const SBR_FRAME_INFO *pFrameInfo,
INT *pDetectionStartPos,
INT noEstPerFrame,
INT prevTransientFrame,
INT prevTransientPos,
INT prevTransientFlag,
INT transientPosOffset,
INT transientFlag,
INT transientPos,
INT deltaTime,
HANDLE_SBR_MISSING_HARMONICS_DETECTOR h_sbrMissingHarmonicsDetector)
{
INT transientFrame, newDetectionAllowed;
/* Determine if this is a frame where a transient starts...
* If the transient flag was set the previous frame but not the
* transient frame flag, the transient frame flag is set in the current frame.
*****************************************************************************/
transientFrame = 0;
if(transientFlag){
if(transientPos + transientPosOffset < pFrameInfo->borders[pFrameInfo->nEnvelopes])
transientFrame = 1;
if(noEstPerFrame > 1){
if(transientPos + transientPosOffset > h_sbrMissingHarmonicsDetector->timeSlots >> 1){
*pDetectionStartPos = noEstPerFrame;
}
else{
*pDetectionStartPos = noEstPerFrame >> 1;
}
}
else{
*pDetectionStartPos = noEstPerFrame;
}
}
else{
if(prevTransientFlag && !prevTransientFrame){
transientFrame = 1;
*pDetectionStartPos = 0;
}
}
/*
* Determine if detection of new missing harmonics are allowed.
* If the frame contains a transient it's ok. If the previous
* frame contained a transient it needs to be sufficiently close
* to the start of the current frame.
****************************************************************/
newDetectionAllowed = 0;
if(transientFrame){
newDetectionAllowed = 1;
}
else {
if(prevTransientFrame &&
fixp_abs(pFrameInfo->borders[0] - (prevTransientPos + transientPosOffset -
h_sbrMissingHarmonicsDetector->timeSlots)) < deltaTime)
newDetectionAllowed = 1;
*pDetectionStartPos = 0;
}
h_sbrMissingHarmonicsDetector->previousTransientFlag = transientFlag;
h_sbrMissingHarmonicsDetector->previousTransientFrame = transientFrame;
h_sbrMissingHarmonicsDetector->previousTransientPos = transientPos;
return (newDetectionAllowed);
}
/**************************************************************************/
/*!
\brief Cleans up the detection after a transient.
\return none.
*/
/**************************************************************************/
static void transientCleanUp(FIXP_DBL **quotaBuffer,
INT nSfb,
UCHAR **detectionVectors,
UCHAR *pAddHarmSfb,
UCHAR *pPrevAddHarmSfb,
INT ** signBuffer,
const UCHAR *pFreqBandTable,
INT start,
INT stop,
INT newDetectionAllowed,
FIXP_DBL *pNrgVector,
THRES_HOLDS mhThresh)
{
INT i,j,li, ui,est;
for(est=start; est < stop; est++) {
for(i=0; i<nSfb; i++) {
pAddHarmSfb[i] = pAddHarmSfb[i] || detectionVectors[est][i];
}
}
if(newDetectionAllowed == 1){
/*
* Check for duplication of sines located
* on the border of two scf-bands.
