ref: ea8a00278f5440673a1c19aa1923befc550ddb63
dir: /codec/decoder/core/src/au_parser.cpp/
/*!
* \copy
* Copyright (c) 2009-2013, Cisco Systems
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 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 OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*
* \file au_parser.c
*
* \brief Interfaces introduced in Access Unit level based parser
*
* \date 03/10/2009 Created
*
*************************************************************************************
*/
#include "codec_def.h"
#include "au_parser.h"
#include "decoder.h"
#include "error_code.h"
#include "memmgr_nal_unit.h"
#include "decoder_core.h"
#include "decoder_core.h"
namespace WelsDec {
/*!
*************************************************************************************
* \brief Start Code Prefix (0x 00 00 00 01) detection
*
* \param pBuf bitstream payload buffer
* \param pOffset offset between NAL rbsp and original bitsteam that
* start code prefix is seperated from.
* \param iBufSize count size of buffer
*
* \return RBSP buffer of start code prefix exclusive
*
* \note N/A
*************************************************************************************
*/
uint8_t* DetectStartCodePrefix (const uint8_t* kpBuf, int32_t* pOffset, int32_t iBufSize) {
uint8_t* pBits = (uint8_t*)kpBuf;
do {
int32_t iIdx = 0;
while ((iIdx < iBufSize) && (! (*pBits))) {
++ pBits;
++ iIdx;
}
if (iIdx >= iBufSize) break;
++ iIdx;
++ pBits;
if ((iIdx >= 3) && ((* (pBits - 1)) == 0x1)) {
*pOffset = ((uintptr_t)pBits) - ((uintptr_t)kpBuf);
return pBits;
}
iBufSize -= iIdx;
} while (1);
return NULL;
}
/*!
*************************************************************************************
* \brief to parse nal unit
*
* \param pCtx decoder context
* \param pNalUnitHeader parsed result of NAL Unit Header to output
* \param pSrcRbsp bitstream buffer to input
* \param iSrcRbspLen length size of bitstream buffer payload
* \param pSrcNal
* \param iSrcNalLen
* \param pConsumedBytes consumed bytes during parsing
*
* \return decoded bytes payload, might be (pSrcRbsp+1) if no escapes
*
* \note N/A
*************************************************************************************
*/
uint8_t* ParseNalHeader (PWelsDecoderContext pCtx, SNalUnitHeader* pNalUnitHeader, uint8_t* pSrcRbsp,
int32_t iSrcRbspLen, uint8_t* pSrcNal, int32_t iSrcNalLen, int32_t* pConsumedBytes) {
PNalUnit pCurNal = NULL;
uint8_t* pNal = pSrcRbsp;
int32_t iNalSize = iSrcRbspLen;
PBitStringAux pBs = NULL;
bool_t bExtensionFlag = false;
int32_t iErr = ERR_NONE;
int32_t iBitSize = 0;
pNalUnitHeader->eNalUnitType = NAL_UNIT_UNSPEC_0;//SHOULD init it. because pCtx->sCurNalHead is common variable.
//remove the consecutive ZERO at the end of current NAL in the reverse order.--2011.6.1
{
int32_t iIndex = iSrcRbspLen - 1;
uint8_t uiBsZero = 0;
while (iIndex >= 0) {
uiBsZero = pSrcRbsp[iIndex];
if (0 == uiBsZero) {
--iNalSize;
--iIndex;
} else {
break;
}
}
}
pNalUnitHeader->uiForbiddenZeroBit = (uint8_t) (pNal[0] >> 7); // uiForbiddenZeroBit
if (pNalUnitHeader->uiForbiddenZeroBit) { //2010.4.14
return NULL; //uiForbiddenZeroBit should always equal to 0
}
pNalUnitHeader->uiNalRefIdc = (uint8_t) (pNal[0] >> 5); // uiNalRefIdc
pNalUnitHeader->eNalUnitType = (ENalUnitType) (pNal[0] & 0x1f); // eNalUnitType
++pNal;
--iNalSize;
++ (*pConsumedBytes);
#ifdef DEBUG_PARSE_INFO
WelsLog (pCtx, WELS_LOG_INFO, "nal type: %d \n", pNalUnitHeader->eNalUnitType);
#endif
if (! (IS_SEI_NAL (pNalUnitHeader->eNalUnitType) || IS_SPS_NAL (pNalUnitHeader->eNalUnitType)
|| pCtx->bSpsExistAheadFlag)) {
WelsLog (pCtx, WELS_LOG_WARNING,
"parse_nal(), no exist Sequence Parameter Sets ahead of sequence when try to decode NAL(type:%d).\n",
pNalUnitHeader->eNalUnitType);
pCtx->iErrorCode = dsNoParamSets;
return NULL;
}
if (! (IS_SEI_NAL (pNalUnitHeader->eNalUnitType) || IS_PARAM_SETS_NALS (pNalUnitHeader->eNalUnitType)
|| pCtx->bPpsExistAheadFlag)) {
WelsLog (pCtx, WELS_LOG_WARNING,
"parse_nal(), no exist Picture Parameter Sets ahead of sequence when try to decode NAL(type:%d).\n",
pNalUnitHeader->eNalUnitType);
pCtx->iErrorCode = dsNoParamSets;
return NULL;
}
if ((IS_VCL_NAL_AVC_BASE (pNalUnitHeader->eNalUnitType) && ! (pCtx->bSpsExistAheadFlag || pCtx->bPpsExistAheadFlag)) ||
