ref: 40566f29f05e2ec8dced96f80dbb47ce23a4cff3
dir: /codec/decoder/core/src/error_concealment.cpp/
/*! * \copy * Copyright (c) 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. * * error_concealment.cpp: Wels decoder error concealment implementation */ #include "error_code.h" #include "expand_pic.h" #include "manage_dec_ref.h" #include "copy_mb.h" #include "error_concealment.h" #include "cpu_core.h" namespace WelsDec { //Init void InitErrorCon (PWelsDecoderContext pCtx) { if ((pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_COPY) || (pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_COPY_CROSS_IDR) || (pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_MV_COPY_CROSS_IDR) || (pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_MV_COPY_CROSS_IDR_FREEZE_RES_CHANGE) || (pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_COPY_CROSS_IDR_FREEZE_RES_CHANGE)) { if ((pCtx->pParam->eEcActiveIdc != ERROR_CON_SLICE_MV_COPY_CROSS_IDR_FREEZE_RES_CHANGE) && (pCtx->pParam->eEcActiveIdc != ERROR_CON_SLICE_COPY_CROSS_IDR_FREEZE_RES_CHANGE)) { pCtx->bFreezeOutput = false; } pCtx->sCopyFunc.pCopyLumaFunc = WelsCopy16x16_c; pCtx->sCopyFunc.pCopyChromaFunc = WelsCopy8x8_c; #if defined(X86_ASM) if (pCtx->uiCpuFlag & WELS_CPU_MMXEXT) { pCtx->sCopyFunc.pCopyChromaFunc = WelsCopy8x8_mmx; //aligned } if (pCtx->uiCpuFlag & WELS_CPU_SSE2) { pCtx->sCopyFunc.pCopyLumaFunc = WelsCopy16x16_sse2; //this is aligned copy; } #endif //X86_ASM #if defined(HAVE_NEON) if (pCtx->uiCpuFlag & WELS_CPU_NEON) { pCtx->sCopyFunc.pCopyLumaFunc = WelsCopy16x16_neon; //aligned pCtx->sCopyFunc.pCopyChromaFunc = WelsCopy8x8_neon; //aligned } #endif //HAVE_NEON #if defined(HAVE_NEON_AARCH64) if (pCtx->uiCpuFlag & WELS_CPU_NEON) { pCtx->sCopyFunc.pCopyLumaFunc = WelsCopy16x16_AArch64_neon; //aligned pCtx->sCopyFunc.pCopyChromaFunc = WelsCopy8x8_AArch64_neon; //aligned } #endif //HAVE_NEON_AARCH64 } //TODO add more methods here return; } //Do error concealment using frame copy method void DoErrorConFrameCopy (PWelsDecoderContext pCtx) { PPicture pDstPic = pCtx->pDec; PPicture pSrcPic = pCtx->pPreviousDecodedPictureInDpb; uint32_t uiHeightInPixelY = (pCtx->pSps->iMbHeight) << 4; int32_t iStrideY = pDstPic->iLinesize[0]; int32_t iStrideUV = pDstPic->iLinesize[1]; pCtx->pDec->iMbEcedNum = pCtx->pSps->iMbWidth * pCtx->pSps->iMbHeight; if ((pCtx->pParam->eEcActiveIdc == ERROR_CON_FRAME_COPY) && (pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt.bIdrFlag)) pSrcPic = NULL; //no cross IDR method, should fill in data instead of copy if (pSrcPic == NULL) { //no ref pic, assign specific data to picture memset (pDstPic->pData[0], 128, uiHeightInPixelY * iStrideY); memset (pDstPic->pData[1], 128, (uiHeightInPixelY >> 1) * iStrideUV); memset (pDstPic->pData[2], 128, (uiHeightInPixelY >> 1) * iStrideUV); } else if (pSrcPic == pDstPic) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "DoErrorConFrameCopy()::EC memcpy overlap."); } else { //has ref pic here memcpy (pDstPic->pData[0], pSrcPic->pData[0], uiHeightInPixelY * iStrideY); memcpy (pDstPic->pData[1], pSrcPic->pData[1], (uiHeightInPixelY >> 1) * iStrideUV); memcpy (pDstPic->pData[2], pSrcPic->pData[2], (uiHeightInPixelY >> 1) * iStrideUV); } } //Do error concealment using slice copy method void DoErrorConSliceCopy (PWelsDecoderContext pCtx) { int32_t iMbWidth = (int32_t) pCtx->pSps->iMbWidth; int32_t iMbHeight = (int32_t) pCtx->pSps->iMbHeight; PPicture pDstPic = pCtx->pDec; PPicture pSrcPic = pCtx->pPreviousDecodedPictureInDpb; if ((pCtx->pParam->eEcActiveIdc == ERROR_CON_SLICE_COPY) && (pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt.bIdrFlag)) pSrcPic = NULL; //no cross IDR method, should fill in data instead of copy //uint8_t *pDstData[3], *pSrcData[3]; bool* pMbCorrectlyDecodedFlag = pCtx->pCurDqLayer->pMbCorrectlyDecodedFlag; //Do slice copy late int32_t iMbXyIndex; uint8_t* pSrcData, *pDstData; uint32_t iSrcStride; // = pSrcPic->iLinesize[0]; uint32_t iDstStride = pDstPic->iLinesize[0]; if (pSrcPic == pDstPic) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "DoErrorConSliceCopy()::EC memcpy overlap."); return; } for (int32_t iMbY = 0; iMbY < iMbHeight; ++iMbY) { for (int32_t iMbX = 0; iMbX < iMbWidth; ++iMbX) { iMbXyIndex = iMbY * iMbWidth + iMbX; if (!pMbCorrectlyDecodedFlag[iMbXyIndex]) { pCtx->pDec->iMbEcedNum++; if (pSrcPic != NULL) { iSrcStride = pSrcPic->iLinesize[0]; //Y component pDstData = pDstPic->pData[0] + iMbY * 16 * iDstStride + iMbX * 16; pSrcData = pSrcPic->pData[0] + iMbY * 16 * iSrcStride + iMbX * 16; pCtx->sCopyFunc.pCopyLumaFunc (pDstData, iDstStride, pSrcData, iSrcStride); //U component pDstData = pDstPic->pData[1] + iMbY * 8 * iDstStride / 2 + iMbX * 8; pSrcData = pSrcPic->pData[1] + iMbY * 8 * iSrcStride / 2 + iMbX * 8; pCtx->sCopyFunc.pCopyChromaFunc (pDstData, iDstStride / 2, pSrcData, iSrcStride / 2); //V component pDstData = pDstPic->pData[2] + iMbY * 8 * iDstStride / 2 + iMbX * 8; pSrcData = pSrcPic->pData[2] + iMbY * 8 * iSrcStride / 2 + iMbX * 8; pCtx->sCopyFunc.pCopyChromaFunc (pDstData, iDstStride / 2, pSrcData, iSrcStride / 2); } else { //pSrcPic == NULL //Y component pDstData = pDstPic->pData[0] + iMbY * 16 * iDstStride + iMbX * 16; for (int32_t i = 0; i < 16; ++i) { memset (pDstData, 128, 16); pDstData += iDstStride; } //U component pDstData = pDstPic->pData[1] + iMbY * 8 * iDstStride / 2 + iMbX * 8; for (int32_t i = 0; i < 8; ++i) { memset (pDstData, 128, 8); pDstData += iDstStride / 2; } //V component pDstData = pDstPic->pData[2] + iMbY * 8 * iDstStride / 2 + iMbX * 8; for (int32_t i = 0; i < 8; ++i) { memset (pDstData, 128, 8); pDstData += iDstStride / 2; } } // } //!pMbCorrectlyDecodedFlag[iMbXyIndex] } //iMbX } //iMbY } //Do error concealment using slice MV copy method void DoMbECMvCopy (PWelsDecoderContext pCtx, PPicture pDec, PPicture pRef, int32_t iMbXy, int32_t iMbX, int32_t iMbY, sMCRefMember* pMCRefMem) { if (pDec == pRef) { return; // for protection, shall never go into this logic, error info printed outside. } int16_t iMVs[2]; int32_t iMbXInPix = iMbX << 4; int32_t iMbYInPix = iMbY << 4; int32_t iScale0; int32_t iScale1; uint8_t* pDst[3]; int32_t iCurrPoc = pDec->iFramePoc; pDst[0] = pDec->pData[0] + iMbXInPix + iMbYInPix * pMCRefMem->iDstLineLuma; pDst[1] = pDec->pData[1] + (iMbXInPix >> 1) + (iMbYInPix >> 1) * pMCRefMem->iDstLineChroma; pDst[2] = pDec->pData[2] + (iMbXInPix >> 1) + (iMbYInPix >> 1) * pMCRefMem->iDstLineChroma; if (pDec->bIdrFlag == true || pCtx->pECRefPic[0] == NULL) { uint8_t* pSrcData; //Y component pSrcData = pMCRefMem->pSrcY + iMbY * 16 * pMCRefMem->iSrcLineLuma + iMbX * 16; pCtx->sCopyFunc.pCopyLumaFunc (pDst[0], pMCRefMem->iDstLineLuma, pSrcData, pMCRefMem->iSrcLineLuma); //U