*************************************************/
for(i=0;i<nSfb-1;i++) {
li = pFreqBandTable[i];
ui = pFreqBandTable[i+1];
/* detection in adjacent channels.*/
if(pAddHarmSfb[i] && pAddHarmSfb[i+1]) {
FIXP_DBL maxVal1, maxVal2;
INT maxPos1, maxPos2, maxPosTime1, maxPosTime2;
li = pFreqBandTable[i];
ui = pFreqBandTable[i+1];
/* Find maximum tonality in the the two scf bands.*/
maxPosTime1 = start;
maxPos1 = li;
maxVal1 = quotaBuffer[start][li];
for(est = start; est < stop; est++){
for(j = li; j<ui; j++){
if(quotaBuffer[est][j] > maxVal1){
maxVal1 = quotaBuffer[est][j];
maxPos1 = j;
maxPosTime1 = est;
}
}
}
li = pFreqBandTable[i+1];
ui = pFreqBandTable[i+2];
/* Find maximum tonality in the the two scf bands.*/
maxPosTime2 = start;
maxPos2 = li;
maxVal2 = quotaBuffer[start][li];
for(est = start; est < stop; est++){
for(j = li; j<ui; j++){
if(quotaBuffer[est][j] > maxVal2){
maxVal2 = quotaBuffer[est][j];
maxPos2 = j;
maxPosTime2 = est;
}
}
}
/* If the maximum values are in adjacent QMF-channels, we need to remove
the lowest of the two.*/
if(maxPos2-maxPos1 < 2){
if(pPrevAddHarmSfb[i] == 1 && pPrevAddHarmSfb[i+1] == 0){
/* Keep the lower, remove the upper.*/
pAddHarmSfb[i+1] = 0;
for(est=start; est<stop; est++){
detectionVectors[est][i+1] = 0;
}
}
else{
if(pPrevAddHarmSfb[i] == 0 && pPrevAddHarmSfb[i+1] == 1){
/* Keep the upper, remove the lower.*/
pAddHarmSfb[i] = 0;
for(est=start; est<stop; est++){
detectionVectors[est][i] = 0;
}
}
else{
/* If the maximum values are in adjacent QMF-channels, and if the signs indicate that it is the same sine,
we need to remove the lowest of the two.*/
if(maxVal1 > maxVal2){
if(signBuffer[maxPosTime1][maxPos2] < 0 && signBuffer[maxPosTime1][maxPos1] > 0){
/* Keep the lower, remove the upper.*/
pAddHarmSfb[i+1] = 0;
for(est=start; est<stop; est++){
detectionVectors[est][i+1] = 0;
}
}
}
else{
if(signBuffer[maxPosTime2][maxPos2] < 0 && signBuffer[maxPosTime2][maxPos1] > 0){
/* Keep the upper, remove the lower.*/
pAddHarmSfb[i] = 0;
for(est=start; est<stop; est++){
detectionVectors[est][i] = 0;
}
}
}
}
}
}
}
}
/* Make sure that the detection is not the cut-off of a low pass filter. */
removeLowPassDetection(pAddHarmSfb,
detectionVectors,
start,
stop,
nSfb,
pFreqBandTable,
pNrgVector,
mhThresh);
}
else {
/*
* If a missing harmonic wasn't missing the previous frame
* the transient-flag needs to be set in order to be allowed to detect it.
*************************************************************************/
for(i=0;i<nSfb;i++){
if(pAddHarmSfb[i] - pPrevAddHarmSfb[i] > 0)
pAddHarmSfb[i] = 0;
}
}
}
/**************************************************************************/
/*!
\brief Do detection for one tonality estimate.
\return none.
*/
/**************************************************************************/
static void detection(FIXP_DBL *quotaBuffer,
FIXP_DBL *pDiffVecScfb,
INT nSfb,
UCHAR *pHarmVec,
const UCHAR *pFreqBandTable,
FIXP_DBL *sfmOrig,
FIXP_DBL *sfmSbr,
GUIDE_VECTORS guideVectors,
GUIDE_VECTORS newGuideVectors,
THRES_HOLDS mhThresh)
{
INT i,j,ll, lu;
FIXP_DBL thresTemp,thresOrig;
/*
* Do detection on the difference vector, i.e. the difference between
* the original and the transposed.
*********************************************************************/
for(i=0;i<nSfb;i++){
thresTemp = (guideVectors.guideVectorDiff[i] != FL2FXCONST_DBL(0.0f))
? fixMax(fMult(mhThresh.decayGuideDiff,guideVectors.guideVectorDiff[i]), mhThresh.thresHoldDiffGuide)
: mhThresh.thresHoldDiff;
thresTemp = fixMin(thresTemp, mhThresh.thresHoldDiff);
if(pDiffVecScfb[i] > thresTemp){
pHarmVec[i] = 1;
newGuideVectors.guideVectorDiff[i] = pDiffVecScfb[i];
}
else{
/* If the guide wasn't zero, but the current level is to low,
start tracking the decay on the tone in the original rather
than the difference.*/
if(guideVectors.guideVectorDiff[i] != FL2FXCONST_DBL(0.0f)){
guideVectors.guideVectorOrig[i] = mhThresh.thresHoldToneGuide;
}
}
}
/*
* Trace tones in the original signal that at one point
* have been detected because they will be replaced by
* multiple tones in the sbr signal.