(IS_NEW_INTRODUCED_NAL (pNalUnitHeader->eNalUnitType) && ! (pCtx->bSpsExistAheadFlag || pCtx->bSubspsExistAheadFlag
|| pCtx->bPpsExistAheadFlag))) {
WelsLog (pCtx, WELS_LOG_WARNING,
"ParseNalHeader(), no exist Parameter Sets ahead of sequence when try to decode slice(type:%d).\n",
pNalUnitHeader->eNalUnitType);
pCtx->iErrorCode |= dsNoParamSets;
return NULL;
}
switch (pNalUnitHeader->eNalUnitType) {
case NAL_UNIT_SEI:
if (pCtx->pAccessUnitList->uiAvailUnitsNum > 0) {
pCtx->pAccessUnitList->uiEndPos = pCtx->pAccessUnitList->uiAvailUnitsNum - 1;
pCtx->bAuReadyFlag = true;
}
break;
case NAL_UNIT_SPS:
if (pCtx->pAccessUnitList->uiAvailUnitsNum > 0) {
pCtx->pAccessUnitList->uiEndPos = pCtx->pAccessUnitList->uiAvailUnitsNum - 1;
pCtx->bAuReadyFlag = true;
}
break;
case NAL_UNIT_PREFIX:
pCurNal = &pCtx->sPrefixNal;
if (iNalSize < NAL_UNIT_HEADER_EXT_SIZE) {
pCtx->iErrorCode |= dsBitstreamError;
PAccessUnit pCurAu = pCtx->pAccessUnitList;
uint32_t uiAvailNalNum = pCurAu->uiAvailUnitsNum;
ForceClearCurrentNal (pCurAu);
if (uiAvailNalNum > 1) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
return NULL;
}
DecodeNalHeaderExt (pCurNal, pNal);
if ((pCurNal->sNalHeaderExt.uiQualityId != 0) || (pCurNal->sNalHeaderExt.bUseRefBasePicFlag != 0)) {
WelsLog (pCtx, WELS_LOG_WARNING,
"ParseNalHeader() in Prefix Nal Unit:uiQualityId (%d) != 0, bUseRefBasePicFlag (%d) != 0, not supported!\n",
pCurNal->sNalHeaderExt.uiQualityId, pCurNal->sNalHeaderExt.bUseRefBasePicFlag);
PAccessUnit pCurAu = pCtx->pAccessUnitList;
uint32_t uiAvailNalNum = pCurAu->uiAvailUnitsNum;
ForceClearCurrentNal (pCurAu);
if (uiAvailNalNum > 1) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
pCtx->iErrorCode |= dsInvalidArgument;
return NULL;
}
pNal += NAL_UNIT_HEADER_EXT_SIZE;
iNalSize -= NAL_UNIT_HEADER_EXT_SIZE;
*pConsumedBytes += NAL_UNIT_HEADER_EXT_SIZE;
pCurNal->sNalHeaderExt.sNalUnitHeader.uiForbiddenZeroBit = pNalUnitHeader->uiForbiddenZeroBit;
pCurNal->sNalHeaderExt.sNalUnitHeader.uiNalRefIdc = pNalUnitHeader->uiNalRefIdc;
pCurNal->sNalHeaderExt.sNalUnitHeader.eNalUnitType = pNalUnitHeader->eNalUnitType;
pBs = &pCtx->sBs;
iBitSize = (iNalSize << 3) - BsGetTrailingBits (pNal + iNalSize - 1); // convert into bit
InitBits (pBs, pNal, iBitSize);
ParsePrefixNalUnit (pCtx, pBs);
break;
case NAL_UNIT_CODED_SLICE_EXT:
bExtensionFlag = true;
case NAL_UNIT_CODED_SLICE:
case NAL_UNIT_CODED_SLICE_IDR: {
PAccessUnit pCurAu = NULL;
uint32_t uiAvailNalNum;
pCurNal = MemGetNextNal (&pCtx->pAccessUnitList);
if (NULL == pCurNal) {
WelsLog (pCtx, WELS_LOG_WARNING, "MemGetNextNal() fail due out of memory.\n");
pCtx->iErrorCode |= dsOutOfMemory;
return NULL;
}
pCurNal->sNalHeaderExt.sNalUnitHeader.uiForbiddenZeroBit = pNalUnitHeader->uiForbiddenZeroBit;
pCurNal->sNalHeaderExt.sNalUnitHeader.uiNalRefIdc = pNalUnitHeader->uiNalRefIdc;
pCurNal->sNalHeaderExt.sNalUnitHeader.eNalUnitType = pNalUnitHeader->eNalUnitType;
pCurAu = pCtx->pAccessUnitList;
uiAvailNalNum = pCurAu->uiAvailUnitsNum;
if (pNalUnitHeader->eNalUnitType == NAL_UNIT_CODED_SLICE_EXT) {
if (iNalSize < NAL_UNIT_HEADER_EXT_SIZE) {
pCtx->iErrorCode |= dsBitstreamError;
ForceClearCurrentNal (pCurAu);
if (uiAvailNalNum > 1) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
return NULL;
}
DecodeNalHeaderExt (pCurNal, pNal);
if (pCurNal->sNalHeaderExt.uiQualityId != 0 ||
pCurNal->sNalHeaderExt.bUseRefBasePicFlag) {
if (pCurNal->sNalHeaderExt.uiQualityId != 0)
WelsLog (pCtx, WELS_LOG_WARNING, "ParseNalHeader():uiQualityId (%d) != 0, MGS not supported!\n",
pCurNal->sNalHeaderExt.uiQualityId);
if (pCurNal->sNalHeaderExt.bUseRefBasePicFlag != 0)
WelsLog (pCtx, WELS_LOG_WARNING, "ParseNalHeader():bUseRefBasePicFlag (%d) != 0, MGS not supported!\n",
pCurNal->sNalHeaderExt.bUseRefBasePicFlag);
pCtx->iErrorCode |= dsInvalidArgument;
ForceClearCurrentNal (pCurAu);
if (uiAvailNalNum > 1) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
return NULL;
}
pNal += NAL_UNIT_HEADER_EXT_SIZE;
iNalSize -= NAL_UNIT_HEADER_EXT_SIZE;
*pConsumedBytes += NAL_UNIT_HEADER_EXT_SIZE;
} else {
if (NAL_UNIT_PREFIX == pCtx->sPrefixNal.sNalHeaderExt.sNalUnitHeader.eNalUnitType) {
PrefetchNalHeaderExtSyntax (pCtx, pCurNal, &pCtx->sPrefixNal);
}
pCurNal->sNalHeaderExt.bIdrFlag = (NAL_UNIT_CODED_SLICE_IDR == pNalUnitHeader->eNalUnitType) ? true :
