ref: e307cbb6a1c426e2dbb23054d02d6ebdaaa559c7
dir: /codec/encoder/core/src/wels_preprocess.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. * */ #if defined(_WIN32) #include <windows.h> #elif defined(MACOS) #include "bundleloader.h" #elif defined(__GNUC__) #include <dlfcn.h> #endif #include <stdio.h> #include <stdlib.h> #include <string.h> #include <assert.h> #include "wels_preprocess.h" #include "memory_align.h" #include "encoder.h" #include "extern.h" #include "picture_handle.h" #include "encoder_context.h" #include "utils.h" #ifdef NO_DYNAMIC_VP EResult WELSAPI CreateVpInterface (void** ppCtx, int iVersion); EResult WELSAPI DestroyVpInterface (void** ppCtx, int iVersion); #endif namespace WelsSVCEnc { #define WelsSafeDelete(p) if(p){ delete (p); (p) = NULL; } //***** entry API declaration ************************************************************************// typedef EResult (WELSAPI* pfnCreateVpInterface) (void**, int); typedef EResult (WELSAPI* pfnDestroyVpInterface) (void*, int); int32_t WelsInitScaledPic (SWelsSvcCodingParam* pParam, Scaled_Picture* pScaledPic, CMemoryAlign* pMemoryAlign); bool_t JudgeNeedOfScaling (SWelsSvcCodingParam* pParam, Scaled_Picture* pScaledPic); void FreeScaledPic (Scaled_Picture* pScaledPic, CMemoryAlign* pMemoryAlign); //******* table definition ***********************************************************************// const uint8_t g_kuiRefTemporalIdx[MAX_TEMPORAL_LEVEL][MAX_GOP_SIZE] = { { 0, }, // 0 { 0, 0, }, // 1 { 0, 0, 0, 1, }, // 2 { 0, 0, 0, 2, 0, 1, 1, 2, }, // 3 { 0, 0, 0, 3, 0, 2, 2, 3, 0, 1, 1, 3, 1, 2, 2, 3 } // 4 }; const int32_t g_kiPixMapSizeInBits = sizeof (uint8_t) * 8; inline void WelsUpdateSpatialIdxMap (sWelsEncCtx* pEncCtx, int32_t iPos, SPicture* pPic, int32_t iDidx) { pEncCtx->sSpatialIndexMap[iPos].pSrc = pPic; pEncCtx->sSpatialIndexMap[iPos].iDid = iDidx; } //***************************************************************************************************// CWelsLib::CWelsLib (void* pEncCtx) { m_pInterface[0] = m_pInterface[1] = NULL; #ifndef NO_DYNAMIC_VP #if defined(_WIN32) const str_t WelsVPLib[] = "welsvp.dll"; HMODULE shModule = LoadLibrary (WelsVPLib); if (!shModule) WelsLog (pEncCtx, WELS_LOG_ERROR, "welsvp load lib dynamic failed module=%x\n", shModule); #elif defined(MACOS) const str_t WelsVPLib[] = "welsvp.bundle"; str_t pCurPath[256]; GetCurrentModulePath (pCurPath, 256); strlcat (pCurPath, WelsVPLib, 256); CFBundleRef shModule = LoadBundle (pCurPath); if (!shModule) WelsLog (pEncCtx, WELS_LOG_ERROR, "welsvp load lib dynamic failed module=%x\n", shModule); #elif defined(__GNUC__) const str_t WelsVPLib[] = "./libwelsvp.so"; void* shModule = NULL; shModule = dlopen (WelsVPLib, RTLD_LAZY); if (shModule == NULL) printf ("dlopen %s iRet=%x, err=%s\n", WelsVPLib, shModule, dlerror()); #endif m_pVpLib = (void*)shModule; #endif } CWelsLib::~CWelsLib() { #ifndef NO_DYNAMIC_VP if (m_pVpLib) { #if defined(_WIN32) HMODULE shModule = (HMODULE)m_pVpLib; FreeLibrary (shModule); #elif defined(MACOS) CFBundleRef shModule = (CFBundleRef)m_pVpLib; FreeBundle (shModule); #elif defined(__GNUC__) void* shModule = m_pVpLib; dlclose (shModule); #endif m_pVpLib = NULL; } #endif } void* CWelsLib::QueryFunction (const str_t* pName) { void* pFunc = NULL; #ifndef NO_DYNAMIC_VP if (m_pVpLib) { #if defined(_WIN32) HMODULE shModule = (HMODULE)m_pVpLib; pFunc = (void*)GetProcAddress (shModule, pName); #elif defined(MACOS) CFBundleRef shModule = (CFBundleRef)m_pVpLib; pFunc = (void*)GetProcessAddress (shModule, pName); #elif defined(__GNUC__) void* shModule = m_pVpLib; pFunc = (void*)dlsym (shModule, pName); if (pFunc == NULL) printf ("dlsym %s iRet=%p, err=%s\n", shModule, pFunc, dlerror()); #endif } #endif return pFunc; } int32_t CWelsLib::CreateIface (void** ppEncCtx) { #ifndef NO_DYNAMIC_VP if (m_pVpLib) { #endif pfnCreateVpInterface pCreateVpInterface = NULL; pfnDestroyVpInterface pDestroyVpInterface = NULL; #ifndef NO_DYNAMIC_VP pCreateVpInterface = (pfnCreateVpInterface) QueryFunction ("CreateVpInterface"); pDestroyVpInterface = (pfnDestroyVpInterface) QueryFunction ("DestroyVpInterface"); #else pCreateVpInterface = CreateVpInterface; // TODO(ekr@rtfm.com): This cast corrects a signature difference... This is a potential real problem pDestroyVpInterface = (pfnDestroyVpInterface)DestroyVpInterface; #endif m_pInterface[0] = (void*)pCreateVpInterface; m_pInterface[1] = (void*)pDestroyVpInterface; if (m_pInterface[0] && m_pInterface[1]) pCreateVpInterface (ppEncCtx, WELSVP_INTERFACE_VERION); #ifndef NO_DYNAMIC_VP } else { } #endif return ppEncCtx ? 