****************************************************/
for(i=0;i<nSfb;i++){
ll = pFreqBandTable[i];
lu = pFreqBandTable[i+1];
thresOrig = fixMax(fMult(guideVectors.guideVectorOrig[i], mhThresh.decayGuideOrig), mhThresh.thresHoldToneGuide);
thresOrig = fixMin(thresOrig, mhThresh.thresHoldTone);
if(guideVectors.guideVectorOrig[i] != FL2FXCONST_DBL(0.0f)){
for(j= ll;j<lu;j++){
if(quotaBuffer[j] > thresOrig){
pHarmVec[i] = 1;
newGuideVectors.guideVectorOrig[i] = quotaBuffer[j];
}
}
}
}
/*
* Check for multiple sines in the transposed signal,
* where there is only one in the original.
****************************************************/
thresOrig = mhThresh.thresHoldTone;
for(i=0;i<nSfb;i++){
ll = pFreqBandTable[i];
lu = pFreqBandTable[i+1];
if(pHarmVec[i] == 0){
if(lu -ll > 1){
for(j= ll;j<lu;j++){
if(quotaBuffer[j] > thresOrig && (sfmSbr[i] > mhThresh.sfmThresSbr && sfmOrig[i] < mhThresh.sfmThresOrig)){
pHarmVec[i] = 1;
newGuideVectors.guideVectorOrig[i] = quotaBuffer[j];
}
}
}
else{
if(i < nSfb -1){
ll = pFreqBandTable[i];
if(i>0){
if(quotaBuffer[ll] > mhThresh.thresHoldTone && (pDiffVecScfb[i+1] < mhThresh.invThresHoldTone || pDiffVecScfb[i-1] < mhThresh.invThresHoldTone)){
pHarmVec[i] = 1;
newGuideVectors.guideVectorOrig[i] = quotaBuffer[ll];
}
}
else{
if(quotaBuffer[ll] > mhThresh.thresHoldTone && pDiffVecScfb[i+1] < mhThresh.invThresHoldTone){
pHarmVec[i] = 1;
newGuideVectors.guideVectorOrig[i] = quotaBuffer[ll];
}
}
}
}
}
}
}
/**************************************************************************/
/*!
\brief Do detection for every tonality estimate, using forward prediction.
\return none.
*/
/**************************************************************************/
static void detectionWithPrediction(FIXP_DBL **quotaBuffer,
FIXP_DBL **pDiffVecScfb,
INT ** signBuffer,
INT nSfb,
const UCHAR* pFreqBandTable,
FIXP_DBL **sfmOrig,
FIXP_DBL **sfmSbr,
UCHAR **detectionVectors,
UCHAR *pPrevAddHarmSfb,
GUIDE_VECTORS *guideVectors,
INT noEstPerFrame,
INT detectionStart,
INT totNoEst,
INT newDetectionAllowed,
INT *pAddHarmFlag,
UCHAR *pAddHarmSfb,
FIXP_DBL *pNrgVector,
const DETECTOR_PARAMETERS_MH *mhParams)
{
INT est = 0,i;
INT start;
FDKmemclear(pAddHarmSfb,nSfb*sizeof(UCHAR));
if(newDetectionAllowed){
if(totNoEst > 1){
start = detectionStart;
if (start != 0) {
FDKmemcpy(guideVectors[start].guideVectorDiff,guideVectors[0].guideVectorDiff,nSfb*sizeof(FIXP_DBL));
FDKmemcpy(guideVectors[start].guideVectorOrig,guideVectors[0].guideVectorOrig,nSfb*sizeof(FIXP_DBL));
FDKmemclear(guideVectors[start-1].guideVectorDetected,nSfb*sizeof(UCHAR));
}
}
else{
start = 0;
}
}
else{
start = 0;
}
for(est = start; est < totNoEst; est++){
/*
* Do detection on the current frame using
* guide-info from the previous.
