blob: 30611e741265f1cdc2d83ef49192b77a0d2735dc [file] [log] [blame]
/* -----------------------------------------------------------------------------
Software License for The Fraunhofer FDK AAC Codec Library for Android
© Copyright 1995 - 2018 Fraunhofer-Gesellschaft zur Förderung 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
----------------------------------------------------------------------------- */
/**************************** SBR decoder library ******************************
Author(s):
Description:
*******************************************************************************/
/*!
\file
\brief Sbr decoder
This module provides the actual decoder implementation. The SBR data (side
information) is already decoded. Only three functions are provided:
\li 1.) createSbrDec(): One time initialization
\li 2.) resetSbrDec(): Called by sbr_Apply() when the information contained in
an SBR_HEADER_ELEMENT requires a reset and recalculation of important SBR
structures. \li 3.) sbr_dec(): The actual decoder. Calls the different tools
such as filterbanks, lppTransposer(), and calculateSbrEnvelope() [the envelope
adjuster].
\sa sbr_dec(), \ref documentationOverview
*/
#include "sbr_dec.h"
#include "sbr_ram.h"
#include "env_extr.h"
#include "env_calc.h"
#include "scale.h"
#include "FDK_matrixCalloc.h"
#include "hbe.h"
#include "genericStds.h"
#include "sbrdec_drc.h"
static void copyHarmonicSpectrum(int *xOverQmf, FIXP_DBL **qmfReal,
FIXP_DBL **qmfImag, int noCols, int overlap,
KEEP_STATES_SYNCED_MODE keepStatesSynced) {
int patchBands;
int patch, band, col, target, sourceBands, i;
int numPatches = 0;
int slotOffset = 0;
FIXP_DBL **ppqmfReal = qmfReal + overlap;
FIXP_DBL **ppqmfImag = qmfImag + overlap;
if (keepStatesSynced == KEEP_STATES_SYNCED_NORMAL) {
slotOffset = noCols - overlap - LPC_ORDER;
}
if (keepStatesSynced == KEEP_STATES_SYNCED_OUTDIFF) {
ppqmfReal = qmfReal;
ppqmfImag = qmfImag;
}
for (i = 1; i < MAX_NUM_PATCHES; i++) {
if (xOverQmf[i] != 0) {
numPatches++;
}
}
for (patch = (MAX_STRETCH_HBE - 1); patch < numPatches; patch++) {
patchBands = xOverQmf[patch + 1] - xOverQmf[patch];
target = xOverQmf[patch];
sourceBands = xOverQmf[MAX_STRETCH_HBE - 1] - xOverQmf[MAX_STRETCH_HBE - 2];
while (patchBands > 0) {
int numBands = sourceBands;
int startBand = xOverQmf[MAX_STRETCH_HBE - 1] - 1;
if (target + numBands >= xOverQmf[patch + 1]) {
numBands = xOverQmf[patch + 1] - target;
}
if ((((target + numBands - 1) % 2) +
((xOverQmf[MAX_STRETCH_HBE - 1] - 1) % 2)) %
2) {
if (numBands == sourceBands) {
numBands--;
} else {
startBand--;
}
}
if (keepStatesSynced == KEEP_STATES_SYNCED_OUTDIFF) {
for (col = slotOffset; col < overlap + LPC_ORDER; col++) {
i = 0;
for (band = numBands; band > 0; band--) {
if ((target + band - 1 < 64) &&
(target + band - 1 < xOverQmf[patch + 1])) {
ppqmfReal[col][target + band - 1] = ppqmfReal[col][startBand - i];
ppqmfImag[col][target + band - 1] = ppqmfImag[col][startBand - i];
i++;
}
}
}
} else {
for (col = slotOffset; col < noCols; col++) {
i = 0;
for (band = numBands; band > 0; band--) {
if ((target + band - 1 < 64) &&
(target + band - 1 < xOverQmf[patch + 1])) {
ppqmfReal[col][target + band - 1] = ppqmfReal[col][startBand - i];
ppqmfImag[col][target + band - 1] = ppqmfImag[col][startBand - i];
i++;
}
}
}
}
target += numBands;
patchBands -= numBands;
}
}
}
/*!
\brief SBR decoder core function for one channel
\image html BufferMgmtDetailed-1632.png
Besides the filter states of the QMF filter bank and the LPC-states of
the LPP-Transposer, processing is mainly based on four buffers:
#timeIn, #timeOut, #WorkBuffer2 and #OverlapBuffer. The #WorkBuffer2
is reused for all channels and might be used by the core decoder, a
static overlap buffer is required for each channel. Due to in-place
processing, #timeIn and #timeOut point to identical locations.
The spectral data is organized in so-called slots. Each slot
contains 64 bands of complex data. The number of slots per frame
depends on the frame size. For mp3PRO, there are 18 slots per frame
and 6 slots per #OverlapBuffer. It is not necessary to have the slots
in located consecutive address ranges.
To optimize memory usage and to minimize the number of memory
accesses, the memory management is organized as follows (slot numbers
based on mp3PRO):
1.) Input time domain signal is located in #timeIn. The last slots
(0..5) of the spectral data of the previous frame are located in the
#OverlapBuffer. In addition, #frameData of the current frame resides
in the upper part of #timeIn.
2.) During the cplxAnalysisQmfFiltering(), 32 samples from #timeIn are
transformed into a slot of up to 32 complex spectral low band values at a
time. The first spectral slot -- nr. 6 -- is written at slot number
zero of #WorkBuffer2. #WorkBuffer2 will be completely filled with
spectral data.
3.) LPP-Transposition in lppTransposer() is processed on 24 slots. During the
transposition, the high band part of the spectral data is replicated
based on the low band data.
Envelope Adjustment is processed on the high band part of the spectral
data only by calculateSbrEnvelope().
4.) The cplxSynthesisQmfFiltering() creates 64 time domain samples out
of a slot of 64 complex spectral values at a time. The first 6 slots
in #timeOut are filled from the results of spectral slots 0..5 in the
#OverlapBuffer. The consecutive slots in timeOut are now filled with
the results of spectral slots 6..17.
5.) The preprocessed slots 18..23 have to be stored in the
#OverlapBuffer.