0 : 1; } int32_t CWelsLib::DestroyIface (void* pEncCtx) { if (pEncCtx) { pfnDestroyVpInterface pDestroyVpInterface = (pfnDestroyVpInterface) m_pInterface[1]; if (pDestroyVpInterface) { pDestroyVpInterface (pEncCtx, WELSVP_INTERFACE_VERION); } else { } } return 0; } /*************************************************************************** * * implement of the interface * ***************************************************************************/ CWelsPreProcess::CWelsPreProcess (void* pEncCtx) { m_pInterfaceVp = NULL; m_pEncLib = NULL; m_bInitDone = false; m_bOfficialBranch = FALSE; m_pEncCtx = pEncCtx; memset (&m_sScaledPicture, 0, sizeof (m_sScaledPicture)); } CWelsPreProcess::~CWelsPreProcess() { FreeScaledPic (&m_sScaledPicture, static_cast<sWelsEncCtx*> (m_pEncCtx)->pMemAlign); WelsPreprocessDestroy(); } int32_t CWelsPreProcess::WelsPreprocessCreate() { if (m_pEncLib == NULL && m_pInterfaceVp == NULL) { m_pEncLib = new CWelsLib (m_pEncCtx); if (!m_pEncLib) goto exit; m_pEncLib->CreateIface ((void**)&m_pInterfaceVp); if (!m_pInterfaceVp) goto exit; } else goto exit; return 0; exit: WelsPreprocessDestroy(); return 1; } int32_t CWelsPreProcess::WelsPreprocessDestroy() { if (m_pEncLib) { m_pEncLib->DestroyIface ((void*)m_pInterfaceVp); m_pInterfaceVp = NULL; WelsSafeDelete (m_pEncLib); } return 0; } int32_t CWelsPreProcess::WelsPreprocessReset (void* pCtx) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; int32_t iRet = -1; if (pEncCtx) { FreeScaledPic (&m_sScaledPicture, pEncCtx->pMemAlign); iRet = InitLastSpatialPictures (pEncCtx); iRet = WelsInitScaledPic (pEncCtx->pSvcParam, &m_sScaledPicture, pEncCtx->pMemAlign); } return iRet; } int32_t CWelsPreProcess::WelsPreprocessStep1 (void* pCtx, const SSourcePicture** kppSrcPicList, const int32_t kiConfiguredLayerNum) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pSvcParam = pEncCtx->pSvcParam; int32_t iNumDependencyLayer = (int32_t)pSvcParam->iNumDependencyLayer; int32_t iSpatialNum = 0; if (!m_bInitDone) { if (WelsPreprocessCreate() != 0) return -1; if (WelsPreprocessReset (pEncCtx) != 0) return -1; m_bOfficialBranch = (iNumDependencyLayer != kiConfiguredLayerNum); if (!m_bOfficialBranch && (iNumDependencyLayer == 1)) { // check the input source uiSize to decide if need switch to official branch // NOTICE: the layernum=1 case is confused in official/non-official cases! SSourcePicture** pic_queue = (SSourcePicture**)kppSrcPicList; for (int32_t i = 0; i < iNumDependencyLayer; i++) { if (pSvcParam->sDependencyLayers[i].iFrameWidth != pic_queue[i]->iPicWidth || pSvcParam->sDependencyLayers[i].iFrameHeight != pic_queue[i]->iPicHeight) { m_bOfficialBranch = TRUE; break; } } } m_bInitDone = TRUE; } if (m_pInterfaceVp == NULL) return -1; if (kiConfiguredLayerNum <= 0) return -1; pEncCtx->pVaa->bSceneChangeFlag = pEncCtx->pVaa->bIdrPeriodFlag = false; if (pSvcParam->uiIntraPeriod) pEncCtx->pVaa->bIdrPeriodFlag = (1 + pEncCtx->iFrameIndex >= (int32_t)pSvcParam->uiIntraPeriod) ? true : false; if (m_bOfficialBranch) { // Perform Down Sampling potentially due to application assert (kiConfiguredLayerNum == 1); iSpatialNum = SingleLayerPreprocess (pEncCtx, kppSrcPicList[0], &m_sScaledPicture); } else { // for console each spatial pictures are available there iSpatialNum = kiConfiguredLayerNum; MultiLayerPreprocess (pEncCtx, kppSrcPicList, iSpatialNum); } return iSpatialNum; } int32_t CWelsPreProcess::WelsPreprocessStep3 (void* pCtx, const int32_t kiDidx) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pSvcParam = pEncCtx->pSvcParam; bool_t bNeededMbAq = (pSvcParam->bEnableAdaptiveQuant && (pEncCtx->eSliceType == P_SLICE)); bool_t bCalculateBGD = (pEncCtx->eSliceType == P_SLICE && pSvcParam->bEnableBackgroundDetection); int32_t iCurTemporalIdx = pEncCtx->uiSpatialLayersInTemporal[kiDidx] - 1; int32_t iRefTemporalIdx = (int32_t)g_kuiRefTemporalIdx[pSvcParam->iDecompStages][pEncCtx->iCodingIndex & (pSvcParam->uiGopSize - 1)]; if (pEncCtx->uiTemporalId == 0 && pEncCtx->pLtr[pEncCtx->uiDependencyId].bReceivedT0LostFlag) iRefTemporalIdx = pEncCtx->uiSpatialLayersInTemporal[kiDidx] + pEncCtx->pVaa->uiValidLongTermPicIdx; SPicture* pCurPic = pEncCtx->pSpatialPic[kiDidx][iCurTemporalIdx]; SPicture* pRefPic = pEncCtx->pSpatialPic[kiDidx][iRefTemporalIdx]; { SPicture* pLastPic = m_pLastSpatialPicture[kiDidx][0]; bool_t bCalculateSQDiff = ((pLastPic->pData[0] == pRefPic->pData[0]) && bNeededMbAq); bool_t bCalculateVar = (pSvcParam->iRCMode == RC_MODE1 && pEncCtx->eSliceType == I_SLICE); VaaCalculation (pEncCtx->pVaa, pCurPic, pRefPic, bCalculateSQDiff, bCalculateVar, bCalculateBGD); } if (pSvcParam->bEnableBackgroundDetection) { BackgroundDetection (pEncCtx->pVaa, pCurPic, pRefPic, bCalculateBGD && pRefPic->iPictureType != I_SLICE); } if (bNeededMbAq) { SPicture* pCurPic = m_pLastSpatialPicture[kiDidx][1]; SPicture* pRefPic = m_pLastSpatialPicture[kiDidx][0]; AdaptiveQuantCalculation (pEncCtx->pVaa, pCurPic, pRefPic); } if (pSvcParam->bEnableRc) { AnalyzePictureComplexity (pEncCtx, pCurPic, pRefPic, kiDidx, bCalculateBGD); } WelsExchangeSpatialPictures (&m_pLastSpatialPicture[kiDidx][1], &m_pLastSpatialPicture[kiDidx][0]); return 0; } /* * SingleLayerPreprocess: down sampling if applicable * @return: exact number of spatial layers need to encoder indeed */ int32_t CWelsPreProcess::SingleLayerPreprocess (void* pCtx, const SSourcePicture* kpSrc, Scaled_Picture* pScaledPicture) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pSvcParam = pEncCtx->pSvcParam; int8_t iDependencyId = pSvcParam->iNumDependencyLayer - 1; int32_t iPicturePos = pEncCtx->uiSpatialLayersInTemporal[iDependencyId] - 1; SPicture* pSrcPic = NULL; // large SPicture* pDstPic = NULL; // small SDLayerParam* pDlayerParam = NULL; int32_t iSpatialNum = 0; int32_t iSrcWidth = 0; int32_t iSrcHeight = 0; int32_t iTargetWidth = 0; int32_t iTargetHeight = 0; int32_t iTemporalId = 0; int32_t iActualSpatialLayerNum = 0; pDlayerParam = &pSvcParam->sDependencyLayers[iDependencyId]; iTargetWidth = pDlayerParam->iFrameWidth; iTargetHeight = pDlayerParam->iFrameHeight; iTemporalId = pDlayerParam->uiCodingIdx2TemporalId[pEncCtx->iCodingIndex & (pSvcParam->uiGopSize - 1)]; iSrcWidth = pSvcParam->SUsedPicRect.iWidth; iSrcHeight = pSvcParam->SUsedPicRect.iHeight; pSrcPic = pScaledPicture->pScaledInputPicture ? pScaledPicture->pScaledInputPicture : pEncCtx->pSpatialPic[iDependencyId][iPicturePos]; WelsMoveMemoryWrapper (pSvcParam, pSrcPic, kpSrc, iSrcWidth, iSrcHeight); if (pSvcParam->bEnableDenoise) BilateralDenoising (pSrcPic, iSrcWidth, iSrcHeight); // different scaling in between input picture and dst highest spatial picture. int32_t iShrinkWidth = iSrcWidth; int32_t iShrinkHeight = iSrcHeight; pDstPic = pSrcPic; if (pScaledPicture->pScaledInputPicture) { // for highest downsampling pDstPic = pEncCtx->pSpatialPic[iDependencyId][iPicturePos]; iShrinkWidth = pScaledPicture->iScaledWidth[iDependencyId]; iShrinkHeight = pScaledPicture->iScaledHeight[iDependencyId]; } DownsamplePadding (pSrcPic, pDstPic, iSrcWidth, iSrcHeight, iShrinkWidth, iShrinkHeight, iTargetWidth, iTargetHeight); if (pSvcParam->bEnableSceneChangeDetect && !pEncCtx->pVaa->bIdrPeriodFlag && ! (pEncCtx->iCodingIndex & (pSvcParam->uiGopSize - 1))) { SPicture* pRefPic = pEncCtx->pLtr[iDependencyId].bReceivedT0LostFlag ? pEncCtx->pSpatialPic[iDependencyId][pEncCtx->uiSpatialLayersInTemporal[iDependencyId] + pEncCtx->pVaa->uiValidLongTermPicIdx] : m_pLastSpatialPicture[iDependencyId][0]; pEncCtx->pVaa->bSceneChangeFlag = DetectSceneChange (pDstPic, pRefPic); } for (int32_t i = 0; i < pSvcParam->iNumDependencyLayer; i++) { if (pSvcParam->sDependencyLayers[i].uiCodingIdx2TemporalId[pEncCtx->iCodingIndex & (pSvcParam->uiGopSize - 1)] != INVALID_TEMPORAL_ID) { ++ iActualSpatialLayerNum; } } if (iTemporalId != INVALID_TEMPORAL_ID) { WelsUpdateSpatialIdxMap (pEncCtx, iActualSpatialLayerNum - 1, pDstPic, iDependencyId); ++ iSpatialNum; -- iActualSpatialLayerNum; } m_pLastSpatialPicture[iDependencyId][1] = pEncCtx->pSpatialPic[iDependencyId][iPicturePos]; -- iDependencyId; // generate other spacial layer // pSrc is // -- padded input pic, if downsample should be applied to generate highest layer, [if] block above // -- highest layer, if no downsampling, [else] block above if (pSvcParam->iNumDependencyLayer > 1) { while (iDependencyId >= 0) { pDlayerParam = &pSvcParam->sDependencyLayers[iDependencyId]; iTargetWidth = pDlayerParam->iFrameWidth; iTargetHeight = pDlayerParam->iFrameHeight; iTemporalId = pDlayerParam->uiCodingIdx2TemporalId[pEncCtx->iCodingIndex & (pSvcParam->uiGopSize - 1)]; iPicturePos = pEncCtx->uiSpatialLayersInTemporal[iDependencyId] - 1; // NOT work for CGS, FIXME // spatial layer is able to encode indeed if ((iTemporalId != INVALID_TEMPORAL_ID)) { // down sampling performed if (NULL == pSrcPic) return -1; pDstPic = pEncCtx->pSpatialPic[iDependencyId][iPicturePos]; // small iShrinkWidth = pScaledPicture->iScaledWidth[iDependencyId]; iShrinkHeight = pScaledPicture->iScaledHeight[iDependencyId]; DownsamplePadding (pSrcPic, pDstPic, iSrcWidth, iSrcHeight, iShrinkWidth, iShrinkHeight, iTargetWidth, iTargetHeight); WelsUpdateSpatialIdxMap (pEncCtx, iActualSpatialLayerNum - 1, pDstPic, iDependencyId); -- iActualSpatialLayerNum; ++ iSpatialNum; m_pLastSpatialPicture[iDependencyId][1] = pEncCtx->pSpatialPic[iDependencyId][iPicturePos]; } -- iDependencyId; } } return iSpatialNum; } int32_t CWelsPreProcess::MultiLayerPreprocess (void* pCtx, const SSourcePicture** kppSrcPicList, const int32_t kiSpatialNum) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pSvcParam = pEncCtx->pSvcParam; const SSourcePicture* pSrc = NULL; SPicture* pDstPic = NULL; const int32_t iSpatialLayersCfgCount = pSvcParam->iNumDependencyLayer; // count number of spatial layers to be encoded in cfg int32_t i = 0; int32_t j = -1; do { pSrc = kppSrcPicList[i]; // do not clear j, just let it continue to save complexity do { ++ j; if (pSvcParam->sDependencyLayers[j].iFrameWidth == pSrc->iPicWidth && pSvcParam->sDependencyLayers[j].iFrameHeight == pSrc->iPicHeight) { break; } } while (j < iSpatialLayersCfgCount); assert (j < iSpatialLayersCfgCount); pDstPic = pEncCtx->pSpatialPic[j][pEncCtx->uiSpatialLayersInTemporal[j] - 1]; WelsUpdateSpatialIdxMap (pEncCtx, i, pDstPic, j); WelsMoveMemoryWrapper (pSvcParam, pDstPic, pSrc, pSrc->iPicWidth, pSrc->iPicHeight); if (pSvcParam->bEnableDenoise) BilateralDenoising (pDstPic, pSrc->iPicWidth, pSrc->iPicHeight); m_pLastSpatialPicture[j][1] = pDstPic; ++ i; } while (i < kiSpatialNum); if (pSvcParam->bEnableSceneChangeDetect && (kiSpatialNum == pSvcParam->iNumDependencyLayer) && !pEncCtx->pVaa->bIdrPeriodFlag) { SPicture* pRef = pEncCtx->pLtr[0].bReceivedT0LostFlag ? pEncCtx->pSpatialPic[0][pEncCtx->uiSpatialLayersInTemporal[0] + pEncCtx->pVaa->uiValidLongTermPicIdx] : m_pLastSpatialPicture[0][0]; pEncCtx->pVaa->bSceneChangeFlag = DetectSceneChange (pDstPic, pRef); } return 0; } /*! * \brief Whether input picture need be scaled? */ bool_t JudgeNeedOfScaling (SWelsSvcCodingParam* pParam, Scaled_Picture* pScaledPicture) { const int32_t kiInputPicWidth = pParam->SUsedPicRect.iWidth; const int32_t kiInputPicHeight = pParam->SUsedPicRect.iHeight; const int32_t kiDstPicWidth = pParam->sDependencyLayers[pParam->iNumDependencyLayer - 1].iActualWidth; const int32_t kiDstPicHeight = pParam->sDependencyLayers[pParam->iNumDependencyLayer - 1].iActualHeight; bool_t bNeedDownsampling = true; int32_t iSpatialIdx = pParam->iNumDependencyLayer - 1; if (kiDstPicWidth >= kiInputPicWidth && kiDstPicHeight >= kiInputPicHeight) { iSpatialIdx --; // highest D layer do not need downsampling bNeedDownsampling = false; } for (; iSpatialIdx >= 0; iSpatialIdx --) { SDLayerParam* pCurLayer = &pParam->sDependencyLayers[iSpatialIdx]; int32_t iCurDstWidth = pCurLayer->iActualWidth; int32_t iCurDstHeight = pCurLayer->iActualHeight; int32_t iInputWidthXDstHeight = kiInputPicWidth * iCurDstHeight; int32_t iInputHeightXDstWidth = kiInputPicHeight * iCurDstWidth; if (iInputWidthXDstHeight > iInputHeightXDstWidth) { pScaledPicture->iScaledWidth[iSpatialIdx] = iCurDstWidth; pScaledPicture->iScaledHeight[iSpatialIdx] = iInputHeightXDstWidth / kiInputPicWidth; } else { pScaledPicture->iScaledWidth[iSpatialIdx] = iInputWidthXDstHeight / kiInputPicHeight; pScaledPicture->iScaledHeight[iSpatialIdx] = iCurDstHeight; } } return bNeedDownsampling; } int32_t WelsInitScaledPic (SWelsSvcCodingParam* pParam, Scaled_Picture* pScaledPicture, CMemoryAlign* pMemoryAlign) { bool_t bInputPicNeedScaling = JudgeNeedOfScaling (pParam, pScaledPicture); if (bInputPicNeedScaling) { pScaledPicture->pScaledInputPicture = AllocPicture (pMemoryAlign, pParam->SUsedPicRect.iWidth, pParam->SUsedPicRect.iHeight, false); if (pScaledPicture->pScaledInputPicture == NULL) return -1; } return 0; } void FreeScaledPic (Scaled_Picture* pScaledPicture, CMemoryAlign* pMemoryAlign) { if (pScaledPicture->pScaledInputPicture) { FreePicture (pMemoryAlign, &pScaledPicture->pScaledInputPicture); pScaledPicture->pScaledInputPicture = NULL; } } int32_t CWelsPreProcess::InitLastSpatialPictures (void* pCtx) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pParam = pEncCtx->pSvcParam; const int32_t kiDlayerCount = pParam->iNumDependencyLayer; int32_t iDlayerIndex = 0; for (; iDlayerIndex < kiDlayerCount; iDlayerIndex++) { const int32_t kiLayerInTemporal = pEncCtx->uiSpatialLayersInTemporal[iDlayerIndex]; m_pLastSpatialPicture[iDlayerIndex][0] = pEncCtx->pSpatialPic[iDlayerIndex][kiLayerInTemporal - 2]; m_pLastSpatialPicture[iDlayerIndex][1] = NULL; } for (; iDlayerIndex < MAX_DEPENDENCY_LAYER; iDlayerIndex++) { m_pLastSpatialPicture[iDlayerIndex][0] = m_pLastSpatialPicture[iDlayerIndex][1] = NULL; } return 0; } //*********************************************************************************************************/ int32_t CWelsPreProcess::ColorspaceConvert (SWelsSvcCodingParam* pSvcParam, SPicture* pDstPic, const SSourcePicture* kpSrc, const int32_t kiWidth, const int32_t kiHeight) { return 1; //not support yet } void CWelsPreProcess::BilateralDenoising (SPicture* pSrc, const int32_t kiWidth, const int32_t kiHeight) { int32_t iMethodIdx = METHOD_DENOISE; SPixMap sSrcPixMap = {0}; sSrcPixMap.pPixel[0] = pSrc->pData[0]; sSrcPixMap.pPixel[1] = pSrc->pData[1]; sSrcPixMap.pPixel[2] = pSrc->pData[2]; sSrcPixMap.iSizeInBits = g_kiPixMapSizeInBits; sSrcPixMap.sRect.iRectWidth = kiWidth; sSrcPixMap.sRect.iRectHeight = kiHeight; sSrcPixMap.iStride[0] = pSrc->iLineSize[0]; sSrcPixMap.iStride[1] = pSrc->iLineSize[1]; sSrcPixMap.iStride[2] = pSrc->iLineSize[2]; sSrcPixMap.eFormat = VIDEO_FORMAT_I420; m_pInterfaceVp->Process (iMethodIdx, &sSrcPixMap, NULL); } bool_t CWelsPreProcess::DetectSceneChange (SPicture* pCurPicture, SPicture* pRefPicture) { bool_t bSceneChangeFlag = false; int32_t iMethodIdx = METHOD_SCENE_CHANGE_DETECTION; SSceneChangeResult sSceneChangeDetectResult = {0}; SPixMap sSrcPixMap = {0}; SPixMap sRefPixMap = {0}; sSrcPixMap.pPixel[0] = pCurPicture->pData[0]; sSrcPixMap.iSizeInBits = g_kiPixMapSizeInBits; sSrcPixMap.iStride[0] = pCurPicture->iLineSize[0]; sSrcPixMap.sRect.iRectWidth = pCurPicture->iWidthInPixel; sSrcPixMap.sRect.iRectHeight = pCurPicture->iHeightInPixel; sSrcPixMap.eFormat = VIDEO_FORMAT_I420; sRefPixMap.pPixel[0] = pRefPicture->pData[0]; sRefPixMap.iSizeInBits = g_kiPixMapSizeInBits; sRefPixMap.iStride[0] = pRefPicture->iLineSize[0]; sRefPixMap.sRect.iRectWidth = pRefPicture->iWidthInPixel; sRefPixMap.sRect.iRectHeight = pRefPicture->iHeightInPixel; sRefPixMap.eFormat = VIDEO_FORMAT_I420; int32_t iRet = m_pInterfaceVp->Process (iMethodIdx, &sSrcPixMap, &sRefPixMap); if (iRet == 0) { m_pInterfaceVp->Get (iMethodIdx, (void*)&sSceneChangeDetectResult); bSceneChangeFlag = sSceneChangeDetectResult.bSceneChangeFlag ? true : false; } return bSceneChangeFlag; } int32_t CWelsPreProcess::DownsamplePadding (SPicture* pSrc, SPicture* pDstPic, int32_t iSrcWidth, int32_t iSrcHeight, int32_t iShrinkWidth, int32_t iShrinkHeight, int32_t iTargetWidth, int32_t iTargetHeight) { int32_t iRet = 0; SPixMap sSrcPixMap = {0}; SPixMap sDstPicMap = {0}; sSrcPixMap.pPixel[0] = pSrc->pData[0]; sSrcPixMap.pPixel[1] = pSrc->pData[1]; sSrcPixMap.pPixel[2] = pSrc->pData[2]; sSrcPixMap.iSizeInBits = g_kiPixMapSizeInBits; sSrcPixMap.sRect.iRectWidth = iSrcWidth; sSrcPixMap.sRect.iRectHeight = iSrcHeight; sSrcPixMap.iStride[0] = pSrc->iLineSize[0]; sSrcPixMap.iStride[1] = pSrc->iLineSize[1]; sSrcPixMap.iStride[2] = pSrc->iLineSize[2]; sSrcPixMap.eFormat = VIDEO_FORMAT_I420; if (iSrcWidth != iShrinkWidth || iSrcHeight != iShrinkHeight) { int32_t iMethodIdx = METHOD_DOWNSAMPLE; sDstPicMap.pPixel[0] = pDstPic->pData[0]; sDstPicMap.pPixel[1] = pDstPic->pData[1]; sDstPicMap.pPixel[2] = pDstPic->pData[2]; sDstPicMap.iSizeInBits = g_kiPixMapSizeInBits; sDstPicMap.sRect.iRectWidth = iShrinkWidth; sDstPicMap.sRect.iRectHeight = iShrinkHeight; sDstPicMap.iStride[0] = pDstPic->iLineSize[0]; sDstPicMap.iStride[1] = pDstPic->iLineSize[1]; sDstPicMap.iStride[2] = pDstPic->iLineSize[2]; sDstPicMap.eFormat = VIDEO_FORMAT_I420; iRet = m_pInterfaceVp->Process (iMethodIdx, &sSrcPixMap, &sDstPicMap); } else { memcpy (&sDstPicMap, &sSrcPixMap, sizeof (sDstPicMap)); // confirmed_safe_unsafe_usage } // get rid of odd line iShrinkWidth -= (iShrinkWidth & 1); iShrinkHeight -= (iShrinkHeight & 1); Padding ((uint8_t*)sDstPicMap.pPixel[0], (uint8_t*)sDstPicMap.pPixel[1], (uint8_t*)sDstPicMap.pPixel[2], sDstPicMap.iStride[0], sDstPicMap.iStride[1], iShrinkWidth, iTargetWidth, iShrinkHeight, iTargetHeight); return