*******************************************/
if(est > 0){
FDKmemcpy(guideVectors[est].guideVectorDetected,detectionVectors[est-1],nSfb*sizeof(UCHAR));
}
FDKmemclear(detectionVectors[est], nSfb*sizeof(UCHAR));
if(est < totNoEst-1){
FDKmemclear(guideVectors[est+1].guideVectorDiff,nSfb*sizeof(FIXP_DBL));
FDKmemclear(guideVectors[est+1].guideVectorOrig,nSfb*sizeof(FIXP_DBL));
FDKmemclear(guideVectors[est+1].guideVectorDetected,nSfb*sizeof(UCHAR));
detection(quotaBuffer[est],
pDiffVecScfb[est],
nSfb,
detectionVectors[est],
pFreqBandTable,
sfmOrig[est],
sfmSbr[est],
guideVectors[est],
guideVectors[est+1],
mhParams->thresHolds);
}
else{
FDKmemclear(guideVectors[est].guideVectorDiff,nSfb*sizeof(FIXP_DBL));
FDKmemclear(guideVectors[est].guideVectorOrig,nSfb*sizeof(FIXP_DBL));
FDKmemclear(guideVectors[est].guideVectorDetected,nSfb*sizeof(UCHAR));
detection(quotaBuffer[est],
pDiffVecScfb[est],
nSfb,
detectionVectors[est],
pFreqBandTable,
sfmOrig[est],
sfmSbr[est],
guideVectors[est],
guideVectors[est],
mhParams->thresHolds);
}
}
/* Clean up the detection.*/
transientCleanUp(quotaBuffer,
nSfb,
detectionVectors,
pAddHarmSfb,
pPrevAddHarmSfb,
signBuffer,
pFreqBandTable,
start,
totNoEst,
newDetectionAllowed,
pNrgVector,
mhParams->thresHolds);
/* Set flag... */
*pAddHarmFlag = 0;
for(i=0; i<nSfb; i++){
if(pAddHarmSfb[i]){
*pAddHarmFlag = 1;
break;
}
}
FDKmemcpy(pPrevAddHarmSfb, pAddHarmSfb, nSfb*sizeof(UCHAR));
FDKmemcpy(guideVectors[0].guideVectorDetected,pAddHarmSfb,nSfb*sizeof(INT));
for(i=0; i<nSfb ; i++){
guideVectors[0].guideVectorDiff[i] = FL2FXCONST_DBL(0.0f);
guideVectors[0].guideVectorOrig[i] = FL2FXCONST_DBL(0.0f);
if(pAddHarmSfb[i] == 1){
/* If we had a detection use the guide-value in the next frame from the last estimate were the detection
was done.*/
for(est=start; est < totNoEst; est++){
if(guideVectors[est].guideVectorDiff[i] != FL2FXCONST_DBL(0.0f)){
guideVectors[0].guideVectorDiff[i] = guideVectors[est].guideVectorDiff[i];
}
if(guideVectors[est].guideVectorOrig[i] != FL2FXCONST_DBL(0.0f)){
guideVectors[0].guideVectorOrig[i] = guideVectors[est].guideVectorOrig[i];
}
}
}
}
}
/**************************************************************************/
/*!
\brief Calculates a compensation vector for the energy data.
This function calculates a compensation vector for the energy data (i.e.
envelope data) that is calculated elsewhere. This is since, one sine on
the border of two scalefactor bands, will be replace by one sine in the
middle of either scalefactor band. However, since the sine that is replaced
will influence the energy estimate in both scalefactor bands (in the envelops
calculation function) a compensation value is required in order to avoid
noise substitution in the decoder next to the synthetic sine.
\return none.
*/
/**************************************************************************/
static void calculateCompVector(UCHAR *pAddHarmSfb,
FIXP_DBL **pTonalityMatrix,
INT ** pSignMatrix,
UCHAR *pEnvComp,
INT nSfb,
const UCHAR *freqBandTable,
INT totNoEst,
INT maxComp,
UCHAR *pPrevEnvComp,
INT newDetectionAllowed)
{
INT scfBand,est,l,ll,lu,maxPosF,maxPosT;
FIXP_DBL maxVal;
INT compValue;
FIXP_DBL tmp;
FDKmemclear(pEnvComp,nSfb*sizeof(UCHAR));
for(scfBand=0; scfBand < nSfb; scfBand++){
if(pAddHarmSfb[scfBand]){ /* A missing sine was detected */
ll = freqBandTable[scfBand];
lu = freqBandTable[scfBand+1];
maxPosF = 0; /* First find the maximum*/
maxPosT = 0;
maxVal = FL2FXCONST_DBL(0.0f);
for(est=0;est<totNoEst;est++){
for(l=ll; l<lu; l++){
if(pTonalityMatrix[est][l] > maxVal){
maxVal = pTonalityMatrix[est][l];
maxPosF = l;
maxPosT = est;
}
}
}
/*
* If the maximum tonality is at the lower border of the
* scalefactor band, we check the sign of the adjacent channels
* to see if this sine is shared by the lower channel. If so, the
* energy of the single sine will be present in two scalefactor bands
* in the SBR data, which will cause problems in the decoder, when we
* add a sine to just one of the channels.