*/
void sbr_dec(
HANDLE_SBR_DEC hSbrDec, /*!< handle to Decoder channel */
INT_PCM *timeIn, /*!< pointer to input time signal */
INT_PCM *timeOut, /*!< pointer to output time signal */
HANDLE_SBR_DEC hSbrDecRight, /*!< handle to Decoder channel right */
INT_PCM *timeOutRight, /*!< pointer to output time signal */
const int strideOut, /*!< Time data traversal strideOut */
HANDLE_SBR_HEADER_DATA hHeaderData, /*!< Static control data */
HANDLE_SBR_FRAME_DATA hFrameData, /*!< Control data of current frame */
HANDLE_SBR_PREV_FRAME_DATA
hPrevFrameData, /*!< Some control data of last frame */
const int applyProcessing, /*!< Flag for SBR operation */
HANDLE_PS_DEC h_ps_d, const UINT flags, const int codecFrameSize) {
int i, slot, reserve;
int saveLbScale;
int lastSlotOffs;
FIXP_DBL maxVal;
/* temporary pointer / variable for QMF;
required as we want to use temporary buffer
creating one frame delay for HBE in LP mode */
INT_PCM *pTimeInQmf = timeIn;
/* Number of QMF timeslots in the overlap buffer: */
int ov_len = hSbrDec->LppTrans.pSettings->overlap;
/* Number of QMF slots per frame */
int noCols = hHeaderData->numberTimeSlots * hHeaderData->timeStep;
/* create pointer array for data to use for HBE and legacy sbr */
FIXP_DBL *pLowBandReal[(3 * 4) + 2 * ((1024) / (32) * (4) / 2)];
FIXP_DBL *pLowBandImag[(3 * 4) + 2 * ((1024) / (32) * (4) / 2)];
/* set pReal to where QMF analysis writes in case of legacy SBR */
FIXP_DBL **pReal = pLowBandReal + ov_len;
FIXP_DBL **pImag = pLowBandImag + ov_len;
/* map QMF buffer to pointer array (Overlap + Frame)*/
for (i = 0; i < noCols + ov_len; i++) {
pLowBandReal[i] = hSbrDec->qmfDomainInCh->hQmfSlotsReal[i];
pLowBandImag[i] = hSbrDec->qmfDomainInCh->hQmfSlotsImag[i];
}
if ((flags & SBRDEC_USAC_HARMONICSBR)) {
/* in case of harmonic SBR and no HBE_LP map additional buffer for
one more frame to pointer arry */
for (i = 0; i < noCols; i++) {
pLowBandReal[i + noCols + ov_len] = hSbrDec->hQmfHBESlotsReal[i];
pLowBandImag[i + noCols + ov_len] = hSbrDec->hQmfHBESlotsImag[i];
}
/* shift scale values according to buffer */
hSbrDec->scale_ov = hSbrDec->scale_lb;
hSbrDec->scale_lb = hSbrDec->scale_hbe;
/* set pReal to where QMF analysis writes in case of HBE */
pReal += noCols;
pImag += noCols;
if (flags & SBRDEC_SKIP_QMF_ANA) {
/* stereoCfgIndex3 with HBE */
FDK_QmfDomain_QmfData2HBE(hSbrDec->qmfDomainInCh,
hSbrDec->hQmfHBESlotsReal,
hSbrDec->hQmfHBESlotsImag);
} else {
/* We have to move old hbe frame data to lb area of buffer */
for (i = 0; i < noCols; i++) {
FDKmemcpy(pLowBandReal[ov_len + i], hSbrDec->hQmfHBESlotsReal[i],
hHeaderData->numberOfAnalysisBands * sizeof(FIXP_DBL));
FDKmemcpy(pLowBandImag[ov_len + i], hSbrDec->hQmfHBESlotsImag[i],
hHeaderData->numberOfAnalysisBands * sizeof(FIXP_DBL));
}
}
}
/*
low band codec signal subband filtering
*/
if (flags & SBRDEC_SKIP_QMF_ANA) {
if (!(flags & SBRDEC_USAC_HARMONICSBR)) /* stereoCfgIndex3 w/o HBE */
FDK_QmfDomain_WorkBuffer2ProcChannel(hSbrDec->qmfDomainInCh);
} else {
C_AALLOC_SCRATCH_START(qmfTemp, FIXP_DBL, 2 * (64));
qmfAnalysisFiltering(&hSbrDec->qmfDomainInCh->fb, pReal, pImag,
&hSbrDec->qmfDomainInCh->scaling, pTimeInQmf, 0, 1,
qmfTemp);
C_AALLOC_SCRATCH_END(qmfTemp, FIXP_DBL, 2 * (64));
}
/*
Clear upper half of spectrum
*/
if (!((flags & SBRDEC_USAC_HARMONICSBR) &&
(hFrameData->sbrPatchingMode == 0))) {
int nAnalysisBands = hHeaderData->numberOfAnalysisBands;
if (!(flags & SBRDEC_LOW_POWER)) {
for (slot = ov_len; slot < noCols + ov_len; slot++) {
FDKmemclear(&pLowBandReal[slot][nAnalysisBands],
((64) - nAnalysisBands) * sizeof(FIXP_DBL));
FDKmemclear(&pLowBandImag[slot][nAnalysisBands],
((64) - nAnalysisBands) * sizeof(FIXP_DBL));
}
} else {
for (slot = ov_len; slot < noCols + ov_len; slot++) {
FDKmemclear(&pLowBandReal[slot][nAnalysisBands],
((64) - nAnalysisBands) * sizeof(FIXP_DBL));
}
}
}
/*
Shift spectral data left to gain accuracy in transposer and adjustor
*/
/* Range was increased from lsb to no_channels because in some cases (e.g.
USAC conf eSbr_4_Pvc.mp4 and some HBE cases) it could be observed that the
signal between lsb and no_channels is used for the patching process.
*/
maxVal = maxSubbandSample(pReal, (flags & SBRDEC_LOW_POWER) ? NULL : pImag, 0,
hSbrDec->qmfDomainInCh->fb.no_channels, 0, noCols);
reserve = fixMax(0, CntLeadingZeros(maxVal) - 1);
reserve = fixMin(reserve,
DFRACT_BITS - 1 - hSbrDec->qmfDomainInCh->scaling.lb_scale);
/* If all data is zero, lb_scale could become too large */
rescaleSubbandSamples(pReal, (flags & SBRDEC_LOW_POWER) ? NULL : pImag, 0,
hSbrDec->qmfDomainInCh->fb.no_channels, 0, noCols,
reserve);
hSbrDec->qmfDomainInCh->scaling.lb_scale += reserve;
if ((flags & SBRDEC_USAC_HARMONICSBR)) {
/* actually this is our hbe_scale */
hSbrDec->scale_hbe = hSbrDec->qmfDomainInCh->scaling.lb_scale;
/* the real lb_scale is stored in scale_lb from sbr */
hSbrDec->qmfDomainInCh->scaling.lb_scale = hSbrDec->scale_lb;
}
/*
save low band scale, wavecoding or parametric stereo may modify it
*/
saveLbScale = hSbrDec->qmfDomainInCh->scaling.lb_scale;
if (applyProcessing) {
UCHAR *borders = hFrameData->frameInfo.borders;
lastSlotOffs = borders[hFrameData->frameInfo.nEnvelopes] -
hHeaderData->numberTimeSlots;
FIXP_DBL degreeAlias[(64)];
PVC_DYNAMIC_DATA pvcDynamicData;
pvcInitFrame(
&hSbrDec->PvcStaticData, &pvcDynamicData,
(hHeaderData->frameErrorFlag ? 0 : hHeaderData->bs_info.pvc_mode),
hFrameData->ns, hHeaderData->timeStep,
hHeaderData->freqBandData.lowSubband,
hFrameData->frameInfo.pvcBorders[0], hFrameData->pvcID);
if (!hHeaderData->frameErrorFlag && (hHeaderData->bs_info.pvc_mode > 0)) {
pvcDecodeFrame(&hSbrDec->PvcStaticData, &pvcDynamicData, pLowBandReal,
pLowBandImag, ov_len,
SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_lb_scale),
SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.lb_scale));
}
pvcEndFrame(&hSbrDec->PvcStaticData, &pvcDynamicData);
/* The transposer will override most values in degreeAlias[].