false; //SHOULD update this flag for AVC if no prefix NAL
pCurNal->sNalHeaderExt.iNoInterLayerPredFlag = 1;
}
pBs = &pCurAu->pNalUnitsList[uiAvailNalNum - 1]->sNalData.sVclNal.sSliceBitsRead;
iBitSize = (iNalSize << 3) - BsGetTrailingBits (pNal + iNalSize - 1); // convert into bit
InitBits (pBs, pNal, iBitSize);
iErr = ParseSliceHeaderSyntaxs (pCtx, pBs, bExtensionFlag);
if (iErr != ERR_NONE) {
//if current NAL occur error when parsing, should clean it from pNalUnitsList
//otherwise, when Next good NAL decoding, this corrupt NAL is considered as normal NAL and lead to decoder crash
ForceClearCurrentNal (pCurAu);
if (uiAvailNalNum > 1) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
if (dsNoParamSets & pCtx->iErrorCode) {
if (uiAvailNalNum <= 1) { //no any data to decode and SPS/PPS ID mismatch, SHOULD request IDR
#ifdef LONG_TERM_REF
pCtx->bParamSetsLostFlag = true;
#else
pCtx->bReferenceLostAtT0Flag = true;
#endif
ResetParameterSetsState (pCtx);
}
return NULL;
} else {
return NULL;
}
#else
return NULL;
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
}
if ((uiAvailNalNum > 1) &&
CheckAccessUnitBoundary (pCurAu->pNalUnitsList[uiAvailNalNum - 1], pCurAu->pNalUnitsList[uiAvailNalNum - 2],
pCurAu->pNalUnitsList[uiAvailNalNum - 1]->sNalData.sVclNal.sSliceHeaderExt.sSliceHeader.pSps)) {
pCurAu->uiEndPos = uiAvailNalNum - 2;
pCtx->bAuReadyFlag = true;
}
}
break;
default:
break;
}
return pNal;
}
bool_t CheckAccessUnitBoundaryExt (PNalUnitHeaderExt pLastNalHdrExt, PNalUnitHeaderExt pCurNalHeaderExt,
PSliceHeader pLastSliceHeader, PSliceHeader pCurSliceHeader) {
const PSps kpSps = pCurSliceHeader->pSps;
//Sub-clause 7.1.4.1.1 temporal_id
if (pLastNalHdrExt->uiTemporalId != pCurNalHeaderExt->uiTemporalId) {
return TRUE;
}
// Subclause 7.4.1.2.5
if (pLastSliceHeader->iRedundantPicCnt < pCurSliceHeader->iRedundantPicCnt)
return FALSE;
else if (pLastSliceHeader->iRedundantPicCnt > pCurSliceHeader->iRedundantPicCnt)
return TRUE;
// Subclause G7.4.1.2.4
if (pLastNalHdrExt->uiDependencyId < pCurNalHeaderExt->uiDependencyId)
return FALSE;
else if (pLastNalHdrExt->uiDependencyId > pCurNalHeaderExt->uiDependencyId)
return TRUE;
if (pLastNalHdrExt->uiQualityId < pCurNalHeaderExt->uiQualityId)
return FALSE;
else if (pLastNalHdrExt->uiQualityId > pCurNalHeaderExt->uiQualityId)
return TRUE;
// Subclause 7.4.1.2.4
if (pLastSliceHeader->iFrameNum != pCurSliceHeader->iFrameNum)
return TRUE;
if (pLastSliceHeader->iPpsId != pCurSliceHeader->iPpsId)
return TRUE;
if (pLastSliceHeader->bFieldPicFlag != pCurSliceHeader->bFieldPicFlag)
return TRUE;
if (pLastSliceHeader->bBottomFiledFlag != pCurSliceHeader->bBottomFiledFlag)
return TRUE;
if ((pLastNalHdrExt->sNalUnitHeader.uiNalRefIdc != NRI_PRI_LOWEST) != (pCurNalHeaderExt->sNalUnitHeader.uiNalRefIdc !=
NRI_PRI_LOWEST))
return TRUE;
if (pLastNalHdrExt->bIdrFlag != pCurNalHeaderExt->bIdrFlag)
return TRUE;
if (pCurNalHeaderExt->bIdrFlag) {
if (pLastSliceHeader->uiIdrPicId != pCurSliceHeader->uiIdrPicId)
return TRUE;
}
if (kpSps->uiPocType == 0) {
if (pLastSliceHeader->iPicOrderCntLsb != pCurSliceHeader->iPicOrderCntLsb)
return TRUE;
if (pLastSliceHeader->iDeltaPicOrderCntBottom != pCurSliceHeader->iDeltaPicOrderCntBottom)
return TRUE;
} else if (kpSps->uiPocType == 1) {
if (pLastSliceHeader->iDeltaPicOrderCnt[0] != pCurSliceHeader->iDeltaPicOrderCnt[0])
return TRUE;
if (pLastSliceHeader->iDeltaPicOrderCnt[1] != pCurSliceHeader->iDeltaPicOrderCnt[1])
return TRUE;
}
return FALSE;
}
bool_t CheckAccessUnitBoundary (const PNalUnit kpCurNal, const PNalUnit kpLastNal, const PSps kpSps) {
const PNalUnitHeaderExt kpLastNalHeaderExt = &kpLastNal->sNalHeaderExt;
const PNalUnitHeaderExt kpCurNalHeaderExt = &kpCurNal->sNalHeaderExt;
const SSliceHeader* kpLastSliceHeader = &kpLastNal->sNalData.sVclNal.sSliceHeaderExt.sSliceHeader;
const SSliceHeader* kpCurSliceHeader = &kpCurNal->sNalData.sVclNal.sSliceHeaderExt.sSliceHeader;
//Sub-clause 7.1.4.1.1 temporal_id
if (kpLastNalHeaderExt->uiTemporalId != kpCurNalHeaderExt->uiTemporalId) {
return TRUE;
}
// Subclause 7.4.1.2.5
if (kpLastSliceHeader->iRedundantPicCnt < kpCurSliceHeader->iRedundantPicCnt)
return FALSE;
else if (kpLastSliceHeader->iRedundantPicCnt > kpCurSliceHeader->iRedundantPicCnt)
return TRUE;
// Subclause G7.4.1.2.4