component pSrcData = pMCRefMem->pSrcU + iMbY * 8 * pMCRefMem->iSrcLineChroma + iMbX * 8; pCtx->sCopyFunc.pCopyChromaFunc (pDst[1], pMCRefMem->iDstLineChroma, pSrcData, pMCRefMem->iSrcLineChroma); //V component pSrcData = pMCRefMem->pSrcV + iMbY * 8 * pMCRefMem->iSrcLineChroma + iMbX * 8; pCtx->sCopyFunc.pCopyChromaFunc (pDst[2], pMCRefMem->iDstLineChroma, pSrcData, pMCRefMem->iSrcLineChroma); return; } if (pCtx->pECRefPic[0]) { if (pCtx->pECRefPic[0] == pRef) { iMVs[0] = pCtx->iECMVs[0][0]; iMVs[1] = pCtx->iECMVs[0][1]; } else { iScale0 = pCtx->pECRefPic[0]->iFramePoc - iCurrPoc; iScale1 = pRef->iFramePoc - iCurrPoc; iMVs[0] = iScale0 == 0 ? 0 : pCtx->iECMVs[0][0] * iScale1 / iScale0; iMVs[1] = iScale0 == 0 ? 0 : pCtx->iECMVs[0][1] * iScale1 / iScale0; } pMCRefMem->pDstY = pDst[0]; pMCRefMem->pDstU = pDst[1]; pMCRefMem->pDstV = pDst[2]; int32_t iFullMVx = (iMbXInPix << 2) + iMVs[0]; //quarter pixel int32_t iFullMVy = (iMbYInPix << 2) + iMVs[1]; // only use to be output pixels to EC; int32_t iPicWidthLeftLimit = 0; int32_t iPicHeightTopLimit = 0; int32_t iPicWidthRightLimit = pMCRefMem->iPicWidth; int32_t iPicHeightBottomLimit = pMCRefMem->iPicHeight; if (pCtx->pSps->bFrameCroppingFlag) { iPicWidthLeftLimit = 0 + pCtx->sFrameCrop.iLeftOffset * 2; iPicWidthRightLimit = (pMCRefMem->iPicWidth - pCtx->sFrameCrop.iRightOffset * 2); iPicHeightTopLimit = 0 + pCtx->sFrameCrop.iTopOffset * 2; iPicHeightBottomLimit = (pMCRefMem->iPicHeight - pCtx->sFrameCrop.iTopOffset * 2); } // further make sure no need to expand picture int32_t iMinLeftOffset = (iPicWidthLeftLimit + 2) * (1 << 2); int32_t iMaxRightOffset = ((iPicWidthRightLimit - 19) * (1 << 2)); int32_t iMinTopOffset = (iPicHeightTopLimit + 2) * (1 << 2); int32_t iMaxBottomOffset = ((iPicHeightBottomLimit - 19) * (1 << 2)); if (iFullMVx < iMinLeftOffset) { iFullMVx = (iFullMVx >> 2) * (1 << 2); iFullMVx = WELS_MAX (iPicWidthLeftLimit, iFullMVx); } else if (iFullMVx > iMaxRightOffset) { iFullMVx = (iFullMVx >> 2) * (1 << 2); iFullMVx = WELS_MIN (((iPicWidthRightLimit - 17) * (1 << 2)), iFullMVx); } if (iFullMVy < iMinTopOffset) { iFullMVy = (iFullMVy >> 2) * (1 << 2); iFullMVy = WELS_MAX (iPicHeightTopLimit, iFullMVy); } else if (iFullMVy > iMaxBottomOffset) { iFullMVy = (iFullMVy >> 2) * (1 << 2); iFullMVy = WELS_MIN (((iPicHeightBottomLimit - 17) * (1 << 2)), iFullMVy); } iMVs[0] = iFullMVx - (iMbXInPix << 2); iMVs[1] = iFullMVy - (iMbYInPix << 2); BaseMC (pMCRefMem, iMbXInPix, iMbYInPix, &pCtx->sMcFunc, 16, 16, iMVs); } return; } void GetAvilInfoFromCorrectMb (PWelsDecoderContext pCtx) { int32_t iMbWidth = (int32_t) pCtx->pSps->iMbWidth; int32_t iMbHeight = (int32_t) pCtx->pSps->iMbHeight; bool* pMbCorrectlyDecodedFlag = pCtx->pCurDqLayer->pMbCorrectlyDecodedFlag; PDqLayer pCurDqLayer = pCtx->pCurDqLayer; int32_t iInterMbCorrectNum[16]; int32_t iMbXyIndex; int8_t iRefIdx; memset (pCtx->iECMVs, 0, sizeof (int32_t) * 32); memset (pCtx->pECRefPic, 0, sizeof (PPicture) * 16); memset (iInterMbCorrectNum, 0, sizeof (int32_t) * 16); for (int32_t iMbY = 0; iMbY < iMbHeight; ++iMbY) { for (int32_t iMbX = 0; iMbX < iMbWidth; ++iMbX) { iMbXyIndex = iMbY * iMbWidth + iMbX; if (pMbCorrectlyDecodedFlag[iMbXyIndex] && IS_INTER (pCurDqLayer->pMbType[iMbXyIndex])) { int32_t iMBType = pCurDqLayer->pMbType[iMbXyIndex]; switch (iMBType) { case MB_TYPE_SKIP: case