*********************************************************************/
if(maxPosF == ll && scfBand){
if(!pAddHarmSfb[scfBand - 1]) { /* No detection below*/
if (pSignMatrix[maxPosT][maxPosF - 1] > 0 && pSignMatrix[maxPosT][maxPosF] < 0) {
/* The comp value is calulated as the tonallity value, i.e we want to
reduce the envelope data for this channel with as much as the tonality
that is spread from the channel above. (ld64(RELAXATION) = 0.31143075889) */
tmp = fixp_abs((FIXP_DBL)CalcLdData(pTonalityMatrix[maxPosT][maxPosF - 1]) + RELAXATION_LD64);
tmp = (tmp >> (DFRACT_BITS-1-LD_DATA_SHIFT-1)) + (FIXP_DBL)1; /* shift one bit less for rounding */
compValue = ((INT)(LONG)tmp) >> 1;
/* limit the comp-value*/
if (compValue > maxComp)
compValue = maxComp;
pEnvComp[scfBand-1] = compValue;
}
}
}
/*
* Same as above, but for the upper end of the scalefactor-band.
***************************************************************/
if(maxPosF == lu-1 && scfBand+1 < nSfb){ /* Upper border*/
if(!pAddHarmSfb[scfBand + 1]) {
if (pSignMatrix[maxPosT][maxPosF] > 0 && pSignMatrix[maxPosT][maxPosF + 1] < 0) {
tmp = fixp_abs((FIXP_DBL)CalcLdData(pTonalityMatrix[maxPosT][maxPosF + 1]) + RELAXATION_LD64);
tmp = (tmp >> (DFRACT_BITS-1-LD_DATA_SHIFT-1)) + (FIXP_DBL)1; /* shift one bit less for rounding */
compValue = ((INT)(LONG)tmp) >> 1;
if (compValue > maxComp)
compValue = maxComp;
pEnvComp[scfBand+1] = compValue;
}
}
}
}
}
if(newDetectionAllowed == 0){
for(scfBand=0;scfBand<nSfb;scfBand++){
if(pEnvComp[scfBand] != 0 && pPrevEnvComp[scfBand] == 0)
pEnvComp[scfBand] = 0;
}
}
/* remember the value for the next frame.*/
FDKmemcpy(pPrevEnvComp,pEnvComp,nSfb*sizeof(UCHAR));
}
/**************************************************************************/
/*!
\brief Detects where strong tonal components will be missing after
HFR in the decoder.
\return none.
*/
/**************************************************************************/
void
FDKsbrEnc_SbrMissingHarmonicsDetectorQmf(HANDLE_SBR_MISSING_HARMONICS_DETECTOR h_sbrMHDet,
FIXP_DBL ** pQuotaBuffer,
INT ** pSignBuffer,
SCHAR* indexVector,
const SBR_FRAME_INFO *pFrameInfo,
const UCHAR* pTranInfo,
INT* pAddHarmonicsFlag,
UCHAR* pAddHarmonicsScaleFactorBands,
const UCHAR* freqBandTable,
INT nSfb,
UCHAR* envelopeCompensation,
FIXP_DBL *pNrgVector)
{
INT transientFlag = pTranInfo[1];
INT transientPos = pTranInfo[0];
INT newDetectionAllowed;
INT transientDetStart = 0;
UCHAR ** detectionVectors = h_sbrMHDet->detectionVectors;
INT move = h_sbrMHDet->move;
INT noEstPerFrame = h_sbrMHDet->noEstPerFrame;
INT totNoEst = h_sbrMHDet->totNoEst;
INT prevTransientFlag = h_sbrMHDet->previousTransientFlag;
INT prevTransientFrame = h_sbrMHDet->previousTransientFrame;
INT transientPosOffset = h_sbrMHDet->transientPosOffset;
INT prevTransientPos = h_sbrMHDet->previousTransientPos;
GUIDE_VECTORS* guideVectors = h_sbrMHDet->guideVectors;
INT deltaTime = h_sbrMHDet->mhParams->deltaTime;
INT maxComp = h_sbrMHDet->mhParams->maxComp;
int est;
/*
Buffer values.