if (kpLastNalHeaderExt->uiDependencyId < kpCurNalHeaderExt->uiDependencyId)
return FALSE;
else if (kpLastNalHeaderExt->uiDependencyId > kpCurNalHeaderExt->uiDependencyId)
return TRUE;
if (kpLastNalHeaderExt->uiQualityId < kpCurNalHeaderExt->uiQualityId)
return FALSE;
else if (kpLastNalHeaderExt->uiQualityId > kpCurNalHeaderExt->uiQualityId)
return TRUE;
// Subclause 7.4.1.2.4
if (kpLastSliceHeader->iFrameNum != kpCurSliceHeader->iFrameNum)
return TRUE;
if (kpLastSliceHeader->iPpsId != kpCurSliceHeader->iPpsId)
return TRUE;
if (kpLastSliceHeader->bFieldPicFlag != kpCurSliceHeader->bFieldPicFlag)
return TRUE;
if (kpLastSliceHeader->bBottomFiledFlag != kpCurSliceHeader->bBottomFiledFlag)
return TRUE;
if ((kpLastNalHeaderExt->sNalUnitHeader.uiNalRefIdc != NRI_PRI_LOWEST) != (kpCurNalHeaderExt->sNalUnitHeader.uiNalRefIdc
!= NRI_PRI_LOWEST))
return TRUE;
if (kpLastNalHeaderExt->bIdrFlag != kpCurNalHeaderExt->bIdrFlag)
return TRUE;
if (kpCurNalHeaderExt->bIdrFlag) {
if (kpLastSliceHeader->uiIdrPicId != kpCurSliceHeader->uiIdrPicId)
return TRUE;
}
if (kpSps->uiPocType == 0) {
if (kpLastSliceHeader->iPicOrderCntLsb != kpCurSliceHeader->iPicOrderCntLsb)
return TRUE;
if (kpLastSliceHeader->iDeltaPicOrderCntBottom != kpCurSliceHeader->iDeltaPicOrderCntBottom)
return TRUE;
} else if (kpSps->uiPocType == 1) {
if (kpLastSliceHeader->iDeltaPicOrderCnt[0] != kpCurSliceHeader->iDeltaPicOrderCnt[0])
return TRUE;
if (kpLastSliceHeader->iDeltaPicOrderCnt[1] != kpCurSliceHeader->iDeltaPicOrderCnt[1])
return TRUE;
}
return FALSE;
}
/*!
*************************************************************************************
* \brief to parse NON VCL NAL Units
*
* \param pCtx decoder context
* \param rbsp rbsp buffer of NAL Unit
* \param src_len length of rbsp buffer
*
* \return 0 - successed
* 1 - failed
*
*************************************************************************************
*/
int32_t ParseNonVclNal (PWelsDecoderContext pCtx, uint8_t* pRbsp, const int32_t kiSrcLen) {
PBitStringAux pBs = NULL;
ENalUnitType eNalType = NAL_UNIT_UNSPEC_0; // make initial value as unspecified
int32_t iPicWidth = 0;
int32_t iPicHeight = 0;
int32_t iBitSize = 0;
int32_t iErr = ERR_NONE;
if (kiSrcLen <= 0)
return iErr;
pBs = &pCtx->sBs; // SBitStringAux instance for non VCL NALs decoding
iBitSize = (kiSrcLen << 3) - BsGetTrailingBits (pRbsp + kiSrcLen - 1); // convert into bit
eNalType = pCtx->sCurNalHead.eNalUnitType;
switch (eNalType) {
case NAL_UNIT_SPS:
case NAL_UNIT_SUBSET_SPS:
if (iBitSize > 0)
InitBits (pBs, pRbsp, iBitSize);
#ifdef DEBUG_PARSE_INFO
WelsLog (pCtx, WELS_LOG_INFO, "parsing nal: %d \n", eNalType);
#endif
iErr = ParseSps (pCtx, pBs, &iPicWidth, &iPicHeight);
if (ERR_NONE != iErr) { // modified for pSps/pSubsetSps invalid, 12/1/2009
pCtx->iErrorCode |= dsNoParamSets;
return iErr;
}
break;
case NAL_UNIT_PPS:
if (iBitSize > 0)
InitBits (pBs, pRbsp, iBitSize);
#ifdef DEBUG_PARSE_INFO
WelsLog (pCtx, WELS_LOG_INFO, "parsing nal: %d \n", eNalType);
#endif
iErr = ParsePps (pCtx, &pCtx->sPpsBuffer[0], pBs);
if (ERR_NONE != iErr) { // modified for pps invalid, 12/1/2009
pCtx->iErrorCode |= dsNoParamSets;
return iErr;
}
pCtx->bPpsExistAheadFlag = true;
break;
case NAL_UNIT_SEI:
break;
case NAL_UNIT_PREFIX:
break;
case NAL_UNIT_CODED_SLICE_DPA:
case NAL_UNIT_CODED_SLICE_DPB:
case NAL_UNIT_CODED_SLICE_DPC:
break;
default:
break;
}
return iErr;
}
void_t ParseRefBasePicMarking (PBitStringAux pBs, PRefBasePicMarking pRefBasePicMarking) {
const bool_t kbAdaptiveMarkingModeFlag = !!BsGetOneBit (pBs);
pRefBasePicMarking->bAdaptiveRefBasePicMarkingModeFlag = kbAdaptiveMarkingModeFlag;
if (kbAdaptiveMarkingModeFlag) {
int32_t iIdx = 0;
do {
const uint32_t kuiMmco = BsGetUe (pBs);
pRefBasePicMarking->mmco_base[iIdx].uiMmcoType = kuiMmco;
if (kuiMmco == MMCO_END)
break;
if (kuiMmco == MMCO_SHORT2UNUSED) {
pRefBasePicMarking->mmco_base[iIdx].uiDiffOfPicNums = 1 + BsGetUe (pBs);
pRefBasePicMarking->mmco_base[iIdx].iShortFrameNum = 0;
} else if (kuiMmco == MMCO_LONG2UNUSED) {
pRefBasePicMarking->mmco_base[iIdx].uiLongTermPicNum = BsGetUe (pBs);
}
++ iIdx;
} while (iIdx < MAX_MMCO_COUNT);
}
}
void_t ParsePrefixNalUnit (PWelsDecoderContext pCtx, PBitStringAux pBs) {
PNalUnit pCurNal = &pCtx->sPrefixNal;
if (pCurNal->sNalHeaderExt.sNalUnitHeader.uiNalRefIdc != 0) {