The array needs to be cleared at least from lowSubband to highSubband
before. */
if (flags & SBRDEC_LOW_POWER)
FDKmemclear(&degreeAlias[hHeaderData->freqBandData.lowSubband],
(hHeaderData->freqBandData.highSubband -
hHeaderData->freqBandData.lowSubband) *
sizeof(FIXP_DBL));
/*
Inverse filtering of lowband and transposition into the SBR-frequency
range
*/
{
KEEP_STATES_SYNCED_MODE keepStatesSyncedMode =
((flags & SBRDEC_USAC_HARMONICSBR) &&
(hFrameData->sbrPatchingMode != 0))
? KEEP_STATES_SYNCED_NORMAL
: KEEP_STATES_SYNCED_OFF;
if (flags & SBRDEC_USAC_HARMONICSBR) {
if (flags & SBRDEC_QUAD_RATE) {
pReal -= 32;
pImag -= 32;
}
if ((hSbrDec->savedStates == 0) && (hFrameData->sbrPatchingMode == 1)) {
/* copy saved states from previous frame to legacy SBR lpc filterstate
* buffer */
for (i = 0; i < LPC_ORDER + ov_len; i++) {
FDKmemcpy(
hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[i],
hSbrDec->codecQMFBufferReal[noCols - LPC_ORDER - ov_len + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
FDKmemcpy(
hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[i],
hSbrDec->codecQMFBufferImag[noCols - LPC_ORDER - ov_len + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
}
}
/* saving unmodified QMF states in case we are switching from legacy SBR
* to HBE */
for (i = 0; i < hSbrDec->hHBE->noCols; i++) {
FDKmemcpy(hSbrDec->codecQMFBufferReal[i], pLowBandReal[ov_len + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
FDKmemcpy(hSbrDec->codecQMFBufferImag[i], pLowBandImag[ov_len + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
}
QmfTransposerApply(
hSbrDec->hHBE, pReal, pImag, noCols, pLowBandReal, pLowBandImag,
hSbrDec->LppTrans.lpcFilterStatesRealHBE,
hSbrDec->LppTrans.lpcFilterStatesImagHBE,
hFrameData->sbrPitchInBins, hSbrDec->scale_lb, hSbrDec->scale_hbe,
&hSbrDec->qmfDomainInCh->scaling.hb_scale, hHeaderData->timeStep,
borders[0], ov_len, keepStatesSyncedMode);
if (flags & SBRDEC_QUAD_RATE) {
int *xOverQmf = GetxOverBandQmfTransposer(hSbrDec->hHBE);
copyHarmonicSpectrum(xOverQmf, pLowBandReal, pLowBandImag, noCols,
ov_len, keepStatesSyncedMode);
}
}
}
if ((flags & SBRDEC_USAC_HARMONICSBR) &&
(hFrameData->sbrPatchingMode == 0)) {
hSbrDec->prev_frame_lSbr = 0;
hSbrDec->prev_frame_hbeSbr = 1;
lppTransposerHBE(
&hSbrDec->LppTrans, hSbrDec->hHBE, &hSbrDec->qmfDomainInCh->scaling,
pLowBandReal, pLowBandImag, hHeaderData->timeStep, borders[0],
lastSlotOffs, hHeaderData->freqBandData.nInvfBands,
hFrameData->sbr_invf_mode, hPrevFrameData->sbr_invf_mode);
} else {
if (flags & SBRDEC_USAC_HARMONICSBR) {
for (i = 0; i < LPC_ORDER + hSbrDec->LppTrans.pSettings->overlap; i++) {
/*
Store the unmodified qmf Slots values for upper part of spectrum
(required for LPC filtering) required if next frame is a HBE frame
*/
FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesRealHBE[i],
hSbrDec->qmfDomainInCh
->hQmfSlotsReal[hSbrDec->hHBE->noCols - LPC_ORDER + i],
(64) * sizeof(FIXP_DBL));
FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesImagHBE[i],
hSbrDec->qmfDomainInCh
->hQmfSlotsImag[hSbrDec->hHBE->noCols - LPC_ORDER + i],
(64) * sizeof(FIXP_DBL));
}
}
{
hSbrDec->prev_frame_lSbr = 1;
hSbrDec->prev_frame_hbeSbr = 0;
}
lppTransposer(
&hSbrDec->LppTrans, &hSbrDec->qmfDomainInCh->scaling, pLowBandReal,
degreeAlias, // only used if useLP = 1
pLowBandImag, flags & SBRDEC_LOW_POWER,
hHeaderData->bs_info.sbr_preprocessing,
hHeaderData->freqBandData.v_k_master[0], hHeaderData->timeStep,
borders[0], lastSlotOffs, hHeaderData->freqBandData.nInvfBands,
hFrameData->sbr_invf_mode, hPrevFrameData->sbr_invf_mode);
}
/*
Adjust envelope of current frame.
*/
if ((hFrameData->sbrPatchingMode !=
hSbrDec->SbrCalculateEnvelope.sbrPatchingMode)) {
ResetLimiterBands(hHeaderData->freqBandData.limiterBandTable,
&hHeaderData->freqBandData.noLimiterBands,
hHeaderData->freqBandData.freqBandTable[0],
hHeaderData->freqBandData.nSfb[0],
hSbrDec->LppTrans.pSettings->patchParam,
hSbrDec->LppTrans.pSettings->noOfPatches,
hHeaderData->bs_data.limiterBands,
hFrameData->sbrPatchingMode,
(flags & SBRDEC_USAC_HARMONICSBR) &&
(hFrameData->sbrPatchingMode == 0)
? GetxOverBandQmfTransposer(hSbrDec->hHBE)
: NULL,
Get41SbrQmfTransposer(hSbrDec->hHBE));
hSbrDec->SbrCalculateEnvelope.sbrPatchingMode =
hFrameData->sbrPatchingMode;
}
calculateSbrEnvelope(
&hSbrDec->qmfDomainInCh->scaling, &hSbrDec->SbrCalculateEnvelope,
hHeaderData, hFrameData, &pvcDynamicData, pLowBandReal, pLowBandImag,
flags & SBRDEC_LOW_POWER,
degreeAlias, flags,
(hHeaderData->frameErrorFlag || hPrevFrameData->frameErrorFlag));
#if (SBRDEC_MAX_HB_FADE_FRAMES > 0)
/* Avoid hard onsets of high band */
if (hHeaderData->frameErrorFlag) {
if (hSbrDec->highBandFadeCnt < SBRDEC_MAX_HB_FADE_FRAMES) {
hSbrDec->highBandFadeCnt += 1;
}
} else {
if (hSbrDec->highBandFadeCnt >
0) { /* Manipulate high band scale factor to get a smooth fade-in */
hSbrDec->qmfDomainInCh->scaling.hb_scale += hSbrDec->highBandFadeCnt;
hSbrDec->qmfDomainInCh->scaling.hb_scale =
fMin(hSbrDec->qmfDomainInCh->scaling.hb_scale, DFRACT_BITS - 1);
hSbrDec->highBandFadeCnt -= 1;
}
}
#endif
/*
Update hPrevFrameData (to be used in the next frame)
*/
for (i = 0; i < hHeaderData->freqBandData.nInvfBands; i++) {
hPrevFrameData->sbr_invf_mode[i] = hFrameData->sbr_invf_mode[i];
}
hPrevFrameData->coupling = hFrameData->coupling;
hPrevFrameData->stopPos = borders[hFrameData->frameInfo.nEnvelopes];
hPrevFrameData->ampRes = hFrameData->ampResolutionCurrentFrame;
hPrevFrameData->prevSbrPitchInBins = hFrameData->sbrPitchInBins;
/* could be done in extractFrameInfo_pvc() but hPrevFrameData is not
* available there */
FDKmemcpy(&hPrevFrameData->prevFrameInfo, &hFrameData->frameInfo,
sizeof(FRAME_INFO));
} else {
/* rescale from lsb to nAnalysisBands in order to compensate scaling with
* hb_scale in this area, done by synthesisFiltering*/
int rescale;
int lsb;
int length;
/* Reset hb_scale if no highband is present, because hb_scale is considered
* in the QMF-synthesis */
hSbrDec->qmfDomainInCh->scaling.hb_scale = saveLbScale;
rescale = hSbrDec->qmfDomainInCh->scaling.hb_scale -
hSbrDec->qmfDomainInCh->scaling.ov_lb_scale;
lsb = hSbrDec->qmfDomainOutCh->fb.lsb;
length = (hSbrDec->qmfDomainInCh->fb.no_channels - lsb);
if ((rescale < 0) && (length > 0)) {
if (!(flags & SBRDEC_LOW_POWER)) {
for (i = 0; i < ov_len; i++) {
scaleValues(&pLowBandReal[i][lsb], length, rescale);
scaleValues(&pLowBandImag[i][lsb], length, rescale);
}
} else {
for (i = 0; i < ov_len; i++) {
scaleValues(&pLowBandReal[i][lsb], length, rescale);
}
}
}
}
if (!(flags & SBRDEC_USAC_HARMONICSBR)) {
int length = hSbrDec->qmfDomainInCh->fb.lsb;
if (flags & SBRDEC_SYNTAX_USAC) {
length = hSbrDec->qmfDomainInCh->fb.no_channels;
}
/* in case of legacy sbr saving of filter states here */
for (i = 0; i < LPC_ORDER + ov_len; i++) {
/*
Store the unmodified qmf Slots values (required for LPC filtering)
*/
if (!(flags & SBRDEC_LOW_POWER)) {
FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[i],
pLowBandReal[noCols - LPC_ORDER + i],
length * sizeof(FIXP_DBL));
FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[i],
pLowBandImag[noCols - LPC_ORDER + i],
length * sizeof(FIXP_DBL));
} else
FDKmemcpy(hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[i],
pLowBandReal[noCols - LPC_ORDER + i],
length * sizeof(FIXP_DBL));
}
}
/*
Synthesis subband filtering.