*/
FDK_ASSERT(move<=(MAX_NO_OF_ESTIMATES>>1));
FDK_ASSERT(noEstPerFrame<=(MAX_NO_OF_ESTIMATES>>1));
FIXP_DBL *sfmSbr[MAX_NO_OF_ESTIMATES];
FIXP_DBL *sfmOrig[MAX_NO_OF_ESTIMATES];
FIXP_DBL *tonalityDiff[MAX_NO_OF_ESTIMATES];
for (est=0; est < MAX_NO_OF_ESTIMATES/2; est++) {
sfmSbr[est] = h_sbrMHDet->sfmSbr[est];
sfmOrig[est] = h_sbrMHDet->sfmOrig[est];
tonalityDiff[est] = h_sbrMHDet->tonalityDiff[est];
}
C_ALLOC_SCRATCH_START(scratch_mem, FIXP_DBL, (3*MAX_NO_OF_ESTIMATES/2*MAX_FREQ_COEFFS));
FIXP_DBL *scratch = scratch_mem;
for (; est < MAX_NO_OF_ESTIMATES; est++) {
sfmSbr[est] = scratch; scratch+=MAX_FREQ_COEFFS;
sfmOrig[est] = scratch; scratch+=MAX_FREQ_COEFFS;
tonalityDiff[est] = scratch; scratch+=MAX_FREQ_COEFFS;
}
/* Determine if we're allowed to detect "missing harmonics" that wasn't detected before.
In order to be allowed to do new detection, there must be a transient in the current
frame, or a transient in the previous frame sufficiently close to the current frame. */
newDetectionAllowed = isDetectionOfNewToneAllowed(pFrameInfo,
&transientDetStart,
noEstPerFrame,
prevTransientFrame,
prevTransientPos,
prevTransientFlag,
transientPosOffset,
transientFlag,
transientPos,
deltaTime,
h_sbrMHDet);
/* Calulate the variables that will be used subsequently for the actual detection */
calculateDetectorInput(pQuotaBuffer,
indexVector,
tonalityDiff,
sfmOrig,
sfmSbr,
freqBandTable,
nSfb,
noEstPerFrame,
move);
/* Do the actual detection using information from previous detections */
detectionWithPrediction(pQuotaBuffer,
tonalityDiff,
pSignBuffer,
nSfb,
freqBandTable,
sfmOrig,
sfmSbr,
detectionVectors,
h_sbrMHDet->guideScfb,
guideVectors,
noEstPerFrame,
transientDetStart,
totNoEst,
newDetectionAllowed,
pAddHarmonicsFlag,
pAddHarmonicsScaleFactorBands,
pNrgVector,
h_sbrMHDet->mhParams);
/* Calculate the comp vector, so that the energy can be
compensated for a sine between two QMF-bands. */
calculateCompVector(pAddHarmonicsScaleFactorBands,
pQuotaBuffer,
pSignBuffer,
envelopeCompensation,
nSfb,
freqBandTable,
totNoEst,
maxComp,
h_sbrMHDet->prevEnvelopeCompensation,
newDetectionAllowed);
for (est=0; est < move; est++) {
FDKmemcpy(tonalityDiff[est], tonalityDiff[est + noEstPerFrame], sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemcpy(sfmOrig[est], sfmOrig[est + noEstPerFrame], sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemcpy(sfmSbr[est], sfmSbr[est + noEstPerFrame], sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
}
C_ALLOC_SCRATCH_END(scratch, FIXP_DBL, (3*MAX_NO_OF_ESTIMATES/2*MAX_FREQ_COEFFS));
}
/**************************************************************************/
/*!
\brief Initialize an instance of the missing harmonics detector.
\return errorCode, noError if OK.
*/
/**************************************************************************/
INT
FDKsbrEnc_CreateSbrMissingHarmonicsDetector (
HANDLE_SBR_MISSING_HARMONICS_DETECTOR hSbrMHDet,
INT chan)
{
HANDLE_SBR_MISSING_HARMONICS_DETECTOR hs = hSbrMHDet;
INT i;
UCHAR* detectionVectors = GetRam_Sbr_detectionVectors(chan);
UCHAR* guideVectorDetected = GetRam_Sbr_guideVectorDetected(chan);
FIXP_DBL* guideVectorDiff = GetRam_Sbr_guideVectorDiff(chan);
FIXP_DBL* guideVectorOrig = GetRam_Sbr_guideVectorOrig(chan);
FDKmemclear (hs,sizeof(SBR_MISSING_HARMONICS_DETECTOR));
hs->prevEnvelopeCompensation = GetRam_Sbr_prevEnvelopeCompensation(chan);
hs->guideScfb = GetRam_Sbr_guideScfb(chan);
for(i=0; i<MAX_NO_OF_ESTIMATES; i++) {
hs->guideVectors[i].guideVectorDiff = guideVectorDiff + (i*MAX_FREQ_COEFFS);
hs->guideVectors[i].guideVectorOrig = guideVectorOrig + (i*MAX_FREQ_COEFFS);
hs->detectionVectors[i] = detectionVectors + (i*MAX_FREQ_COEFFS);
hs->guideVectors[i].guideVectorDetected = guideVectorDetected + (i*MAX_FREQ_COEFFS);
}
return 0;
}
/**************************************************************************/
/*!