PNalUnitHeaderExt head_ext = &pCurNal->sNalHeaderExt;
PPrefixNalUnit sPrefixNal = &pCurNal->sNalData.sPrefixNal;
sPrefixNal->bStoreRefBasePicFlag = !!BsGetOneBit (pBs);
if ((head_ext->bUseRefBasePicFlag || sPrefixNal->bStoreRefBasePicFlag) && !head_ext->bIdrFlag) {
ParseRefBasePicMarking (pBs, &sPrefixNal->sRefPicBaseMarking);
}
sPrefixNal->bPrefixNalUnitAdditionalExtFlag = !!BsGetOneBit (pBs);
if (sPrefixNal->bPrefixNalUnitAdditionalExtFlag) {
sPrefixNal->bPrefixNalUnitExtFlag = !!BsGetOneBit (pBs);
}
}
}
int32_t DecodeSpsSvcExt (PWelsDecoderContext pCtx, PSubsetSps pSpsExt, PBitStringAux pBs) {
PSpsSvcExt pExt = NULL;
uint8_t uiChromaArrayType = 1;
pExt = &pSpsExt->sSpsSvcExt;
pExt->bInterLayerDeblockingFilterCtrlPresentFlag = !!BsGetOneBit (pBs);
pExt->uiExtendedSpatialScalability = BsGetBits (pBs, 2);
if (pExt->uiExtendedSpatialScalability > 2) {
WelsLog (pCtx, WELS_LOG_WARNING, "DecodeSpsSvcExt():extended_spatial_scalability (%d) != 0, ESS not supported!\n",
pExt->uiExtendedSpatialScalability);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_INVALID_ESS);
}
pExt->uiChromaPhaseXPlus1Flag =
0; // FIXME: Incoherent with JVT X201 standard (= 1), but conformance to JSVM (= 0) implementation.
pExt->uiChromaPhaseYPlus1 = 1;
uiChromaArrayType = pSpsExt->sSps.uiChromaArrayType;
pExt->uiChromaPhaseXPlus1Flag = BsGetOneBit (pBs);
pExt->uiChromaPhaseYPlus1 = BsGetBits (pBs, 2);
pExt->uiSeqRefLayerChromaPhaseXPlus1Flag = pExt->uiChromaPhaseXPlus1Flag;
pExt->uiSeqRefLayerChromaPhaseYPlus1 = pExt->uiChromaPhaseYPlus1;
memset (&pExt->sSeqScaledRefLayer, 0, sizeof (SPosOffset));
if (pExt->uiExtendedSpatialScalability == 1) {
SPosOffset* const kpPos = &pExt->sSeqScaledRefLayer;
pExt->uiSeqRefLayerChromaPhaseXPlus1Flag = BsGetOneBit (pBs);
pExt->uiSeqRefLayerChromaPhaseYPlus1 = BsGetBits (pBs, 2);
kpPos->iLeftOffset = BsGetSe (pBs);
kpPos->iTopOffset = BsGetSe (pBs);
kpPos->iRightOffset = BsGetSe (pBs);
kpPos->iBottomOffset = BsGetSe (pBs);
}
pExt->bSeqTCoeffLevelPredFlag = !!BsGetOneBit (pBs);
pExt->bAdaptiveTCoeffLevelPredFlag = false;
if (pExt->bSeqTCoeffLevelPredFlag)
pExt->bAdaptiveTCoeffLevelPredFlag = !!BsGetOneBit (pBs);
pExt->bSliceHeaderRestrictionFlag = !!BsGetOneBit (pBs);
return 0;
}
// table A-1 - Level limits
static const SLevelLimits g_kSLevelLimits[17] = {
{1485, 99, 396, 64, 175, -256, 255, 2, 0x7fff}, /* level 1 */
{1485, 99, 396, 128, 350, -256, 255, 2, 0x7fff}, /* level 1.b */
{3000, 396, 900, 192, 500, -512, 511, 2, 0x7fff}, /* level 1.1 */
{6000, 396, 2376, 384, 1000, -512, 511, 2, 0x7fff}, /* level 1.2 */
{11880, 396, 2376, 768, 2000, -512, 511, 2, 0x7fff}, /* level 1.3 */
{11880, 396, 2376, 2000, 2000, -512, 511, 2, 0x7fff}, /* level 2 */
{19800, 792, 4752, 4000, 4000, -1024, 1023, 2, 0x7fff}, /* level 2.1 */
{20250, 1620, 8100, 4000, 4000, -1024, 1023, 2, 0x7fff}, /* level 2.2 */
{40500, 1620, 8100, 10000, 10000, -1024, 1023, 2, 32 }, /* level 3 */
{108000, 3600, 18000, 14000, 14000, -2048, 2047, 4, 16}, /* level 3.1 */
{216000, 5120, 20480, 20000, 20000, -2048, 2047, 4, 16}, /* level 3.2 */
{245760, 8192, 32768, 20000, 25000, -2048, 2047, 4, 16}, /* level 4 */
{245760, 8192, 32768, 50000, 62500, -2048, 2047, 2, 16}, /* level 4.1 */
{522240, 8704, 34816, 50000, 62500, -2048, 2047, 2, 16}, /* level 4.2 */
{589824, 22080, 110400, 135000, 135000, -2048, 2047, 2, 16}, /* level 5 */
{983040, 36864, 184320, 240000, 240000, -2048, 2047, 2, 16}, /* level 5.1 */
{2073600, 36864, 184320, 240000, 240000, -2048, 2047, 2, 16} /* level 5.2 */
};
const SLevelLimits *GetLevelLimits(int32_t iLevelIdx, bool_t bConstraint3) {
switch (iLevelIdx) {
case 10:
return &g_kSLevelLimits[0];
case 11:
if(bConstraint3)
return &g_kSLevelLimits[1];
else
return &g_kSLevelLimits[2];
case 12:
return &g_kSLevelLimits[3];
case 13:
return &g_kSLevelLimits[4];
case 20:
return &g_kSLevelLimits[5];
case 21:
return &g_kSLevelLimits[6];
case 22:
return &g_kSLevelLimits[7];
case 30:
return &g_kSLevelLimits[8];
case 31:
return &g_kSLevelLimits[9];
case 32:
return &g_kSLevelLimits[10];
case 40:
return &g_kSLevelLimits[11];
case 41:
return &g_kSLevelLimits[12];
case 42:
return &g_kSLevelLimits[13];
case 50:
return &g_kSLevelLimits[14];
case 51:
return &g_kSLevelLimits[15];
case 52:
return &g_kSLevelLimits[16];
default:
return NULL;
}
return NULL;
}
/*!
