ref: 45c2fff6b8def33940bafe3fd157d0991057c4fa
dir: /codec/decoder/core/src/decoder.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 decoder.c * * \brief Interfaces implementation introduced in decoder system architecture * * \date 03/10/2009 Created * ************************************************************************************* */ #include "codec_def.h" #include "decoder.h" #include "cpu.h" #include "au_parser.h" #include "get_intra_predictor.h" #include "rec_mb.h" #include "mc.h" #include "decode_mb_aux.h" #include "manage_dec_ref.h" #include "decoder_core.h" #include "deblocking.h" #include "expand_pic.h" #include "decode_slice.h" #include "error_concealment.h" #include "mem_align.h" namespace WelsDec { extern PPicture AllocPicture (PWelsDecoderContext pCtx, const int32_t kiPicWidth, const int32_t kiPicHeight); extern void FreePicture (PPicture pPic); static int32_t CreatePicBuff (PWelsDecoderContext pCtx, PPicBuff* ppPicBuf, const int32_t kiSize, const int32_t kiPicWidth, const int32_t kiPicHeight) { PPicBuff pPicBuf = NULL; int32_t iPicIdx = 0; if (kiSize <= 0 || kiPicWidth <= 0 || kiPicHeight <= 0) { return 1; } pPicBuf = (PPicBuff)WelsMalloc (sizeof (SPicBuff), "PPicBuff"); if (NULL == pPicBuf) { return 1; } pPicBuf->ppPic = (PPicture*)WelsMalloc (kiSize * sizeof (PPicture), "PPicture*"); if (NULL == pPicBuf->ppPic) { return 1; } for (iPicIdx = 0; iPicIdx < kiSize; ++ iPicIdx) { PPicture pPic = AllocPicture (pCtx, kiPicWidth, kiPicHeight); if (NULL == pPic) { return 1; } pPicBuf->ppPic[iPicIdx] = pPic; } // initialize context in queue pPicBuf->iCapacity = kiSize; pPicBuf->iCurrentIdx = 0; *ppPicBuf = pPicBuf; return 0; } static void DestroyPicBuff (PPicBuff* ppPicBuf) { PPicBuff pPicBuf = NULL; if (NULL == ppPicBuf || NULL == *ppPicBuf) return; pPicBuf = *ppPicBuf; while (pPicBuf->ppPic != NULL) { int32_t iPicIdx = 0; while (iPicIdx < pPicBuf->iCapacity) { PPicture pPic = pPicBuf->ppPic[iPicIdx]; if (pPic != NULL) { FreePicture (pPic); } pPic = NULL; ++ iPicIdx; } WelsFree (pPicBuf->ppPic, "pPicBuf->queue"); pPicBuf->ppPic = NULL; } pPicBuf->iCapacity = 0; pPicBuf->iCurrentIdx = 0; WelsFree (pPicBuf, "pPicBuf"); pPicBuf = NULL; *ppPicBuf = NULL; } /* * fill data fields in default for decoder context */ void WelsDecoderDefaults (PWelsDecoderContext pCtx, SLogContext* pLogCtx) { int32_t iCpuCores = 1; memset (pCtx, 0, sizeof (SWelsDecoderContext)); // fill zero first pCtx->sLogCtx = *pLogCtx; pCtx->pArgDec = NULL; pCtx->iOutputColorFormat = videoFormatI420; // yuv in default pCtx->bHaveGotMemory = false; // not ever request memory blocks for decoder context related pCtx->uiCpuFlag = 0; pCtx->bAuReadyFlag = 0; // au data is not ready pCtx->uiCpuFlag = WelsCPUFeatureDetect (&iCpuCores); pCtx->iImgWidthInPixel = 0; pCtx->iImgHeightInPixel = 0; // alloc picture data when picture size is available pCtx->iFrameNum = -1; pCtx->iPrevFrameNum = -1; pCtx->iErrorCode = ERR_NONE; pCtx->pDec = NULL; WelsResetRefPic (pCtx); pCtx->iActiveFmoNum = 0; pCtx->pPicBuff[LIST_0] = NULL; pCtx->pPicBuff[LIST_1] = NULL; pCtx->bAvcBasedFlag = true; pCtx->iErrorConMethod = ERROR_CON_SLICE_COPY; pCtx->pPreviousDecodedPictureInDpb = NULL; } /* * destory_mb_blocks */ /* * get size of reference picture list in target layer incoming, = (iNumRefFrames */ static inline int32_t GetTargetRefListSize (PWelsDecoderContext