\brief Initialize an instance of the missing harmonics detector.
\return errorCode, noError if OK.
*/
/**************************************************************************/
INT
FDKsbrEnc_InitSbrMissingHarmonicsDetector (
HANDLE_SBR_MISSING_HARMONICS_DETECTOR hSbrMHDet,
INT sampleFreq,
INT frameSize,
INT nSfb,
INT qmfNoChannels,
INT totNoEst,
INT move,
INT noEstPerFrame,
UINT sbrSyntaxFlags
)
{
HANDLE_SBR_MISSING_HARMONICS_DETECTOR hs = hSbrMHDet;
int i;
FDK_ASSERT(totNoEst <= MAX_NO_OF_ESTIMATES);
if (sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY)
{
switch(frameSize){
case 1024:
case 512:
hs->transientPosOffset = FRAME_MIDDLE_SLOT_512LD;
hs->timeSlots = 16;
break;
case 960:
case 480:
hs->transientPosOffset = FRAME_MIDDLE_SLOT_512LD;
hs->timeSlots = 15;
break;
default:
return -1;
}
} else
{
switch(frameSize){
case 2048:
case 1024:
hs->transientPosOffset = FRAME_MIDDLE_SLOT_2048;
hs->timeSlots = NUMBER_TIME_SLOTS_2048;
break;
case 1920:
case 960:
hs->transientPosOffset = FRAME_MIDDLE_SLOT_1920;
hs->timeSlots = NUMBER_TIME_SLOTS_1920;
break;
default:
return -1;
}
}
if (sbrSyntaxFlags & SBR_SYNTAX_LOW_DELAY) {
hs->mhParams = ¶msAacLd;
} else
hs->mhParams = ¶msAac;
hs->qmfNoChannels = qmfNoChannels;
hs->sampleFreq = sampleFreq;
hs->nSfb = nSfb;
hs->totNoEst = totNoEst;
hs->move = move;
hs->noEstPerFrame = noEstPerFrame;
for(i=0; i<totNoEst; i++) {
FDKmemclear (hs->guideVectors[i].guideVectorDiff,sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemclear (hs->guideVectors[i].guideVectorOrig,sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemclear (hs->detectionVectors[i],sizeof(UCHAR)*MAX_FREQ_COEFFS);
FDKmemclear (hs->guideVectors[i].guideVectorDetected,sizeof(UCHAR)*MAX_FREQ_COEFFS);
}
//for(i=0; i<totNoEst/2; i++) {
for(i=0; i<MAX_NO_OF_ESTIMATES/2; i++) {
FDKmemclear (hs->tonalityDiff[i],sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemclear (hs->sfmOrig[i],sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
FDKmemclear (hs->sfmSbr[i],sizeof(FIXP_DBL)*MAX_FREQ_COEFFS);
}
FDKmemclear ( hs->prevEnvelopeCompensation, sizeof(UCHAR)*MAX_FREQ_COEFFS);
FDKmemclear ( hs->guideScfb, sizeof(UCHAR)*MAX_FREQ_COEFFS);
hs->previousTransientFlag = 0;
hs->previousTransientFrame = 0;
hs->previousTransientPos = 0;
return (0);
}
/**************************************************************************/
/*!
\brief Deletes an instance of the missing harmonics detector.
\return none.
*/
/**************************************************************************/
void
FDKsbrEnc_DeleteSbrMissingHarmonicsDetector(HANDLE_SBR_MISSING_HARMONICS_DETECTOR hSbrMHDet)
{
if (hSbrMHDet) {
HANDLE_SBR_MISSING_HARMONICS_DETECTOR hs = hSbrMHDet;
FreeRam_Sbr_detectionVectors(&hs->detectionVectors[0]);
FreeRam_Sbr_guideVectorDetected(&hs->guideVectors[0].guideVectorDetected);
FreeRam_Sbr_guideVectorDiff(&hs->guideVectors[0].guideVectorDiff);
FreeRam_Sbr_guideVectorOrig(&hs->guideVectors[0].guideVectorOrig);
FreeRam_Sbr_prevEnvelopeCompensation(&hs->prevEnvelopeCompensation);
FreeRam_Sbr_guideScfb(&hs->guideScfb);
}
}
/**************************************************************************/
/*!