MB_TYPE_16x16: iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][0]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][0][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][0][1]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; iInterMbCorrectNum[iRefIdx]++; break; case MB_TYPE_16x8: iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][0]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][0][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][0][1]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; iInterMbCorrectNum[iRefIdx]++; iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][8]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][8][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][8][1]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; iInterMbCorrectNum[iRefIdx]++; break; case MB_TYPE_8x16: iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][0]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][0][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][0][1]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; iInterMbCorrectNum[iRefIdx]++; iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][2]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][2][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][2][1]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; iInterMbCorrectNum[iRefIdx]++; break; case MB_TYPE_8x8: case MB_TYPE_8x8_REF0: { uint32_t iSubMBType; int32_t i, j, iIIdx, iJIdx; for (i = 0; i < 4; i++) { iSubMBType = pCurDqLayer->pSubMbType[iMbXyIndex][i]; iIIdx = ((i >> 1) << 3) + ((i & 1) << 1); iRefIdx = pCurDqLayer->pRefIndex[0][iMbXyIndex][iIIdx]; pCtx->pECRefPic[iRefIdx] = pCtx->sRefPic.pRefList[LIST_0][iRefIdx]; switch (iSubMBType) { case SUB_MB_TYPE_8x8: pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][1]; iInterMbCorrectNum[iRefIdx]++; break; case SUB_MB_TYPE_8x4: pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][1]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + 4][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + 4][1]; iInterMbCorrectNum[iRefIdx] += 2; break; case SUB_MB_TYPE_4x8: pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx][1]; pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + 1][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + 1][1]; iInterMbCorrectNum[iRefIdx] += 2; break; case SUB_MB_TYPE_4x4: { for (j = 0; j < 4; j++) { iJIdx = ((j >> 1) << 2) + (j & 1); pCtx->iECMVs[iRefIdx][0] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + iJIdx][0]; pCtx->iECMVs[iRefIdx][1] += pCurDqLayer->pMv[0][iMbXyIndex][iIIdx + iJIdx][1]; } iInterMbCorrectNum[iRefIdx] += 4; } break; default: break; } } } break; default: break; } } //pMbCorrectlyDecodedFlag[iMbXyIndex] } //iMbX } //iMbY for (int32_t i = 0; i < 16; i++) { if (iInterMbCorrectNum[i]) { pCtx->iECMVs[i][0] = pCtx->iECMVs[i][0] / iInterMbCorrectNum[i]; pCtx->iECMVs[i][1] = pCtx->iECMVs[i][1] / iInterMbCorrectNum[i]; } } } void DoErrorConSliceMVCopy (PWelsDecoderContext pCtx) { int32_t iMbWidth = (int32_t) pCtx->pSps->iMbWidth; int32_t iMbHeight = (int32_t) pCtx->pSps->iMbHeight; PPicture pDstPic = pCtx->pDec; PPicture pSrcPic = pCtx->pPreviousDecodedPictureInDpb; bool* pMbCorrectlyDecodedFlag = pCtx->pCurDqLayer->pMbCorrectlyDecodedFlag; int32_t iMbXyIndex; uint8_t* pDstData; uint32_t iDstStride = pDstPic->iLinesize[0]; sMCRefMember