pCtx) { int32_t iNumRefFrames = 0; if ((pCtx == NULL) || (pCtx->pSps == NULL)) { iNumRefFrames = MAX_REF_PIC_COUNT; } else { iNumRefFrames = pCtx->pSps->iNumRefFrames + 1; } #ifdef LONG_TERM_REF //pic_queue size minimum set 2 if (iNumRefFrames < 2) { iNumRefFrames = 2; } #endif return iNumRefFrames; } /* * request memory blocks for decoder avc part */ int32_t WelsRequestMem (PWelsDecoderContext pCtx, const int32_t kiMbWidth, const int32_t kiMbHeight) { const int32_t kiPicWidth = kiMbWidth << 4; const int32_t kiPicHeight = kiMbHeight << 4; int32_t iErr = ERR_NONE; int32_t iListIdx = 0; //, mb_blocks = 0; int32_t iPicQueueSize = 0; // adaptive size of picture queue, = (pSps->iNumRefFrames x 2) bool bNeedChangePicQueue = true; WELS_VERIFY_RETURN_IF (ERR_INFO_INVALID_PARAM, (NULL == pCtx || kiPicWidth <= 0 || kiPicHeight <= 0)) // Fixed the issue about different gop size over last, 5/17/2010 // get picture queue size currently iPicQueueSize = GetTargetRefListSize (pCtx); // adaptive size of picture queue, = (pSps->iNumRefFrames x 2) pCtx->iPicQueueNumber = iPicQueueSize; if (pCtx->pPicBuff[LIST_0] != NULL && pCtx->pPicBuff[LIST_0]->iCapacity == iPicQueueSize) // comparing current picture queue size requested and previous allocation picture queue bNeedChangePicQueue = false; // HD based pic buffer need consider memory size consumed when switch from 720p to other lower size WELS_VERIFY_RETURN_IF (ERR_NONE, pCtx->bHaveGotMemory && (kiPicWidth == pCtx->iImgWidthInPixel && kiPicHeight == pCtx->iImgHeightInPixel) && (!bNeedChangePicQueue)) // have same scaled buffer // sync update pRefList WelsResetRefPic (pCtx); // added to sync update ref list due to pictures are free // for Recycled_Pic_Queue for (iListIdx = LIST_0; iListIdx < LIST_A; ++ iListIdx) { PPicBuff* ppPic = &pCtx->pPicBuff[iListIdx]; if (NULL != ppPic && NULL != *ppPic) { DestroyPicBuff (ppPic); } } pCtx->pPreviousDecodedPictureInDpb = NULL; // currently only active for LIST_0 due to have no B frames iErr = CreatePicBuff (pCtx, &pCtx->pPicBuff[LIST_0], iPicQueueSize, kiPicWidth, kiPicHeight); if (iErr != ERR_NONE) return iErr; pCtx->iImgWidthInPixel = kiPicWidth; // target width of image to be reconstruted while decoding pCtx->iImgHeightInPixel = kiPicHeight; // target height of image to be reconstruted while decoding pCtx->bHaveGotMemory = true; // global memory for decoder context related is requested pCtx->pDec = NULL; // need prefetch a new pic due to spatial size changed return ERR_NONE; } /* * free memory blocks in avc */ void WelsFreeMem (PWelsDecoderContext pCtx) { int32_t iListIdx = 0; /* TODO: free memory blocks introduced in avc */ ResetFmoList (pCtx); WelsResetRefPic (pCtx); // for sPicBuff for (iListIdx = LIST_0; iListIdx < LIST_A; ++ iListIdx) { PPicBuff* pPicBuff = &pCtx->pPicBuff[iListIdx]; if (NULL != pPicBuff && NULL != *pPicBuff) { DestroyPicBuff (pPicBuff); } } // added for safe memory pCtx->iImgWidthInPixel = 0; pCtx->iImgHeightInPixel = 0; pCtx->bHaveGotMemory = false; } /*! * \brief Open decoder */ void WelsOpenDecoder (PWelsDecoderContext pCtx) { // function pointers //initial MC function pointer-- InitMcFunc (& (pCtx->sMcFunc), pCtx->uiCpuFlag); InitExpandPictureFunc (& (pCtx->sExpandPicFunc), pCtx->uiCpuFlag); AssignFuncPointerForRec (pCtx); // vlc tables InitVlcTable (&pCtx->sVlcTable); // startup memory if (ERR_NONE != WelsInitMemory (pCtx)) return; #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; // should be true to waiting IDR at incoming AU bits following, 6/4/2010 #endif //LONG_TERM_REF pCtx->bNewSeqBegin = true; pCtx->bDecErrorConedFlag = false; //default: decoder normal status pCtx->bPrintFrameErrorTraceFlag = true; pCtx->iIgnoredErrorInfoPacketCount = 0; } /*! * \brief Close decoder */ void WelsCloseDecoder (PWelsDecoderContext pCtx) { WelsFreeMem (pCtx); WelsFreeMemory (pCtx); UninitialDqLayersContext (pCtx); #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = false; #else pCtx->bReferenceLostAtT0Flag = false; #endif pCtx->bNewSeqBegin = false; pCtx->bPrintFrameErrorTraceFlag = false; } /*! * \brief configure decoder parameters */ int32_t DecoderConfigParam (PWelsDecoderContext pCtx, const SDecodingParam* kpParam) { if (NULL == pCtx || NULL == kpParam) return 1; pCtx->pParam = (SDecodingParam*)WelsMalloc (sizeof (SDecodingParam), "SDecodingParam"); if (NULL == pCtx->pParam) return 1; memcpy (pCtx->pParam, kpParam, sizeof (SDecodingParam)); pCtx->iOutputColorFormat = pCtx->pParam->iOutputColorFormat; pCtx->bErrorResilienceFlag = pCtx->pParam->uiEcActiveFlag ? true : false; if (VIDEO_BITSTREAM_SVC == pCtx->pParam->sVideoProperty.eVideoBsType || VIDEO_BITSTREAM_AVC == pCtx->pParam->sVideoProperty.eVideoBsType) { pCtx->eVideoType = pCtx->pParam->sVideoProperty.eVideoBsType; } else { pCtx->eVideoType = VIDEO_BITSTREAM_DEFAULT; } WelsLog (& (pCtx->sLogCtx), WELS_LOG_INFO, "eVideoType: %d\n", pCtx->eVideoType); return 0; } /*! ************************************************************************************* * \brief Initialize Wels decoder parameters and memory * * \param pCtx input context to be initialized at first stage * * \return 0 - successed * \return 1 - failed * * \note N/A ************************************************************************************* */ int32_t WelsInitDecoder (PWelsDecoderContext pCtx, SLogContext* pLogCtx) { if (pCtx == NULL) { return ERR_INFO_INVALID_PTR; } // default WelsDecoderDefaults (pCtx, pLogCtx); // open decoder WelsOpenDecoder (pCtx); return ERR_NONE; } /*! ************************************************************************************* * \brief Uninitialize Wels decoder parameters and memory * * \param pCtx input context to be uninitialized at release stage * * \return NONE * * \note N/A ************************************************************************************* */ void WelsEndDecoder (PWelsDecoderContext pCtx) { // close decoder WelsCloseDecoder (pCtx); } void GetVclNalTemporalId (PWelsDecoderContext pCtx) { PAccessUnit pAccessUnit = pCtx->pAccessUnitList; int32_t idx = pAccessUnit->uiStartPos; pCtx->iFeedbackVclNalInAu = FEEDBACK_VCL_NAL; pCtx->iFeedbackTidInAu = pAccessUnit->pNalUnitsList[idx]->sNalHeaderExt.uiTemporalId; } /*! ************************************************************************************* * \brief First entrance to decoding core interface. * * \param pCtx decoder context * \param pBufBs bit streaming buffer * \param kBsLen size in bytes length of bit streaming buffer input * \param ppDst picture payload data to be output * \param pDstBufInfo buf information of ouput data * * \return 0 - successed * \return 1 - failed * * \note N/A ************************************************************************************* */ int32_t WelsDecodeBs (PWelsDecoderContext pCtx, const uint8_t* kpBsBuf, const int32_t kiBsLen, uint8_t** ppDst, SBufferInfo* pDstBufInfo) { if (!pCtx->bEndOfStreamFlag) { SDataBuffer* pRawData = &pCtx->sRawData; int32_t iSrcIdx = 0; //the index of source bit-stream till now after parsing one or more NALs int32_t iSrcConsumed = 0; // consumed bit count of source bs int32_t iDstIdx = 0; //the size of current NAL after 0x03 removal and 00 00 01 removal int32_t iSrcLength = 0; //the total size of current AU or NAL int32_t iRet = 0; int32_t iConsumedBytes = 0; int32_t iOffset = 0; uint8_t* pSrcNal = NULL; uint8_t* pDstNal = NULL; uint8_t* pNalPayload = NULL; if (NULL == DetectStartCodePrefix (kpBsBuf, &iOffset, kiBsLen)) { //CAN'T find the 00 00 01 start prefix from the source buffer return dsBitstreamError; } pSrcNal = const_cast<uint8_t*> (kpBsBuf) + iOffset; iSrcLength = kiBsLen - iOffset; if ((kiBsLen + 4) > (pRawData->pEnd - pRawData->pCurPos)) { pRawData->pCurPos = pRawData->pHead; } //copy raw data from source buffer (application) to raw data buffer (codec inside) //0x03 removal and extract all of NAL Unit from current raw data pDstNal = pRawData->pCurPos; while (iSrcConsumed < iSrcLength) { if ((2 + iSrcConsumed < iSrcLength) && (0 == LD16 (pSrcNal + iSrcIdx)) && ((pSrcNal[2 + iSrcIdx] == 0x03) || (pSrcNal[2 + iSrcIdx] == 0x01))) { if (pSrcNal[2 + iSrcIdx] == 0x03) { ST16 (pDstNal + iDstIdx, 0); iDstIdx += 2; iSrcIdx += 3; iSrcConsumed += 3; } else { iConsumedBytes = 0; pNalPayload = ParseNalHeader (pCtx, &pCtx->sCurNalHead, pDstNal, iDstIdx, pSrcNal - 3, iSrcIdx + 3, &iConsumedBytes); if (IS_PARAM_SETS_NALS (pCtx->sCurNalHead.eNalUnitType) && pNalPayload) { iRet = ParseNonVclNal (pCtx, pNalPayload, iDstIdx - iConsumedBytes); } if (pCtx->bAuReadyFlag) { ConstructAccessUnit (pCtx, ppDst, pDstBufInfo); if ((dsOutOfMemory | dsNoParamSets) & pCtx->iErrorCode) { #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; #endif ResetParameterSetsState (pCtx); if (dsOutOfMemory & pCtx->iErrorCode) { return pCtx->iErrorCode; } } } if (iRet) { iRet = 0; if (dsNoParamSets & pCtx->iErrorCode) { #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; #endif ResetParameterSetsState (pCtx); } return pCtx->iErrorCode; } pDstNal += iDstIdx; //update current position if ((iSrcLength - iSrcConsumed + 4) > (pRawData->pEnd - pDstNal)) { pRawData->pCurPos = pRawData->pHead; } else { pRawData->pCurPos = pDstNal; } pDstNal = pRawData->pCurPos + 4; //init, 4 bytes used to store the next NAL pSrcNal += iSrcIdx + 3; iSrcConsumed += 3; iSrcIdx = 0; iDstIdx = 0; //reset 0, used to statistic the length of next NAL } continue; } pDstNal[iDstIdx++] = pSrcNal[iSrcIdx++]; iSrcConsumed++; } //last NAL decoding iConsumedBytes = 0; pNalPayload = ParseNalHeader (pCtx, &pCtx->sCurNalHead, pDstNal, iDstIdx, pSrcNal - 3, iSrcIdx + 3, &iConsumedBytes); if ((pCtx->iErrorConMethod != ERROR_CON_DISABLE) && (IS_VCL_NAL (pCtx->sCurNalHead.eNalUnitType, 1))) { CheckAndDoEC (pCtx, ppDst, pDstBufInfo); } if (IS_PARAM_SETS_NALS (pCtx->sCurNalHead.eNalUnitType) && pNalPayload) { iRet = ParseNonVclNal (pCtx, pNalPayload, iDstIdx - iConsumedBytes); } if (pCtx->bAuReadyFlag) { ConstructAccessUnit (pCtx, ppDst, pDstBufInfo); if ((dsOutOfMemory | dsNoParamSets) & pCtx->iErrorCode) { #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; #endif