*/
if (!(flags & SBRDEC_PS_DECODED)) {
if (!(flags & SBRDEC_SKIP_QMF_SYN)) {
int outScalefactor = 0;
if (h_ps_d != NULL) {
h_ps_d->procFrameBased = 1; /* we here do frame based processing */
}
sbrDecoder_drcApply(&hSbrDec->sbrDrcChannel, pLowBandReal,
(flags & SBRDEC_LOW_POWER) ? NULL : pLowBandImag,
hSbrDec->qmfDomainOutCh->fb.no_col, &outScalefactor);
qmfChangeOutScalefactor(&hSbrDec->qmfDomainOutCh->fb, outScalefactor);
{
HANDLE_FREQ_BAND_DATA hFreq = &hHeaderData->freqBandData;
int save_usb = hSbrDec->qmfDomainOutCh->fb.usb;
#if (QMF_MAX_SYNTHESIS_BANDS <= 64)
C_AALLOC_SCRATCH_START(qmfTemp, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#else
C_AALLOC_STACK_START(qmfTemp, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#endif
if (hSbrDec->qmfDomainOutCh->fb.usb < hFreq->ov_highSubband) {
/* we need to patch usb for this frame as overlap may contain higher
frequency range if headerchange occured; fb. usb is always limited
to maximum fb.no_channels; In case of wrongly decoded headers it
might be that ov_highSubband is higher than the number of synthesis
channels (fb.no_channels), which is forbidden, therefore we need to
limit ov_highSubband with fMin function to avoid not allowed usb in
synthesis filterbank. */
hSbrDec->qmfDomainOutCh->fb.usb =
fMin((UINT)hFreq->ov_highSubband,
(UINT)hSbrDec->qmfDomainOutCh->fb.no_channels);
}
{
qmfSynthesisFiltering(
&hSbrDec->qmfDomainOutCh->fb, pLowBandReal,
(flags & SBRDEC_LOW_POWER) ? NULL : pLowBandImag,
&hSbrDec->qmfDomainInCh->scaling,
hSbrDec->LppTrans.pSettings->overlap, timeOut, strideOut,
qmfTemp);
}
/* restore saved value */
hSbrDec->qmfDomainOutCh->fb.usb = save_usb;
hFreq->ov_highSubband = save_usb;
#if (QMF_MAX_SYNTHESIS_BANDS <= 64)
C_AALLOC_SCRATCH_END(qmfTemp, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#else
C_AALLOC_STACK_END(qmfTemp, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#endif
}
}
} else { /* (flags & SBRDEC_PS_DECODED) */
INT sdiff;
INT scaleFactorHighBand, scaleFactorLowBand_ov, scaleFactorLowBand_no_ov;
HANDLE_QMF_FILTER_BANK synQmf = &hSbrDec->qmfDomainOutCh->fb;
HANDLE_QMF_FILTER_BANK synQmfRight = &hSbrDecRight->qmfDomainOutCh->fb;
/* adapt scaling */
sdiff = hSbrDec->qmfDomainInCh->scaling.lb_scale -
reserve; /* Scaling difference */
scaleFactorHighBand = sdiff - hSbrDec->qmfDomainInCh->scaling.hb_scale;
scaleFactorLowBand_ov = sdiff - hSbrDec->qmfDomainInCh->scaling.ov_lb_scale;
scaleFactorLowBand_no_ov = sdiff - hSbrDec->qmfDomainInCh->scaling.lb_scale;
/* Scale of low band overlapping QMF data */
scaleFactorLowBand_ov =
fMin(DFRACT_BITS - 1, fMax(-(DFRACT_BITS - 1), scaleFactorLowBand_ov));
/* Scale of low band current QMF data */
scaleFactorLowBand_no_ov = fMin(
DFRACT_BITS - 1, fMax(-(DFRACT_BITS - 1), scaleFactorLowBand_no_ov));
/* Scale of current high band */
scaleFactorHighBand =
fMin(DFRACT_BITS - 1, fMax(-(DFRACT_BITS - 1), scaleFactorHighBand));
if (h_ps_d->procFrameBased == 1) /* If we have switched from frame to slot
based processing copy filter states */
{ /* procFrameBased will be unset later */
/* copy filter states from left to right */
/* was ((640)-(64))*sizeof(FIXP_QSS)
flexible amount of synthesis bands needed for QMF based resampling
*/
FDK_ASSERT(hSbrDec->qmfDomainInCh->pGlobalConf->nBandsSynthesis <=
QMF_MAX_SYNTHESIS_BANDS);
FDKmemcpy(synQmfRight->FilterStates, synQmf->FilterStates,
9 * hSbrDec->qmfDomainInCh->pGlobalConf->nBandsSynthesis *
sizeof(FIXP_QSS));
}
/* Feed delaylines when parametric stereo is switched on. */
PreparePsProcessing(h_ps_d, pLowBandReal, pLowBandImag,
scaleFactorLowBand_ov);
/* use the same synthese qmf values for left and right channel */
synQmfRight->no_col = synQmf->no_col;
synQmfRight->lsb = synQmf->lsb;
synQmfRight->usb = synQmf->usb;
int env = 0;
{
#if (QMF_MAX_SYNTHESIS_BANDS <= 64)
C_AALLOC_SCRATCH_START(pWorkBuffer, FIXP_DBL,
2 * QMF_MAX_SYNTHESIS_BANDS);
#else
C_AALLOC_STACK_START(pWorkBuffer, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#endif
int maxShift = 0;
if (hSbrDec->sbrDrcChannel.enable != 0) {
if (hSbrDec->sbrDrcChannel.prevFact_exp > maxShift) {
maxShift = hSbrDec->sbrDrcChannel.prevFact_exp;
}
if (hSbrDec->sbrDrcChannel.currFact_exp > maxShift) {
maxShift = hSbrDec->sbrDrcChannel.currFact_exp;
}
if (hSbrDec->sbrDrcChannel.nextFact_exp > maxShift) {
maxShift = hSbrDec->sbrDrcChannel.nextFact_exp;
}
}
/* copy DRC data to right channel (with PS both channels use the same DRC
* gains) */
FDKmemcpy(&hSbrDecRight->sbrDrcChannel, &hSbrDec->sbrDrcChannel,
sizeof(SBRDEC_DRC_CHANNEL));
for (i = 0; i < synQmf->no_col; i++) { /* ----- no_col loop ----- */
INT outScalefactorR, outScalefactorL;
/* qmf timeslot of right channel */
FIXP_DBL *rQmfReal = pWorkBuffer;
FIXP_DBL *rQmfImag = pWorkBuffer + synQmf->no_channels;
{
if (i ==
h_ps_d->bsData[h_ps_d->processSlot].mpeg.aEnvStartStop[env]) {
initSlotBasedRotation(h_ps_d, env,
hHeaderData->freqBandData.highSubband);
env++;
}
ApplyPsSlot(
h_ps_d, /* parametric stereo decoder handle */
(pLowBandReal + i), /* one timeslot of left/mono channel */