sMCRefMem; if (pSrcPic != NULL) { sMCRefMem.iSrcLineLuma = pSrcPic->iLinesize[0]; sMCRefMem.iSrcLineChroma = pSrcPic->iLinesize[1]; sMCRefMem.pSrcY = pSrcPic->pData[0]; sMCRefMem.pSrcU = pSrcPic->pData[1]; sMCRefMem.pSrcV = pSrcPic->pData[2]; sMCRefMem.iDstLineLuma = pDstPic->iLinesize[0]; sMCRefMem.iDstLineChroma = pDstPic->iLinesize[1]; sMCRefMem.iPicWidth = pDstPic->iWidthInPixel; sMCRefMem.iPicHeight = pDstPic->iHeightInPixel; if (pDstPic == pSrcPic) { // output error info, EC will be ignored in DoMbECMvCopy WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "DoErrorConSliceMVCopy()::EC memcpy overlap."); return; } } for (int32_t iMbY = 0; iMbY < iMbHeight; ++iMbY) { for (int32_t iMbX = 0; iMbX < iMbWidth; ++iMbX) { iMbXyIndex = iMbY * iMbWidth + iMbX; if (!pMbCorrectlyDecodedFlag[iMbXyIndex]) { pCtx->pDec->iMbEcedNum++; if (pSrcPic != NULL) { DoMbECMvCopy (pCtx, pDstPic, pSrcPic, iMbXyIndex, iMbX, iMbY, &sMCRefMem); } else { //pSrcPic == NULL //Y component pDstData = pDstPic->pData[0] + iMbY * 16 * iDstStride + iMbX * 16; for (int32_t i = 0; i < 16; ++i) { memset (pDstData, 128, 16); pDstData += iDstStride; } //U component pDstData = pDstPic->pData[1] + iMbY * 8 * iDstStride / 2 + iMbX * 8; for (int32_t i = 0; i < 8; ++i) { memset (pDstData, 128, 8); pDstData += iDstStride / 2; } //V component pDstData = pDstPic->pData[2] + iMbY * 8 * iDstStride / 2 + iMbX * 8; for (int32_t i = 0; i < 8; ++i) { memset (pDstData, 128, 8); pDstData += iDstStride / 2; } } // } //!pMbCorrectlyDecodedFlag[iMbXyIndex] } //iMbX } //iMbY } //Mark erroneous frame as Ref Pic into DPB int32_t MarkECFrameAsRef (PWelsDecoderContext pCtx) { int32_t iRet = WelsMarkAsRef (pCtx); // Under EC mode, the ERR_INFO_DUPLICATE_FRAME_NUM does not need to be process if (iRet != ERR_NONE) { return iRet; } ExpandReferencingPicture (pCtx->pDec->pData, pCtx->pDec->iWidthInPixel, pCtx->pDec->iHeightInPixel, pCtx->pDec->iLinesize, pCtx->sExpandPicFunc.pfExpandLumaPicture, pCtx->sExpandPicFunc.pfExpandChromaPicture); return ERR_NONE; } bool NeedErrorCon (PWelsDecoderContext pCtx) { bool bNeedEC = false; int32_t iMbNum = pCtx->pSps->iMbWidth * pCtx->pSps->iMbHeight; for (int32_t i = 0; i < iMbNum; ++i) { if (!pCtx->pCurDqLayer->pMbCorrectlyDecodedFlag[i]) { bNeedEC = true; break; } } return bNeedEC; } // ImplementErrorConceal // Do actual error concealment void ImplementErrorCon (PWelsDecoderContext pCtx) { if (ERROR_CON_DISABLE == pCtx->pParam->eEcActiveIdc) { pCtx->iErrorCode |= dsBitstreamError; return; } else if ((ERROR_CON_FRAME_COPY == pCtx->pParam->eEcActiveIdc) || (ERROR_CON_FRAME_COPY_CROSS_IDR == pCtx->pParam->eEcActiveIdc)) { DoErrorConFrameCopy (pCtx); } else if ((ERROR_CON_SLICE_COPY == pCtx->pParam->eEcActiveIdc) || (ERROR_CON_SLICE_COPY_CROSS_IDR == pCtx->pParam->eEcActiveIdc) || (ERROR_CON_SLICE_COPY_CROSS_IDR_FREEZE_RES_CHANGE == pCtx->pParam->eEcActiveIdc)) { DoErrorConSliceCopy (pCtx); } else if ((ERROR_CON_SLICE_MV_COPY_CROSS_IDR == pCtx->pParam->eEcActiveIdc) || (ERROR_CON_SLICE_MV_COPY_CROSS_IDR_FREEZE_RES_CHANGE == pCtx->pParam->eEcActiveIdc)) { GetAvilInfoFromCorrectMb (pCtx); DoErrorConSliceMVCopy (pCtx); } //TODO add other EC methods here in the future pCtx->iErrorCode |= dsDataErrorConcealed; pCtx->pDec->bIsComplete = false; // Set complete flag to false after do EC. } } // namespace WelsDec