*************************************************************************************
* \brief to parse Sequence Parameter Set (SPS)
*
* \param pCtx Decoder context
* \param pBsAux bitstream reader auxiliary
* \param pPicWidth picture width current Sps represented
* \param pPicHeight picture height current Sps represented
*
* \return 0 - successed
* 1 - failed
*
* \note Call it in case eNalUnitType is SPS.
*************************************************************************************
*/
int32_t ParseSps (PWelsDecoderContext pCtx, PBitStringAux pBsAux, int32_t* pPicWidth, int32_t* pPicHeight) {
PBitStringAux pBs = pBsAux;
PSps pSps = NULL;
PSubsetSps pSubsetSps = NULL;
SNalUnitHeader* pNalHead = &pCtx->sCurNalHead;
ProfileIdc uiProfileIdc;
uint8_t uiLevelIdc;
int32_t iSpsId;
bool_t bConstraintSetFlags[6] = { false };
const bool_t kbUseSubsetFlag = IS_SUBSET_SPS_NAL (pNalHead->eNalUnitType);
if (kbUseSubsetFlag) { // SubsetSps
pCtx->bSubspsExistAheadFlag = true;
} else { // Sps
pCtx->bSpsExistAheadFlag = true;
// added for EC, 10/28/2009
// for safe
memset (&pCtx->bSpsAvailFlags[0], 0, sizeof (pCtx->bSpsAvailFlags));
memset (&pCtx->bSubspsAvailFlags[0], 0, sizeof (pCtx->bSubspsAvailFlags));
memset (&pCtx->bPpsAvailFlags[0], 0, sizeof (pCtx->bPpsAvailFlags));
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pCtx->iSpsTotalNum = 0;
pCtx->iSubspsTotalNum = 0;
pCtx->iPpsTotalNum = 0;
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
}
uiProfileIdc = BsGetBits (pBs, 8);
bConstraintSetFlags[0] = !!BsGetOneBit (pBs); // constraint_set0_flag
bConstraintSetFlags[1] = !!BsGetOneBit (pBs); // constraint_set1_flag
bConstraintSetFlags[2] = !!BsGetOneBit (pBs); // constraint_set2_flag
bConstraintSetFlags[3] = !!BsGetOneBit (pBs); // constraint_set3_flag
bConstraintSetFlags[4] = !!BsGetOneBit (pBs); // constraint_set4_flag
bConstraintSetFlags[5] = !!BsGetOneBit (pBs); // constraint_set5_flag
BsGetBits (pBs, 2); // reserved_zero_2bits, equal to 0
uiLevelIdc = BsGetBits (pBs, 8); // level_idc
iSpsId = BsGetUe (pBs); // seq_parameter_set_id
if (iSpsId >= MAX_SPS_COUNT || iSpsId < 0) { // Modified to check invalid negative iSpsId, 12/1/2009
WelsLog (pCtx, WELS_LOG_WARNING, " iSpsId is out of range! \n");
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_SPS_ID_OVERFLOW);
}
if (kbUseSubsetFlag) {
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pSubsetSps = &pCtx->sSubsetSpsBuffer[pCtx->iSubspsTotalNum];
pCtx->bSubspsAvailFlags[pCtx->iSubspsTotalNum] = true;
pSubsetSps->sSps.iSpsId = iSpsId;
pSps = &pSubsetSps->sSps;
++pCtx->iSubspsTotalNum;
#else
pSubsetSps = &pCtx->sSubsetSpsBuffer[iSpsId];
pSps = &pSubsetSps->sSps;
pCtx->bSubspsAvailFlags[iSpsId] = true; // added for EC, 10/28/2009
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
} else {
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pSps = &pCtx->sSpsBuffer[pCtx->iSpsTotalNum];
pCtx->bSpsAvailFlags[pCtx->iSpsTotalNum] = true;
pSps->iSpsId = iSpsId;
++pCtx->iSpsTotalNum;
#else
pSps = &pCtx->sSpsBuffer[iSpsId];
pCtx->bSpsAvailFlags[iSpsId] = true; // added for EC, 10/28/2009
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
}
const SLevelLimits *pSLevelLimits = GetLevelLimits(uiLevelIdc, bConstraintSetFlags[3]);
if (NULL == pSLevelLimits) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): level_idx (%d).\n", uiLevelIdc);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_NON_BASELINE);
}
else pSps->pSLevelLimits = pSLevelLimits;
// syntax elements in default
pSps->uiChromaFormatIdc = 1;
pSps->uiBitDepthLuma =
pSps->uiBitDepthChroma = 8;
pSps->uiProfileIdc = uiProfileIdc;
pSps->uiLevelIdc = uiLevelIdc;
pSps->iSpsId = iSpsId;
if (PRO_SCALABLE_BASELINE == uiProfileIdc || PRO_SCALABLE_HIGH == uiProfileIdc ||
PRO_HIGH == uiProfileIdc || PRO_HIGH10 == uiProfileIdc ||
PRO_HIGH422 == uiProfileIdc || PRO_HIGH444 == uiProfileIdc ||
PRO_CAVLC444 == uiProfileIdc || 44 == uiProfileIdc) {
pSps->uiChromaFormatIdc = BsGetUe (pBs);
if (pSps->uiChromaFormatIdc != 1) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): chroma_format_idc (%d) = 1 supported.\n", pSps->uiChromaFormatIdc);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_NON_BASELINE);