\brief Resets an instance of the missing harmonics detector.
\return error code, noError if OK.
*/
/**************************************************************************/
INT
FDKsbrEnc_ResetSbrMissingHarmonicsDetector (HANDLE_SBR_MISSING_HARMONICS_DETECTOR hSbrMissingHarmonicsDetector,
INT nSfb)
{
int i;
FIXP_DBL tempGuide[MAX_FREQ_COEFFS];
UCHAR tempGuideInt[MAX_FREQ_COEFFS];
INT nSfbPrev;
nSfbPrev = hSbrMissingHarmonicsDetector->nSfb;
hSbrMissingHarmonicsDetector->nSfb = nSfb;
FDKmemcpy( tempGuideInt, hSbrMissingHarmonicsDetector->guideScfb, nSfbPrev * sizeof(UCHAR) );
if ( nSfb > nSfbPrev ) {
for ( i = 0; i < (nSfb - nSfbPrev); i++ ) {
hSbrMissingHarmonicsDetector->guideScfb[i] = 0;
}
for ( i = 0; i < nSfbPrev; i++ ) {
hSbrMissingHarmonicsDetector->guideScfb[i + (nSfb - nSfbPrev)] = tempGuideInt[i];
}
}
else {
for ( i = 0; i < nSfb; i++ ) {
hSbrMissingHarmonicsDetector->guideScfb[i] = tempGuideInt[i + (nSfbPrev-nSfb)];
}
}
FDKmemcpy ( tempGuide, hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDiff, nSfbPrev * sizeof(FIXP_DBL) );
if (nSfb > nSfbPrev ) {
for ( i = 0; i < (nSfb - nSfbPrev); i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDiff[i] = FL2FXCONST_DBL(0.0f);
}
for ( i = 0; i < nSfbPrev; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDiff[i + (nSfb - nSfbPrev)] = tempGuide[i];
}
}
else {
for ( i = 0; i < nSfb; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDiff[i] = tempGuide[i + (nSfbPrev-nSfb)];
}
}
FDKmemcpy ( tempGuide, hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorOrig, nSfbPrev * sizeof(FIXP_DBL) );
if ( nSfb > nSfbPrev ) {
for ( i = 0; i< (nSfb - nSfbPrev); i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorOrig[i] = FL2FXCONST_DBL(0.0f);
}
for ( i = 0; i < nSfbPrev; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorOrig[i + (nSfb - nSfbPrev)] = tempGuide[i];
}
}
else {
for ( i = 0; i < nSfb; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorOrig[i] = tempGuide[i + (nSfbPrev-nSfb)];
}
}
FDKmemcpy ( tempGuideInt, hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDetected, nSfbPrev * sizeof(UCHAR) );
if ( nSfb > nSfbPrev ) {
for ( i = 0; i < (nSfb - nSfbPrev); i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDetected[i] = 0;
}
for ( i = 0; i < nSfbPrev; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDetected[i + (nSfb - nSfbPrev)] = tempGuideInt[i];
}
}
else {
for ( i = 0; i < nSfb; i++ ) {
hSbrMissingHarmonicsDetector->guideVectors[0].guideVectorDetected[i] = tempGuideInt[i + (nSfbPrev-nSfb)];
}
}
FDKmemcpy ( tempGuideInt, hSbrMissingHarmonicsDetector->prevEnvelopeCompensation, nSfbPrev * sizeof(UCHAR) );
if ( nSfb > nSfbPrev ) {
for ( i = 0; i < (nSfb - nSfbPrev); i++ ) {
hSbrMissingHarmonicsDetector->prevEnvelopeCompensation[i] = 0;
}
for ( i = 0; i < nSfbPrev; i++ ) {
hSbrMissingHarmonicsDetector->prevEnvelopeCompensation[i + (nSfb - nSfbPrev)] = tempGuideInt[i];
}
}
else {
for ( i = 0; i < nSfb; i++ ) {
hSbrMissingHarmonicsDetector->prevEnvelopeCompensation[i] = tempGuideInt[i + (nSfbPrev-nSfb)];
}
}
return 0;
}
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