(pLowBandImag + i), /* one timeslot of left/mono channel */
rQmfReal, /* one timeslot or right channel */
rQmfImag, /* one timeslot or right channel */
scaleFactorLowBand_no_ov,
(i < hSbrDec->LppTrans.pSettings->overlap)
? scaleFactorLowBand_ov
: scaleFactorLowBand_no_ov,
scaleFactorHighBand, synQmf->lsb, synQmf->usb);
outScalefactorL = outScalefactorR = 1; /* psDiffScale! (MPEG-PS) */
}
sbrDecoder_drcApplySlot(/* right channel */
&hSbrDecRight->sbrDrcChannel, rQmfReal,
rQmfImag, i, synQmfRight->no_col, maxShift);
outScalefactorR += maxShift;
sbrDecoder_drcApplySlot(/* left channel */
&hSbrDec->sbrDrcChannel, *(pLowBandReal + i),
*(pLowBandImag + i), i, synQmf->no_col,
maxShift);
outScalefactorL += maxShift;
if (!(flags & SBRDEC_SKIP_QMF_SYN)) {
qmfSynthesisFilteringSlot(
synQmfRight, rQmfReal, /* QMF real buffer */
rQmfImag, /* QMF imag buffer */
outScalefactorL, outScalefactorL,
timeOutRight + (i * synQmf->no_channels * strideOut), strideOut,
pWorkBuffer);
qmfSynthesisFilteringSlot(
synQmf, *(pLowBandReal + i), /* QMF real buffer */
*(pLowBandImag + i), /* QMF imag buffer */
outScalefactorR, outScalefactorR,
timeOut + (i * synQmf->no_channels * strideOut), strideOut,
pWorkBuffer);
}
} /* no_col loop i */
#if (QMF_MAX_SYNTHESIS_BANDS <= 64)
C_AALLOC_SCRATCH_END(pWorkBuffer, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#else
C_AALLOC_STACK_END(pWorkBuffer, FIXP_DBL, 2 * QMF_MAX_SYNTHESIS_BANDS);
#endif
}
}
sbrDecoder_drcUpdateChannel(&hSbrDec->sbrDrcChannel);
/*
Update overlap buffer
Even bands above usb are copied to avoid outdated spectral data in case
the stop frequency raises.
*/
if (!(flags & SBRDEC_SKIP_QMF_SYN)) {
{
FDK_QmfDomain_SaveOverlap(hSbrDec->qmfDomainInCh, 0);
FDK_ASSERT(hSbrDec->qmfDomainInCh->scaling.ov_lb_scale == saveLbScale);
}
}
hSbrDec->savedStates = 0;
/* Save current frame status */
hPrevFrameData->frameErrorFlag = hHeaderData->frameErrorFlag;
hSbrDec->applySbrProc_old = applyProcessing;
} /* sbr_dec() */
/*!
\brief Creates sbr decoder structure
\return errorCode, 0 if successful
*/
SBR_ERROR
createSbrDec(SBR_CHANNEL *hSbrChannel,
HANDLE_SBR_HEADER_DATA hHeaderData, /*!< Static control data */
TRANSPOSER_SETTINGS *pSettings,
const int downsampleFac, /*!< Downsampling factor */
const UINT qmfFlags, /*!< flags -> 1: HQ/LP selector, 2: CLDFB */
const UINT flags, const int overlap,
int chan, /*!< Channel for which to assign buffers etc. */
int codecFrameSize)
{
SBR_ERROR err = SBRDEC_OK;
int timeSlots =
hHeaderData->numberTimeSlots; /* Number of SBR slots per frame */
int noCols =
timeSlots * hHeaderData->timeStep; /* Number of QMF slots per frame */
HANDLE_SBR_DEC hs = &(hSbrChannel->SbrDec);
#if (SBRDEC_MAX_HB_FADE_FRAMES > 0)
hs->highBandFadeCnt = SBRDEC_MAX_HB_FADE_FRAMES;
#endif
hs->scale_hbe = 15;
hs->scale_lb = 15;
hs->scale_ov = 15;
hs->prev_frame_lSbr = 0;
hs->prev_frame_hbeSbr = 0;
hs->codecFrameSize = codecFrameSize;
/*
create envelope calculator
*/
err = createSbrEnvelopeCalc(&hs->SbrCalculateEnvelope, hHeaderData, chan,
flags);
if (err != SBRDEC_OK) {
return err;
}
initSbrPrevFrameData(&hSbrChannel->prevFrameData, timeSlots);
/*
create transposer
*/
err = createLppTransposer(
&hs->LppTrans, pSettings, hHeaderData->freqBandData.lowSubband,
hHeaderData->freqBandData.v_k_master, hHeaderData->freqBandData.numMaster,
hHeaderData->freqBandData.highSubband, timeSlots, noCols,
hHeaderData->freqBandData.freqBandTableNoise,
hHeaderData->freqBandData.nNfb, hHeaderData->sbrProcSmplRate, chan,
overlap);
if (err != SBRDEC_OK) {
return err;
}
if (flags & SBRDEC_USAC_HARMONICSBR) {
int noChannels, bSbr41 = flags & SBRDEC_QUAD_RATE ? 1 : 0;
noChannels =
QMF_SYNTH_CHANNELS /
((bSbr41 + 1) * 2); /* 32 for (32:64 and 24:64) and 16 for 16:64 */
/* shared memory between hbeLightTimeDelayBuffer and hQmfHBESlotsReal if
* SBRDEC_HBE_ENABLE */
hSbrChannel->SbrDec.tmp_memory = (FIXP_DBL **)fdkCallocMatrix2D_aligned(
noCols, noChannels, sizeof(FIXP_DBL));
if (hSbrChannel->SbrDec.tmp_memory == NULL) {
return SBRDEC_MEM_ALLOC_FAILED;
}
hSbrChannel->SbrDec.hQmfHBESlotsReal = hSbrChannel->SbrDec.tmp_memory;
hSbrChannel->SbrDec.hQmfHBESlotsImag =
(FIXP_DBL **)fdkCallocMatrix2D_aligned(noCols, noChannels,
sizeof(FIXP_DBL));
if (hSbrChannel->SbrDec.hQmfHBESlotsImag == NULL) {
return SBRDEC_MEM_ALLOC_FAILED;
}
/* buffers containing unmodified qmf data; required when switching from
* legacy SBR to HBE */
/* buffer can be used as LPCFilterstates buffer because legacy SBR needs
* exactly these values for LPC filtering */
hSbrChannel->SbrDec.codecQMFBufferReal =
(FIXP_DBL **)fdkCallocMatrix2D_aligned(noCols, noChannels,
sizeof(FIXP_DBL));
if (hSbrChannel->SbrDec.codecQMFBufferReal == NULL) {
return SBRDEC_MEM_ALLOC_FAILED;
}
hSbrChannel->SbrDec.codecQMFBufferImag =
(FIXP_DBL **)fdkCallocMatrix2D_aligned(noCols, noChannels,
sizeof(FIXP_DBL));
if (hSbrChannel->SbrDec.codecQMFBufferImag == NULL) {
return SBRDEC_MEM_ALLOC_FAILED;
}
err = QmfTransposerCreate(&hs->hHBE, codecFrameSize, 0, bSbr41);
if (err != SBRDEC_OK) {
return err;
}
}
return err;
}
/*!