ResetParameterSetsState (pCtx); return pCtx->iErrorCode; } } if (iRet) { iRet = 0; if (dsNoParamSets & pCtx->iErrorCode) { #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; #endif ResetParameterSetsState (pCtx); } return pCtx->iErrorCode; } pDstNal += iDstIdx; pRawData->pCurPos = pDstNal; //init the pCurPos for next NAL(s) storage } else { /* no supplementary picture payload input, but stored a picture */ PAccessUnit pCurAu = pCtx->pAccessUnitList; // current access unit, it will never point to NULL after decode's successful initialization if (pCurAu->uiAvailUnitsNum == 0) { return pCtx->iErrorCode; } else { pCtx->pAccessUnitList->uiEndPos = pCtx->pAccessUnitList->uiAvailUnitsNum - 1; ConstructAccessUnit (pCtx, ppDst, pDstBufInfo); if ((dsOutOfMemory | dsNoParamSets) & pCtx->iErrorCode) { #ifdef LONG_TERM_REF pCtx->bParamSetsLostFlag = true; #else pCtx->bReferenceLostAtT0Flag = true; #endif ResetParameterSetsState (pCtx); return pCtx->iErrorCode; } } } return pCtx->iErrorCode; } /* * set colorspace format in decoder */ int32_t DecoderSetCsp (PWelsDecoderContext pCtx, const int32_t kiColorFormat) { WELS_VERIFY_RETURN_IF (1, (NULL == pCtx)); pCtx->iOutputColorFormat = kiColorFormat; if (pCtx->pParam != NULL) { pCtx->pParam->iOutputColorFormat = kiColorFormat; } return 0; } /*! * \brief make sure synchonozization picture resolution (get from slice header) among different parts (i.e, memory related and so on) * over decoder internal * ( MB coordinate and parts of data within decoder context structure ) * \param pCtx Wels decoder context * \param iMbWidth MB width * \pram iMbHeight MB height * \return 0 - successful; none 0 - something wrong */ int32_t SyncPictureResolutionExt (PWelsDecoderContext pCtx, const int32_t kiMbWidth, const int32_t kiMbHeight) { int32_t iErr = ERR_NONE; const int32_t kiPicWidth = kiMbWidth << 4; const int32_t kiPicHeight = kiMbHeight << 4; iErr = WelsRequestMem (pCtx, kiMbWidth, kiMbHeight); // common memory used if (ERR_NONE != iErr) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "SyncPictureResolutionExt()::WelsRequestMem--buffer allocated failure.\n"); pCtx->iErrorCode = dsOutOfMemory; return iErr; } iErr = InitialDqLayersContext (pCtx, kiPicWidth, kiPicHeight); if (ERR_NONE != iErr) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "SyncPictureResolutionExt()::InitialDqLayersContext--buffer allocated failure.\n"); pCtx->iErrorCode = dsOutOfMemory; } return iErr; } void AssignFuncPointerForRec (PWelsDecoderContext pCtx) { pCtx->pGetI16x16LumaPredFunc[I16_PRED_V ] = WelsI16x16LumaPredV_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_H ] = WelsI16x16LumaPredH_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC ] = WelsI16x16LumaPredDc_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_P ] = WelsI16x16LumaPredPlane_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_L ] = WelsI16x16LumaPredDcLeft_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_T ] = WelsI16x16LumaPredDcTop_c; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_128] = WelsI16x16LumaPredDcNA_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_V ] = WelsI4x4LumaPredV_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_H ] = WelsI4x4LumaPredH_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC ] = WelsI4x4LumaPredDc_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC_L ] = WelsI4x4LumaPredDcLeft_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC_T ] = WelsI4x4LumaPredDcTop_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC_128] = WelsI4x4LumaPredDcNA_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL ] = WelsI4x4LumaPredDDL_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL_TOP] = WelsI4x4LumaPredDDLTop_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDR ] = WelsI4x4LumaPredDDR_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL ] = WelsI4x4LumaPredVL_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL_TOP] = WelsI4x4LumaPredVLTop_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VR ] = WelsI4x4LumaPredVR_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HU ] = WelsI4x4LumaPredHU_c; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HD ] = WelsI4x4LumaPredHD_c; pCtx->pGetIChromaPredFunc[C_PRED_DC ] = WelsIChromaPredDc_c; pCtx->pGetIChromaPredFunc[C_PRED_H ] = WelsIChromaPredH_c; pCtx->pGetIChromaPredFunc[C_PRED_V ] = WelsIChromaPredV_c; pCtx->pGetIChromaPredFunc[C_PRED_P ] = WelsIChromaPredPlane_c; pCtx->pGetIChromaPredFunc[C_PRED_DC_L ] = WelsIChromaPredDcLeft_c; pCtx->pGetIChromaPredFunc[C_PRED_DC_T ] = WelsIChromaPredDcTop_c; pCtx->pGetIChromaPredFunc[C_PRED_DC_128] = WelsIChromaPredDcNA_c; pCtx->pIdctResAddPredFunc = IdctResAddPred_c; #if defined(HAVE_NEON) if (pCtx->uiCpuFlag & WELS_CPU_NEON) { pCtx->pIdctResAddPredFunc = IdctResAddPred_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC] = WelsDecoderI16x16LumaPredDc_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_P] = WelsDecoderI16x16LumaPredPlane_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_H] = WelsDecoderI16x16LumaPredH_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_V] = WelsDecoderI16x16LumaPredV_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_V ] = WelsDecoderI4x4LumaPredV_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_H ] = WelsDecoderI4x4LumaPredH_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL ] = WelsDecoderI4x4LumaPredDDL_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDR ] = WelsDecoderI4x4LumaPredDDR_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL ] = WelsDecoderI4x4LumaPredVL_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VR ] = WelsDecoderI4x4LumaPredVR_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HU ] = WelsDecoderI4x4LumaPredHU_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HD ] = WelsDecoderI4x4LumaPredHD_neon; pCtx->pGetIChromaPredFunc[C_PRED_H] = WelsDecoderIChromaPredH_neon; pCtx->pGetIChromaPredFunc[C_PRED_V] = WelsDecoderIChromaPredV_neon; pCtx->pGetIChromaPredFunc[C_PRED_P ] = WelsDecoderIChromaPredPlane_neon; pCtx->pGetIChromaPredFunc[C_PRED_DC] = WelsDecoderIChromaPredDc_neon; } #endif//HAVE_NEON #if defined(HAVE_NEON_AARCH64) if (pCtx->uiCpuFlag & WELS_CPU_NEON) { //pCtx->pIdctResAddPredFunc = IdctResAddPred_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC] = WelsDecoderI16x16LumaPredDc_AArch64_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_P] = WelsDecoderI16x16LumaPredPlane_AArch64_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_H] = WelsDecoderI16x16LumaPredH_AArch64_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_V] = WelsDecoderI16x16LumaPredV_AArch64_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_L] = WelsDecoderI16x16LumaPredDcLeft_AArch64_neon; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_T] = WelsDecoderI16x16LumaPredDcTop_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_H ] = WelsDecoderI4x4LumaPredH_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL ] = WelsDecoderI4x4LumaPredDDL_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL_TOP] = WelsDecoderI4x4LumaPredDDLTop_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL ] = WelsDecoderI4x4LumaPredVL_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL_TOP ] = WelsDecoderI4x4LumaPredVLTop_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VR ] = WelsDecoderI4x4LumaPredVR_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HU ] = WelsDecoderI4x4LumaPredHU_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HD ] = WelsDecoderI4x4LumaPredHD_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC ] = WelsDecoderI4x4LumaPredDc_AArch64_neon; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DC_T ] = WelsDecoderI4x4LumaPredDcTop_AArch64_neon; pCtx->pGetIChromaPredFunc[C_PRED_H] = WelsDecoderIChromaPredH_AArch64_neon; pCtx->pGetIChromaPredFunc[C_PRED_V] = WelsDecoderIChromaPredV_AArch64_neon; pCtx->pGetIChromaPredFunc[C_PRED_P ] = WelsDecoderIChromaPredPlane_AArch64_neon; pCtx->pGetIChromaPredFunc[C_PRED_DC] = WelsDecoderIChromaPredDc_AArch64_neon; pCtx->pGetIChromaPredFunc[C_PRED_DC_T] = WelsDecoderIChromaPredDcTop_AArch64_neon; } #endif//HAVE_NEON_AARCH64 #if defined(X86_ASM) if (pCtx->uiCpuFlag & WELS_CPU_MMXEXT) { pCtx->pIdctResAddPredFunc = IdctResAddPred_mmx; /////////mmx code opt--- pCtx->pGetIChromaPredFunc[C_PRED_H] = WelsDecoderIChromaPredH_mmx; pCtx->pGetIChromaPredFunc[C_PRED_V] = WelsDecoderIChromaPredV_mmx; pCtx->pGetIChromaPredFunc[C_PRED_DC_L ] = WelsDecoderIChromaPredDcLeft_mmx; pCtx->pGetIChromaPredFunc[C_PRED_DC_128] = WelsDecoderIChromaPredDcNA_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDR] = WelsDecoderI4x4LumaPredDDR_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HD ] = WelsDecoderI4x4LumaPredHD_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_HU ] = WelsDecoderI4x4LumaPredHU_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VR ] = WelsDecoderI4x4LumaPredVR_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_DDL] = WelsDecoderI4x4LumaPredDDL_mmx; pCtx->pGetI4x4LumaPredFunc[I4_PRED_VL ] = WelsDecoderI4x4LumaPredVL_mmx; } if (pCtx->uiCpuFlag & WELS_CPU_SSE2) { /////////sse2 code opt--- pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC] = WelsDecoderI16x16LumaPredDc_sse2; pCtx->pGetI16x16LumaPredFunc[I16_PRED_P] = WelsDecoderI16x16LumaPredPlane_sse2; pCtx->pGetI16x16LumaPredFunc[I16_PRED_H] = WelsDecoderI16x16LumaPredH_sse2; pCtx->pGetI16x16LumaPredFunc[I16_PRED_V] = WelsDecoderI16x16LumaPredV_sse2; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_T ] = WelsDecoderI16x16LumaPredDcTop_sse2; pCtx->pGetI16x16LumaPredFunc[I16_PRED_DC_128] = WelsDecoderI16x16LumaPredDcNA_sse2; pCtx->pGetIChromaPredFunc[C_PRED_P ] = WelsDecoderIChromaPredPlane_sse2; pCtx->pGetIChromaPredFunc[C_PRED_DC] = WelsDecoderIChromaPredDc_sse2; pCtx->pGetIChromaPredFunc[C_PRED_DC_T] = WelsDecoderIChromaPredDcTop_sse2; pCtx->pGetI4x4LumaPredFunc[I4_PRED_H] = WelsDecoderI4x4LumaPredH_sse2; } #endif DeblockingInit (&pCtx->sDeblockingFunc, pCtx->uiCpuFlag); WelsBlockFuncInit (&pCtx->sBlockFunc, pCtx->uiCpuFlag); } } // namespace WelsDec