}
pSps->uiChromaArrayType = pSps->uiChromaFormatIdc;
pSps->uiBitDepthLuma = 8 + BsGetUe (pBs);
if (pSps->uiBitDepthLuma != 8) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): bit_depth_luma (%d) Only 8 bit supported.\n", pSps->uiBitDepthLuma);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_NON_BASELINE);
}
pSps->uiBitDepthChroma = 8 + BsGetUe (pBs);
if (pSps->uiBitDepthChroma != 8) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): bit_depth_chroma (%d). Only 8 bit supported.\n", pSps->uiBitDepthChroma);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_NON_BASELINE);
}
pSps->bQpPrimeYZeroTransfBypassFlag = !!BsGetOneBit (pBs);
pSps->bSeqScalingMatrixPresentFlag = !!BsGetOneBit (pBs);
if (pSps->bSeqScalingMatrixPresentFlag) { // For high profile, it is not used in current application. FIXME
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): seq_scaling_matrix_present_flag (%d). Feature not supported.\n",
pSps->bSeqScalingMatrixPresentFlag);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_NON_BASELINE);
}
}
pSps->uiLog2MaxFrameNum = 4 + BsGetUe (pBs); // log2_max_frame_num_minus4
pSps->uiPocType = BsGetUe (pBs); // pic_order_cnt_type
if (0 == pSps->uiPocType) {
pSps->iLog2MaxPocLsb = 4 + BsGetUe (pBs); // log2_max_pic_order_cnt_lsb_minus4
} else if (1 == pSps->uiPocType) {
int32_t i;
pSps->bDeltaPicOrderAlwaysZeroFlag = !!BsGetOneBit (pBs); // bDeltaPicOrderAlwaysZeroFlag
pSps->iOffsetForNonRefPic = BsGetSe (pBs); // iOffsetForNonRefPic
pSps->iOffsetForTopToBottomField = BsGetSe (pBs); // iOffsetForTopToBottomField
pSps->iNumRefFramesInPocCycle = BsGetUe (pBs); // num_ref_frames_in_pic_order_cnt_cycle
for (i = 0; i < pSps->iNumRefFramesInPocCycle; i++)
pSps->iOffsetForRefFrame[ i ] = BsGetSe (pBs); // iOffsetForRefFrame[ i ]
}
if (pSps->uiPocType > 2) {
WelsLog (pCtx, WELS_LOG_WARNING, " illegal pic_order_cnt_type: %d ! \n", pSps->uiPocType);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_INVALID_POC_TYPE);
}
pSps->iNumRefFrames = BsGetUe (pBs); // max_num_ref_frames
pSps->bGapsInFrameNumValueAllowedFlag = !!BsGetOneBit (pBs); // bGapsInFrameNumValueAllowedFlag
pSps->iMbWidth = 1 + BsGetUe (pBs); // pic_width_in_mbs_minus1
pSps->iMbHeight = 1 + BsGetUe (pBs); // pic_height_in_map_units_minus1
pSps->uiTotalMbCount = pSps->iMbWidth * pSps->iMbHeight;
pSps->bFrameMbsOnlyFlag = !!BsGetOneBit (pBs); // frame_mbs_only_flag
if (!pSps->bFrameMbsOnlyFlag) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParseSps(): frame_mbs_only_flag (%d) not supported.\n", pSps->bFrameMbsOnlyFlag);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_MBAFF);
}
pSps->bDirect8x8InferenceFlag = !!BsGetOneBit (pBs); // direct_8x8_inference_flag
pSps->bFrameCroppingFlag = !!BsGetOneBit (pBs); // frame_cropping_flag
if (pSps->bFrameCroppingFlag) {
pSps->sFrameCrop.iLeftOffset = BsGetUe (pBs); // frame_crop_left_offset
pSps->sFrameCrop.iRightOffset = BsGetUe (pBs); // frame_crop_right_offset
pSps->sFrameCrop.iTopOffset = BsGetUe (pBs); // frame_crop_top_offset
pSps->sFrameCrop.iBottomOffset = BsGetUe (pBs); // frame_crop_bottom_offset
} else {
pSps->sFrameCrop.iLeftOffset = 0; // frame_crop_left_offset
pSps->sFrameCrop.iRightOffset = 0; // frame_crop_right_offset
pSps->sFrameCrop.iTopOffset = 0; // frame_crop_top_offset
pSps->sFrameCrop.iBottomOffset = 0; // frame_crop_bottom_offset
}
pSps->bVuiParamPresentFlag = !!BsGetOneBit (pBs); // vui_parameters_present_flag
// Check if SPS SVC extension applicated
if (kbUseSubsetFlag && (PRO_SCALABLE_BASELINE == uiProfileIdc || PRO_SCALABLE_HIGH == uiProfileIdc)) {
if (DecodeSpsSvcExt (pCtx, pSubsetSps, pBs) != ERR_NONE) {
return -1;
}
pSubsetSps->bSvcVuiParamPresentFlag = !!BsGetOneBit (pBs);
if (pSubsetSps->bSvcVuiParamPresentFlag) {
}
}
if (PRO_SCALABLE_BASELINE == uiProfileIdc || PRO_SCALABLE_HIGH == uiProfileIdc)
pCtx->bAvcBasedFlag = false;
else
pCtx->bAvcBasedFlag = true; // added for avc base pBs
*pPicWidth = pSps->iMbWidth << 4;
*pPicHeight = pSps->iMbHeight << 4;
return 0;
}
/*!