\brief Delete sbr decoder structure
\return errorCode, 0 if successful
*/
int deleteSbrDec(SBR_CHANNEL *hSbrChannel) {
HANDLE_SBR_DEC hs = &hSbrChannel->SbrDec;
deleteSbrEnvelopeCalc(&hs->SbrCalculateEnvelope);
if (hs->tmp_memory != NULL) {
FDK_FREE_MEMORY_2D_ALIGNED(hs->tmp_memory);
}
/* modify here */
FDK_FREE_MEMORY_2D_ALIGNED(hs->hQmfHBESlotsImag);
if (hs->hHBE != NULL) QmfTransposerClose(hs->hHBE);
if (hs->codecQMFBufferReal != NULL) {
FDK_FREE_MEMORY_2D_ALIGNED(hs->codecQMFBufferReal);
}
if (hs->codecQMFBufferImag != NULL) {
FDK_FREE_MEMORY_2D_ALIGNED(hs->codecQMFBufferImag);
}
return 0;
}
/*!
\brief resets sbr decoder structure
\return errorCode, 0 if successful
*/
SBR_ERROR
resetSbrDec(HANDLE_SBR_DEC hSbrDec, HANDLE_SBR_HEADER_DATA hHeaderData,
HANDLE_SBR_PREV_FRAME_DATA hPrevFrameData, const int downsampleFac,
const UINT flags, HANDLE_SBR_FRAME_DATA hFrameData) {
SBR_ERROR sbrError = SBRDEC_OK;
int i;
FIXP_DBL *pLowBandReal[128];
FIXP_DBL *pLowBandImag[128];
int useLP = flags & SBRDEC_LOW_POWER;
int old_lsb = hSbrDec->qmfDomainInCh->fb.lsb;
int old_usb = hSbrDec->qmfDomainInCh->fb.usb;
int new_lsb = hHeaderData->freqBandData.lowSubband;
/* int new_usb = hHeaderData->freqBandData.highSubband; */
int l, startBand, stopBand, startSlot, size;
FIXP_DBL **OverlapBufferReal = hSbrDec->qmfDomainInCh->hQmfSlotsReal;
FIXP_DBL **OverlapBufferImag = hSbrDec->qmfDomainInCh->hQmfSlotsImag;
/* in case the previous frame was not active in terms of SBR processing, the
full band from 0 to no_channels was rescaled and not overwritten. Thats why
the scaling factor lb_scale can be seen as assigned to all bands from 0 to
no_channels in the previous frame. The same states for the current frame if
the current frame is not active in terms of SBR processing
*/
int applySbrProc = (hHeaderData->syncState == SBR_ACTIVE ||
(hHeaderData->frameErrorFlag == 0 &&
hHeaderData->syncState == SBR_HEADER));
int applySbrProc_old = hSbrDec->applySbrProc_old;
if (!applySbrProc) {
new_lsb = (hSbrDec->qmfDomainInCh->fb).no_channels;
}
if (!applySbrProc_old) {
old_lsb = (hSbrDec->qmfDomainInCh->fb).no_channels;
old_usb = old_lsb;
}
resetSbrEnvelopeCalc(&hSbrDec->SbrCalculateEnvelope);
/* Change lsb and usb */
/* Synthesis */
FDK_ASSERT(hSbrDec->qmfDomainOutCh != NULL);
hSbrDec->qmfDomainOutCh->fb.lsb =
fixMin((INT)hSbrDec->qmfDomainOutCh->fb.no_channels,
(INT)hHeaderData->freqBandData.lowSubband);
hSbrDec->qmfDomainOutCh->fb.usb =
fixMin((INT)hSbrDec->qmfDomainOutCh->fb.no_channels,
(INT)hHeaderData->freqBandData.highSubband);
/* Analysis */
FDK_ASSERT(hSbrDec->qmfDomainInCh != NULL);
hSbrDec->qmfDomainInCh->fb.lsb = hSbrDec->qmfDomainOutCh->fb.lsb;
hSbrDec->qmfDomainInCh->fb.usb = hSbrDec->qmfDomainOutCh->fb.usb;
/*
The following initialization of spectral data in the overlap buffer
is required for dynamic x-over or a change of the start-freq for 2 reasons:
1. If the lowband gets _wider_, unadjusted data would remain
2. If the lowband becomes _smaller_, the highest bands of the old lowband
must be cleared because the whitening would be affected
*/
startBand = old_lsb;
stopBand = new_lsb;
startSlot = fMax(0, hHeaderData->timeStep * (hPrevFrameData->stopPos -
hHeaderData->numberTimeSlots));
size = fMax(0, stopBand - startBand);
/* in case of USAC we don't want to zero out the memory, as this can lead to
holes in the spectrum; fix shall only be applied for USAC not for MPEG-4
SBR, in this case setting zero remains */
if (!(flags & SBRDEC_SYNTAX_USAC)) {
/* keep already adjusted data in the x-over-area */
if (!useLP) {
for (l = startSlot; l < hSbrDec->LppTrans.pSettings->overlap; l++) {
FDKmemclear(&OverlapBufferReal[l][startBand], size * sizeof(FIXP_DBL));
FDKmemclear(&OverlapBufferImag[l][startBand], size * sizeof(FIXP_DBL));
}
} else {
for (l = startSlot; l < hSbrDec->LppTrans.pSettings->overlap; l++) {
FDKmemclear(&OverlapBufferReal[l][startBand], size * sizeof(FIXP_DBL));
}
}
/*
reset LPC filter states
*/
startBand = fixMin(old_lsb, new_lsb);
stopBand = fixMax(old_lsb, new_lsb);
size = fixMax(0, stopBand - startBand);
FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[0][startBand],
size * sizeof(FIXP_DBL));
FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[1][startBand],
size * sizeof(FIXP_DBL));
if (!useLP) {
FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[0][startBand],
size * sizeof(FIXP_DBL));
FDKmemclear(&hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[1][startBand],
size * sizeof(FIXP_DBL));
}
}
if (startSlot != 0) {
int source_exp, target_exp, delta_exp, target_lsb, target_usb, reserve;
FIXP_DBL maxVal;
/*
Rescale already processed spectral data between old and new x-over
frequency. This must be done because of the separate scalefactors for
lowband and highband.
*/
/* We have four relevant transitions to cover:
1. old_usb is lower than new_lsb; old SBR area is completely below new SBR
area.
-> entire old area was highband and belongs to lowband now
and has to be rescaled.
2. old_lsb is higher than new_usb; new SBR area is completely below old SBR
area.
-> old area between new_lsb and old_lsb was lowband and belongs to
highband now and has to be rescaled to match new highband scale.
3. old_lsb is lower and old_usb is higher than new_lsb; old and new SBR
areas overlap.
-> old area between old_lsb and new_lsb was highband and belongs to
lowband now and has to be rescaled to match new lowband scale.
4. new_lsb is lower and new_usb_is higher than old_lsb; old and new SBR
areas overlap.
-> old area between new_lsb and old_usb was lowband and belongs to
highband now and has to be rescaled to match new highband scale.
*/
if (new_lsb > old_lsb) {
/* case 1 and 3 */
source_exp = SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_hb_scale);
target_exp = SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_lb_scale);
startBand = old_lsb;
if (new_lsb >= old_usb) {
/* case 1 */
stopBand = old_usb;
} else {
/* case 3 */
stopBand = new_lsb;
}
target_lsb = 0;
target_usb = old_lsb;
} else {
/* case 2 and 4 */
source_exp = SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_lb_scale);
target_exp = SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_hb_scale);
startBand = new_lsb;
stopBand = old_lsb;
target_lsb = old_lsb;
target_usb = old_usb;
}
maxVal =
maxSubbandSample(OverlapBufferReal, (useLP) ? NULL : OverlapBufferImag,
startBand, stopBand, 0, startSlot);
reserve = ((LONG)maxVal != 0 ? CntLeadingZeros(maxVal) - 1 : 0);
reserve = fixMin(
reserve,
DFRACT_BITS - 1 -
EXP2SCALE(
source_exp)); /* what is this line for, why do we need it? */
/* process only if x-over-area is not dominant after rescale;
otherwise I'm not sure if all buffers are scaled correctly;
*/
if (target_exp - (source_exp - reserve) >= 0) {
rescaleSubbandSamples(OverlapBufferReal,
(useLP) ? NULL : OverlapBufferImag, startBand,
stopBand, 0, startSlot, reserve);
source_exp -= reserve;
}
delta_exp = target_exp - source_exp;
if (delta_exp < 0) { /* x-over-area is dominant */
startBand = target_lsb;
stopBand = target_usb;
delta_exp = -delta_exp;
if (new_lsb > old_lsb) {
/* The lowband has to be rescaled */
hSbrDec->qmfDomainInCh->scaling.ov_lb_scale = EXP2SCALE(source_exp);
} else {
/* The highband has to be rescaled */
hSbrDec->qmfDomainInCh->scaling.ov_hb_scale = EXP2SCALE(source_exp);
}
}
FDK_ASSERT(startBand <= stopBand);
if (!useLP) {
for (l = 0; l < startSlot; l++) {
scaleValues(OverlapBufferReal[l] + startBand, stopBand - startBand,
-delta_exp);
scaleValues(OverlapBufferImag[l] + startBand, stopBand - startBand,
-delta_exp);
}
} else
for (l = 0; l < startSlot; l++) {
scaleValues(OverlapBufferReal[l] + startBand, stopBand - startBand,
-delta_exp);
}
} /* startSlot != 0 */
/*
Initialize transposer and limiter
*/
sbrError = resetLppTransposer(
&hSbrDec->LppTrans, hHeaderData->freqBandData.lowSubband,
hHeaderData->freqBandData.v_k_master, hHeaderData->freqBandData.numMaster,
hHeaderData->freqBandData.freqBandTableNoise,
hHeaderData->freqBandData.nNfb, hHeaderData->freqBandData.highSubband,
hHeaderData->sbrProcSmplRate);
if (sbrError != SBRDEC_OK) return sbrError;
hSbrDec->savedStates = 0;
if ((flags & SBRDEC_USAC_HARMONICSBR) && applySbrProc) {
sbrError = QmfTransposerReInit(hSbrDec->hHBE,
hHeaderData->freqBandData.freqBandTable,
hHeaderData->freqBandData.nSfb);
if (sbrError != SBRDEC_OK) return sbrError;
/* copy saved states from previous frame to legacy SBR lpc filterstate
* buffer */
for (i = 0; i < LPC_ORDER + hSbrDec->LppTrans.pSettings->overlap; i++) {
FDKmemcpy(
hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[i],
hSbrDec->codecQMFBufferReal[hSbrDec->hHBE->noCols - LPC_ORDER -
hSbrDec->LppTrans.pSettings->overlap + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
FDKmemcpy(
hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[i],
hSbrDec->codecQMFBufferImag[hSbrDec->hHBE->noCols - LPC_ORDER -
hSbrDec->LppTrans.pSettings->overlap + i],
hSbrDec->hHBE->noChannels * sizeof(FIXP_DBL));
}
hSbrDec->savedStates = 1;
{
/* map QMF buffer to pointer array (Overlap + Frame)*/
for (i = 0; i < hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER; i++) {
pLowBandReal[i] = hSbrDec->LppTrans.lpcFilterStatesRealHBE[i];
pLowBandImag[i] = hSbrDec->LppTrans.lpcFilterStatesImagHBE[i];
}
/* map QMF buffer to pointer array (Overlap + Frame)*/
for (i = 0; i < hSbrDec->hHBE->noCols; i++) {
pLowBandReal[i + hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->codecQMFBufferReal[i];
pLowBandImag[i + hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->codecQMFBufferImag[i];
}
if (flags & SBRDEC_QUAD_RATE) {
if (hFrameData->sbrPatchingMode == 0) {
int *xOverQmf = GetxOverBandQmfTransposer(hSbrDec->hHBE);
/* in case of harmonic SBR and no HBE_LP map additional buffer for
one more frame to pointer arry */
for (i = 0; i < hSbrDec->hHBE->noCols / 2; i++) {
pLowBandReal[i + hSbrDec->hHBE->noCols +
hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->hQmfHBESlotsReal[i];
pLowBandImag[i + hSbrDec->hHBE->noCols +
hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->hQmfHBESlotsImag[i];
}
QmfTransposerApply(
hSbrDec->hHBE,
pLowBandReal + hSbrDec->LppTrans.pSettings->overlap +
hSbrDec->hHBE->noCols / 2 + LPC_ORDER,
pLowBandImag + hSbrDec->LppTrans.pSettings->overlap +
hSbrDec->hHBE->noCols / 2 + LPC_ORDER,
hSbrDec->hHBE->noCols, pLowBandReal, pLowBandImag,