*************************************************************************************
* \brief to parse Picture Parameter Set (PPS)
*
* \param pCtx Decoder context
* \param pPpsList pps list
* \param pBsAux bitstream reader auxiliary
*
* \return 0 - successed
* 1 - failed
*
* \note Call it in case eNalUnitType is PPS.
*************************************************************************************
*/
int32_t ParsePps (PWelsDecoderContext pCtx, PPps pPpsList, PBitStringAux pBsAux) {
PPps pPps = NULL;
uint32_t uiPpsId = 0;
uint32_t iTmp;
uiPpsId = BsGetUe (pBsAux);
if (uiPpsId >= MAX_PPS_COUNT) {
return ERR_INFO_PPS_ID_OVERFLOW;
}
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pPps = &pPpsList[pCtx->iPpsTotalNum];
#else
pPps = &pPpsList[uiPpsId];
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pPps->iPpsId = uiPpsId;
pPps->iSpsId = BsGetUe (pBsAux);
if (pPps->iSpsId >= MAX_SPS_COUNT) {
return ERR_INFO_SPS_ID_OVERFLOW;
}
pPps->bEntropyCodingModeFlag = !!BsGetOneBit (pBsAux);
pPps->bPicOrderPresentFlag = !!BsGetOneBit (pBsAux);
pPps->uiNumSliceGroups = 1 + BsGetUe (pBsAux);
if (pPps->uiNumSliceGroups > MAX_SLICEGROUP_IDS) {
return ERR_INFO_INVALID_SLICEGROUP;
}
if (pPps->uiNumSliceGroups > 1) {
pPps->uiSliceGroupMapType = BsGetUe (pBsAux);
if (pPps->uiSliceGroupMapType > 1) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParsePps(): slice_group_map_type (%d): support only 0,1.\n",
pPps->uiSliceGroupMapType);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_FMOTYPE);
}
switch (pPps->uiSliceGroupMapType) {
case 0:
for (iTmp = 0; iTmp < pPps->uiNumSliceGroups; iTmp++) {
pPps->uiRunLength[iTmp] = 1 + BsGetUe (pBsAux);
}
break;
default:
break;
}
}
pPps->uiNumRefIdxL0Active = 1 + BsGetUe (pBsAux);
pPps->uiNumRefIdxL1Active = 1 + BsGetUe (pBsAux);
if (pPps->uiNumRefIdxL0Active > MAX_REF_PIC_COUNT ||
pPps->uiNumRefIdxL1Active > MAX_REF_PIC_COUNT) {
return ERR_INFO_REF_COUNT_OVERFLOW;
}
pPps->bWeightedPredFlag = !!BsGetOneBit (pBsAux);
pPps->uiWeightedBipredIdc = BsGetBits (pBsAux, 2);
if (pPps->bWeightedPredFlag || pPps->uiWeightedBipredIdc != 0) {
WelsLog (pCtx, WELS_LOG_WARNING, "ParsePps(): weighted_pred_flag (%d) weighted_bipred_idc (%d) neither supported.\n",
pPps->bWeightedPredFlag, pPps->uiWeightedBipredIdc);
return GENERATE_ERROR_NO (ERR_LEVEL_PARAM_SETS, ERR_INFO_UNSUPPORTED_WP);
}
pPps->iPicInitQp = 26 + BsGetSe (pBsAux);
pPps->iPicInitQs = 26 + BsGetSe (pBsAux);
pPps->iChromaQpIndexOffset = BsGetSe (pBsAux);
pPps->bDeblockingFilterControlPresentFlag = !!BsGetOneBit (pBsAux);
pPps->bConstainedIntraPredFlag = !!BsGetOneBit (pBsAux);
pPps->bRedundantPicCntPresentFlag = !!BsGetOneBit (pBsAux);
#ifdef MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
pCtx->bPpsAvailFlags[pCtx->iPpsTotalNum] = true;
++pCtx->iPpsTotalNum;
#else
pCtx->bPpsAvailFlags[uiPpsId] = true; // added for EC, 10/28/2009
#endif //MOSAIC_AVOID_BASED_ON_SPS_PPS_ID
return ERR_NONE;
}
/*!
*************************************************************************************
* \brief to parse SEI message payload
*
* \param pSei sei message to be parsed output
* \param pBsAux bitstream reader auxiliary
*
* \return 0 - successed
* 1 - failed
*
* \note Call it in case eNalUnitType is NAL_UNIT_SEI.
*************************************************************************************
*/
int32_t ParseSei (void_t* pSei, PBitStringAux pBsAux) { // reserved Sei_Msg type
return ERR_NONE;
}
/*!
*************************************************************************************
* \brief reset fmo list due to got Sps now
*
* \param pCtx decoder context
*
* \return count number of fmo context units are reset
*************************************************************************************
*/
int32_t ResetFmoList (PWelsDecoderContext pCtx) {
int32_t iCountNum = 0;
if (NULL != pCtx) {
// Fixed memory leak due to PPS_ID might not be continuous sometimes, 1/5/2010
UninitFmoList (&pCtx->sFmoList[0], MAX_PPS_COUNT, pCtx->iActiveFmoNum);
iCountNum = pCtx->iActiveFmoNum;
pCtx->iActiveFmoNum = 0;
}
return iCountNum;
}
} // namespace WelsDec