hSbrDec->LppTrans.lpcFilterStatesRealHBE,
hSbrDec->LppTrans.lpcFilterStatesImagHBE,
hPrevFrameData->prevSbrPitchInBins, hSbrDec->scale_lb,
hSbrDec->scale_hbe, &hSbrDec->qmfDomainInCh->scaling.hb_scale,
hHeaderData->timeStep, hFrameData->frameInfo.borders[0],
hSbrDec->LppTrans.pSettings->overlap, KEEP_STATES_SYNCED_OUTDIFF);
copyHarmonicSpectrum(
xOverQmf, pLowBandReal, pLowBandImag, hSbrDec->hHBE->noCols,
hSbrDec->LppTrans.pSettings->overlap, KEEP_STATES_SYNCED_OUTDIFF);
}
} else {
/* in case of harmonic SBR and no HBE_LP map additional buffer for
one more frame to pointer arry */
for (i = 0; i < hSbrDec->hHBE->noCols; i++) {
pLowBandReal[i + hSbrDec->hHBE->noCols +
hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->hQmfHBESlotsReal[i];
pLowBandImag[i + hSbrDec->hHBE->noCols +
hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER] =
hSbrDec->hQmfHBESlotsImag[i];
}
if (hFrameData->sbrPatchingMode == 0) {
QmfTransposerApply(
hSbrDec->hHBE,
pLowBandReal + hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER,
pLowBandImag + hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER,
hSbrDec->hHBE->noCols, pLowBandReal, pLowBandImag,
hSbrDec->LppTrans.lpcFilterStatesRealHBE,
hSbrDec->LppTrans.lpcFilterStatesImagHBE,
0 /* not required for keeping states updated in this frame*/,
hSbrDec->scale_lb, hSbrDec->scale_lb,
&hSbrDec->qmfDomainInCh->scaling.hb_scale, hHeaderData->timeStep,
hFrameData->frameInfo.borders[0],
hSbrDec->LppTrans.pSettings->overlap, KEEP_STATES_SYNCED_NOOUT);
}
QmfTransposerApply(
hSbrDec->hHBE,
pLowBandReal + hSbrDec->LppTrans.pSettings->overlap +
hSbrDec->hHBE->noCols + LPC_ORDER,
pLowBandImag + hSbrDec->LppTrans.pSettings->overlap +
hSbrDec->hHBE->noCols + LPC_ORDER,
hSbrDec->hHBE->noCols, pLowBandReal, pLowBandImag,
hSbrDec->LppTrans.lpcFilterStatesRealHBE,
hSbrDec->LppTrans.lpcFilterStatesImagHBE,
hPrevFrameData->prevSbrPitchInBins, hSbrDec->scale_lb,
hSbrDec->scale_hbe, &hSbrDec->qmfDomainInCh->scaling.hb_scale,
hHeaderData->timeStep, hFrameData->frameInfo.borders[0],
hSbrDec->LppTrans.pSettings->overlap, KEEP_STATES_SYNCED_OUTDIFF);
}
if (hFrameData->sbrPatchingMode == 0) {
for (i = startSlot; i < hSbrDec->LppTrans.pSettings->overlap; i++) {
/*
Store the unmodified qmf Slots values for upper part of spectrum
(required for LPC filtering) required if next frame is a HBE frame
*/
FDKmemcpy(hSbrDec->qmfDomainInCh->hQmfSlotsReal[i],
hSbrDec->LppTrans.lpcFilterStatesRealHBE[i + LPC_ORDER],
(64) * sizeof(FIXP_DBL));
FDKmemcpy(hSbrDec->qmfDomainInCh->hQmfSlotsImag[i],
hSbrDec->LppTrans.lpcFilterStatesImagHBE[i + LPC_ORDER],
(64) * sizeof(FIXP_DBL));
}
for (i = startSlot; i < hSbrDec->LppTrans.pSettings->overlap; i++) {
/*
Store the unmodified qmf Slots values for upper part of spectrum
(required for LPC filtering) required if next frame is a HBE frame
*/
FDKmemcpy(
hSbrDec->qmfDomainInCh->hQmfSlotsReal[i],
hSbrDec->codecQMFBufferReal[hSbrDec->hHBE->noCols -
hSbrDec->LppTrans.pSettings->overlap +
i],
new_lsb * sizeof(FIXP_DBL));
FDKmemcpy(
hSbrDec->qmfDomainInCh->hQmfSlotsImag[i],
hSbrDec->codecQMFBufferImag[hSbrDec->hHBE->noCols -
hSbrDec->LppTrans.pSettings->overlap +
i],
new_lsb * sizeof(FIXP_DBL));
}
}
}
}
{
int adapt_lb = 0, diff = 0,
new_scale = hSbrDec->qmfDomainInCh->scaling.ov_lb_scale;
if ((hSbrDec->qmfDomainInCh->scaling.ov_lb_scale !=
hSbrDec->qmfDomainInCh->scaling.lb_scale) &&
startSlot != 0) {
/* we need to adapt spectrum to have equal scale factor, always larger
* than zero */
diff = SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.ov_lb_scale) -
SCALE2EXP(hSbrDec->qmfDomainInCh->scaling.lb_scale);
if (diff > 0) {
adapt_lb = 1;
diff = -diff;
new_scale = hSbrDec->qmfDomainInCh->scaling.ov_lb_scale;
}
stopBand = new_lsb;
}
if (hFrameData->sbrPatchingMode == 1) {
/* scale states from LegSBR filterstates buffer */
for (i = 0; i < hSbrDec->LppTrans.pSettings->overlap + LPC_ORDER; i++) {
scaleValues(hSbrDec->LppTrans.lpcFilterStatesRealLegSBR[i], new_lsb,
diff);
if (!useLP) {
scaleValues(hSbrDec->LppTrans.lpcFilterStatesImagLegSBR[i], new_lsb,
diff);
}
}
if (flags & SBRDEC_SYNTAX_USAC) {
/* get missing states between old and new x_over from LegSBR
* filterstates buffer */
/* in case of legacy SBR we leave these values zeroed out */
for (i = startSlot; i < hSbrDec->LppTrans.pSettings->overlap; i++) {
FDKmemcpy(&OverlapBufferReal[i][old_lsb],
&hSbrDec->LppTrans
.lpcFilterStatesRealLegSBR[LPC_ORDER + i][old_lsb],
fMax(new_lsb - old_lsb, 0) * sizeof(FIXP_DBL));
if (!useLP) {
FDKmemcpy(&OverlapBufferImag[i][old_lsb],
&hSbrDec->LppTrans
.lpcFilterStatesImagLegSBR[LPC_ORDER + i][old_lsb],
fMax(new_lsb - old_lsb, 0) * sizeof(FIXP_DBL));
}
}
}
if (new_lsb > old_lsb) {
stopBand = old_lsb;
}
}
if ((adapt_lb == 1) && (stopBand > startBand)) {
for (l = startSlot; l < hSbrDec->LppTrans.pSettings->overlap; l++) {
scaleValues(OverlapBufferReal[l] + startBand, stopBand - startBand,
diff);
if (!useLP) {
scaleValues(OverlapBufferImag[l] + startBand, stopBand - startBand,
diff);
}
}
}
hSbrDec->qmfDomainInCh->scaling.ov_lb_scale = new_scale;
}
sbrError = ResetLimiterBands(hHeaderData->freqBandData.limiterBandTable,
&hHeaderData->freqBandData.noLimiterBands,
hHeaderData->freqBandData.freqBandTable[0],
hHeaderData->freqBandData.nSfb[0],
hSbrDec->LppTrans.pSettings->patchParam,
hSbrDec->LppTrans.pSettings->noOfPatches,
hHeaderData->bs_data.limiterBands,
hFrameData->sbrPatchingMode,
GetxOverBandQmfTransposer(hSbrDec->hHBE),
Get41SbrQmfTransposer(hSbrDec->hHBE));
hSbrDec->SbrCalculateEnvelope.sbrPatchingMode = hFrameData->sbrPatchingMode;
return sbrError;
}