iRet; } //*********************************************************************************************************/ void CWelsPreProcess::VaaCalculation (SVAAFrameInfo* pVaaInfo, SPicture* pCurPicture, SPicture* pRefPicture, bool_t bCalculateSQDiff, bool_t bCalculateVar, bool_t bCalculateBGD) { pVaaInfo->sVaaCalcInfo.pCurY = pCurPicture->pData[0]; pVaaInfo->sVaaCalcInfo.pRefY = pRefPicture->pData[0]; { int32_t iMethodIdx = METHOD_VAA_STATISTICS; SPixMap sCurPixMap = {0}; SPixMap sRefPixMap = {0}; SVAACalcParam calc_param = {0}; sCurPixMap.pPixel[0] = pCurPicture->pData[0]; sCurPixMap.iSizeInBits = g_kiPixMapSizeInBits; sCurPixMap.sRect.iRectWidth = pCurPicture->iWidthInPixel; sCurPixMap.sRect.iRectHeight = pCurPicture->iHeightInPixel; sCurPixMap.iStride[0] = pCurPicture->iLineSize[0]; sCurPixMap.eFormat = VIDEO_FORMAT_I420; sRefPixMap.pPixel[0] = pRefPicture->pData[0]; sRefPixMap.iSizeInBits = g_kiPixMapSizeInBits; sRefPixMap.sRect.iRectWidth = pRefPicture->iWidthInPixel; sRefPixMap.sRect.iRectHeight = pRefPicture->iHeightInPixel; sRefPixMap.iStride[0] = pRefPicture->iLineSize[0]; sRefPixMap.eFormat = VIDEO_FORMAT_I420; calc_param.iCalcVar = bCalculateVar; calc_param.iCalcBgd = bCalculateBGD; calc_param.iCalcSsd = bCalculateSQDiff; calc_param.pCalcResult = &pVaaInfo->sVaaCalcInfo; m_pInterfaceVp->Set (iMethodIdx, &calc_param); m_pInterfaceVp->Process (iMethodIdx, &sCurPixMap, &sRefPixMap); } } void CWelsPreProcess::BackgroundDetection (SVAAFrameInfo* pVaaInfo, SPicture* pCurPicture, SPicture* pRefPicture, bool_t bDetectFlag) { if (bDetectFlag) { pVaaInfo->iPicWidth = pCurPicture->iWidthInPixel; pVaaInfo->iPicHeight = pCurPicture->iHeightInPixel; pVaaInfo->iPicStride = pCurPicture->iLineSize[0]; pVaaInfo->iPicStrideUV = pCurPicture->iLineSize[1]; pVaaInfo->pCurY = pCurPicture->pData[0]; pVaaInfo->pRefY = pRefPicture->pData[0]; pVaaInfo->pCurU = pCurPicture->pData[1]; pVaaInfo->pRefU = pRefPicture->pData[1]; pVaaInfo->pCurV = pCurPicture->pData[2]; pVaaInfo->pRefV = pRefPicture->pData[2]; int32_t iMethodIdx = METHOD_BACKGROUND_DETECTION; SPixMap sSrcPixMap = {0}; SPixMap sRefPixMap = {0}; SBGDInterface BGDParam = {0}; sSrcPixMap.pPixel[0] = pCurPicture->pData[0]; sSrcPixMap.pPixel[1] = pCurPicture->pData[1]; sSrcPixMap.pPixel[2] = pCurPicture->pData[2]; sSrcPixMap.iSizeInBits = g_kiPixMapSizeInBits; sSrcPixMap.iStride[0] = pCurPicture->iLineSize[0]; sSrcPixMap.iStride[1] = pCurPicture->iLineSize[1]; sSrcPixMap.iStride[2] = pCurPicture->iLineSize[2]; sSrcPixMap.sRect.iRectWidth = pCurPicture->iWidthInPixel; sSrcPixMap.sRect.iRectHeight = pCurPicture->iHeightInPixel; sSrcPixMap.eFormat = VIDEO_FORMAT_I420; sRefPixMap.pPixel[0] = pRefPicture->pData[0]; sRefPixMap.pPixel[1] = pRefPicture->pData[1]; sRefPixMap.pPixel[2] = pRefPicture->pData[2]; sRefPixMap.iSizeInBits = g_kiPixMapSizeInBits; sRefPixMap.iStride[0] = pRefPicture->iLineSize[0]; sRefPixMap.iStride[1] = pRefPicture->iLineSize[1]; sRefPixMap.iStride[2] = pRefPicture->iLineSize[2]; sRefPixMap.sRect.iRectWidth = pRefPicture->iWidthInPixel; sRefPixMap.sRect.iRectHeight = pRefPicture->iHeightInPixel; sRefPixMap.eFormat = VIDEO_FORMAT_I420; BGDParam.pBackgroundMbFlag = pVaaInfo->pVaaBackgroundMbFlag; BGDParam.pCalcRes = & (pVaaInfo->sVaaCalcInfo); m_pInterfaceVp->Set (iMethodIdx, (void*)&BGDParam); m_pInterfaceVp->Process (iMethodIdx, &sSrcPixMap, &sRefPixMap); } else { int32_t iPicWidthInMb = (pCurPicture->iWidthInPixel + 15) >> 4; int32_t iPicHeightInMb = (pCurPicture->iHeightInPixel + 15) >> 4; memset (pVaaInfo->pVaaBackgroundMbFlag, 0, iPicWidthInMb * iPicHeightInMb); } } void CWelsPreProcess::AdaptiveQuantCalculation (SVAAFrameInfo* pVaaInfo, SPicture* pCurPicture, SPicture* pRefPicture) { pVaaInfo->sAdaptiveQuantParam.pCalcResult = & (pVaaInfo->sVaaCalcInfo); pVaaInfo->sAdaptiveQuantParam.dAverMotionTextureIndexToDeltaQp = 0; { int32_t iMethodIdx = METHOD_ADAPTIVE_QUANT; SPixMap pSrc = {0}; SPixMap pRef = {0}; int32_t iRet = 0; pSrc.pPixel[0] = pCurPicture->pData[0]; pSrc.iSizeInBits = g_kiPixMapSizeInBits; pSrc.iStride[0] = pCurPicture->iLineSize[0]; pSrc.sRect.iRectWidth = pCurPicture->iWidthInPixel; pSrc.sRect.iRectHeight = pCurPicture->iHeightInPixel; pSrc.eFormat = VIDEO_FORMAT_I420; pRef.pPixel[0] = pRefPicture->pData[0]; pRef.iSizeInBits = g_kiPixMapSizeInBits; pRef.iStride[0] = pRefPicture->iLineSize[0]; pRef.sRect.iRectWidth = pRefPicture->iWidthInPixel; pRef.sRect.iRectHeight = pRefPicture->iHeightInPixel; pRef.eFormat = VIDEO_FORMAT_I420; iRet = m_pInterfaceVp->Set (iMethodIdx, (void*) & (pVaaInfo->sAdaptiveQuantParam)); iRet = m_pInterfaceVp->Process (iMethodIdx, &pSrc, &pRef); if (iRet == 0) m_pInterfaceVp->Get (iMethodIdx, (void*) & (pVaaInfo->sAdaptiveQuantParam)); } } void CWelsPreProcess::SetRefMbType (void* pCtx, uint32_t** pRefMbTypeArray, int32_t iRefPicType) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; const uint8_t uiTid = pEncCtx->uiTemporalId; const uint8_t uiDid = pEncCtx->uiDependencyId; SRefList* pRefPicLlist = pEncCtx->ppRefPicListExt[uiDid]; SLTRState* pLtr = &pEncCtx->pLtr[uiDid]; uint8_t i = 0; if (pEncCtx->pSvcParam->bEnableLongTermReference && pLtr->bReceivedT0LostFlag && uiTid == 0) { for (i = 0; i < pRefPicLlist->uiLongRefCount; i++) { SPicture* pRef = pRefPicLlist->pLongRefList[i]; if (pRef != NULL && pRef->uiRecieveConfirmed == 1/*RECIEVE_SUCCESS*/) { *pRefMbTypeArray = pRef->uiRefMbType; break; } } } else { for (i = 0; i < pRefPicLlist->uiShortRefCount; i++) { SPicture* pRef = pRefPicLlist->pShortRefList[i]; if (pRef != NULL && pRef->bUsedAsRef && pRef->iFramePoc >= 0 && pRef->uiTemporalId <= uiTid) { *pRefMbTypeArray = pRef->uiRefMbType; break; } } } } void CWelsPreProcess::AnalyzePictureComplexity (void* pCtx, SPicture* pCurPicture, SPicture* pRefPicture, const int32_t kiDependencyId, const bool_t bCalculateBGD) { sWelsEncCtx* pEncCtx = (sWelsEncCtx*)pCtx; SWelsSvcCodingParam* pSvcParam = pEncCtx->pSvcParam; SVAAFrameInfo* pVaaInfo = pEncCtx->pVaa; SComplexityAnalysisParam* sComplexityAnalysisParam = & (pVaaInfo->sComplexityAnalysisParam); SWelsSvcRc* SWelsSvcRc = &pEncCtx->pWelsSvcRc[kiDependencyId]; int32_t iComplexityAnalysisMode = 0; if (pSvcParam->iRCMode == RC_MODE0 && pEncCtx->eSliceType == P_SLICE) { iComplexityAnalysisMode = FRAME_SAD; } else if (pSvcParam->iRCMode == RC_MODE1 && pEncCtx->eSliceType == P_SLICE) { iComplexityAnalysisMode = GOM_SAD; } else if (pSvcParam->iRCMode == RC_MODE1 && pEncCtx->eSliceType == I_SLICE) { iComplexityAnalysisMode = GOM_VAR; } else { return; } sComplexityAnalysisParam->iComplexityAnalysisMode = iComplexityAnalysisMode; sComplexityAnalysisParam->pCalcResult = & (pVaaInfo->sVaaCalcInfo); sComplexityAnalysisParam->pBackgroundMbFlag = pVaaInfo->pVaaBackgroundMbFlag; SetRefMbType (pEncCtx, & (sComplexityAnalysisParam->uiRefMbType), pRefPicture->iPictureType); sComplexityAnalysisParam->iCalcBgd = bCalculateBGD; sComplexityAnalysisParam->iFrameComplexity = 0; memset (SWelsSvcRc->pGomForegroundBlockNum, 0, SWelsSvcRc->iGomSize * sizeof (int32_t)); if (iComplexityAnalysisMode != FRAME_SAD) memset (SWelsSvcRc->pCurrentFrameGomSad, 0, SWelsSvcRc->iGomSize * sizeof (int32_t)); sComplexityAnalysisParam->pGomComplexity = SWelsSvcRc->pCurrentFrameGomSad; sComplexityAnalysisParam->pGomForegroundBlockNum = SWelsSvcRc->pGomForegroundBlockNum; sComplexityAnalysisParam->iMbNumInGom = SWelsSvcRc->iNumberMbGom; { int32_t iMethodIdx = METHOD_COMPLEXITY_ANALYSIS; SPixMap sSrcPixMap = {0}; SPixMap sRefPixMap = {0}; int32_t iRet = 0; sSrcPixMap.pPixel[0] = pCurPicture->pData[0]; sSrcPixMap.iSizeInBits = g_kiPixMapSizeInBits; sSrcPixMap.iStride[0] = pCurPicture->iLineSize[0]; sSrcPixMap.sRect.iRectWidth = pCurPicture->iWidthInPixel; sSrcPixMap.sRect.iRectHeight = pCurPicture->iHeightInPixel; sSrcPixMap.eFormat = VIDEO_FORMAT_I420; sRefPixMap.pPixel[0] = pRefPicture->pData[0]; sRefPixMap.iSizeInBits = g_kiPixMapSizeInBits; sRefPixMap.iStride[0] = pRefPicture->iLineSize[0]; sRefPixMap.sRect.iRectWidth = pRefPicture->iWidthInPixel; sRefPixMap.sRect.iRectHeight = pRefPicture->iHeightInPixel; sRefPixMap.eFormat = VIDEO_FORMAT_I420; iRet = m_pInterfaceVp->Set (iMethodIdx, (void*)sComplexityAnalysisParam); iRet = m_pInterfaceVp->Process (iMethodIdx, &sSrcPixMap, &sRefPixMap); if (iRet == 0) m_pInterfaceVp->Get (iMethodIdx, (void*)sComplexityAnalysisParam); } } void CWelsPreProcess::Padding (uint8_t* pSrcY, uint8_t* pSrcU, uint8_t* pSrcV, int32_t iStrideY, int32_t iStrideUV, int32_t iActualWidth, int32_t iPaddingWidth, int32_t iActualHeight, int32_t iPaddingHeight) { int32_t i; if (iPaddingHeight > iActualHeight) { for (i = iActualHeight; i < iPaddingHeight; i++) { memset (pSrcY + i * iStrideY, 0, iActualWidth); if (! (i & 1)) { memset (pSrcU + i / 2 * iStrideUV, 0x80, iActualWidth / 2); memset (pSrcV + i / 2 * iStrideUV, 0x80, iActualWidth / 2); } } } if (iPaddingWidth > iActualWidth) { for (i = 0; i < iPaddingHeight; i++) { memset (pSrcY + i * iStrideY + iActualWidth, 0, iPaddingWidth - iActualWidth); if (! (i & 1)) { memset (pSrcU + i / 2 * iStrideUV + iActualWidth / 2, 0x80, (iPaddingWidth - iActualWidth) / 2); memset (pSrcV + i / 2 * iStrideUV + iActualWidth / 2, 0x80, (iPaddingWidth - iActualWidth) / 2); } } } } //TODO: may opti later //TODO: not use this func? void* WelsMemcpy (void* dst, const void* kpSrc, uint32_t uiSize) { return ::memcpy (dst, kpSrc, uiSize); } void* WelsMemset (void* p, int32_t val, uint32_t uiSize) { return ::memset (p, val, uiSize); } //i420_to_i420_c void WelsMoveMemory_c (uint8_t* pDstY, uint8_t* pDstU, uint8_t* pDstV, int32_t iDstStrideY, int32_t iDstStrideUV, uint8_t* pSrcY, uint8_t* pSrcU, uint8_t* pSrcV, int32_t iSrcStrideY, int32_t iSrcStrideUV, int32_t iWidth, int32_t iHeight) { int32_t iWidth2 = iWidth >> 1; int32_t iHeight2 = iHeight >> 1; int32_t j; for (j = iHeight; j; j--) { WelsMemcpy (pDstY, pSrcY, iWidth); pDstY += iDstStrideY; pSrcY += iSrcStrideY; } for (j = iHeight2; j; j--) { WelsMemcpy (pDstU, pSrcU, iWidth2); WelsMemcpy (pDstV, pSrcV, iWidth2); pDstU += iDstStrideUV; pDstV += iDstStrideUV; pSrcU += iSrcStrideUV; pSrcV += iSrcStrideUV; } } //vp's padding void VPpadding (uint8_t* pSrcPtr, int32_t iCurWidth, int32_t iTargetWidth, int32_t iCurHeight, int32_t iTargetHeight, int32_t iStride, uint8_t uiStuffValue) { uint8_t* pTmp; if (iTargetWidth > iCurWidth) { pTmp = pSrcPtr + iCurWidth; for (int32_t i = 0; i < iCurHeight; i++) { WelsMemset (pTmp, uiStuffValue, iTargetWidth - iCurWidth); pTmp += iStride; } } if (iTargetHeight > iCurHeight) { pTmp = pSrcPtr + iCurHeight * iStride; for (int32_t i = iCurHeight; i < iTargetHeight; i++) { WelsMemset (pTmp, uiStuffValue, iTargetWidth); pTmp += iStride; } } } void CWelsPreProcess::WelsMoveMemoryWrapper (SWelsSvcCodingParam* pSvcParam, SPicture* pDstPic, const SSourcePicture* kpSrc, const int32_t kiTargetWidth, const int32_t kiTargetHeight) { if (VIDEO_FORMAT_I420 != (kpSrc->iColorFormat & (~VIDEO_FORMAT_VFlip))) return; int32_t iSrcWidth = kpSrc->iPicWidth; int32_t iSrcHeight = kpSrc->iPicHeight; if (iSrcHeight > kiTargetHeight) iSrcHeight = kiTargetHeight; if (iSrcWidth > kiTargetWidth) iSrcWidth = kiTargetWidth; // copy from fr26 to fix the odd uiSize failed issue if (iSrcWidth & 0x1) -- iSrcWidth; if (iSrcHeight & 0x1) -- iSrcHeight; const int32_t kiSrcTopOffsetY = pSvcParam->SUsedPicRect.iTop; const int32_t kiSrcTopOffsetUV = (kiSrcTopOffsetY >> 1); const int32_t kiSrcLeftOffsetY = pSvcParam->SUsedPicRect.iLeft; const int32_t kiSrcLeftOffsetUV = (kiSrcLeftOffsetY >> 1); int32_t iSrcOffset[3] = {0, 0, 0}; iSrcOffset[0] = kpSrc->iStride[0] * kiSrcTopOffsetY + kiSrcLeftOffsetY; iSrcOffset[1] = kpSrc->iStride[1] * kiSrcTopOffsetUV + kiSrcLeftOffsetUV ; iSrcOffset[2] = kpSrc->iStride[2] * kiSrcTopOffsetUV + kiSrcLeftOffsetUV; uint8_t* pSrcY = kpSrc->pData[0] + iSrcOffset[0]; uint8_t* pSrcU = kpSrc->pData[1] + iSrcOffset[1]; uint8_t* pSrcV = kpSrc->pData[2] + iSrcOffset[2]; const int32_t kiSrcStrideY = kpSrc->iStride[0]; const int32_t kiSrcStrideUV = kpSrc->iStride[1]; uint8_t* pDstY = pDstPic->pData[0]; uint8_t* pDstU = pDstPic->pData[1]; uint8_t* pDstV = pDstPic->pData[2]; const int32_t kiDstStrideY = pDstPic->iLineSize[0]; const int32_t kiDstStrideUV = pDstPic->iLineSize[1]; #define MAX_WIDTH (4096) #define MAX_HEIGHT (2304)//MAX_FS_LEVEL51 (36864); MAX_FS_LEVEL51*256/4096 = 2304 if (pSrcY) { if (iSrcWidth <= 0 || iSrcWidth > MAX_WIDTH || iSrcHeight <= 0 || iSrcHeight > MAX_HEIGHT) return; if (kiSrcTopOffsetY >= iSrcHeight || kiSrcLeftOffsetY >= iSrcWidth || iSrcWidth > kiSrcStrideY) return; } if (pDstY) { if (kiTargetWidth <= 0 || kiTargetWidth > MAX_WIDTH || kiTargetHeight <= 0 || kiTargetHeight > MAX_HEIGHT) return; if (kiTargetWidth > kiDstStrideY) return; } if (pSrcY == NULL || pSrcU == NULL || pSrcV == NULL || pDstY == NULL || pDstU == NULL || pDstV == NULL || (iSrcWidth & 1) || (iSrcHeight & 1)) { } else { //i420_to_i420_c WelsMoveMemory_c (pDstY, pDstU, pDstV, kiDstStrideY, kiDstStrideUV, pSrcY, pSrcU, pSrcV, kiSrcStrideY, kiSrcStrideUV, iSrcWidth, iSrcHeight); //in VP Process if (kiTargetWidth > iSrcWidth || kiTargetHeight > iSrcHeight) { const int32_t kiTargetWidthC = (kiTargetWidth >> 1); const int32_t kiTargetHeightC = (kiTargetHeight >> 1); const int32_t kiSrcWidthC = (iSrcWidth >> 1); const int32_t kiSrcHeightC = (iSrcHeight >> 1); // padding pDstPic I420 VPpadding ((uint8_t*)pDstY, iSrcWidth, kiTargetWidth, iSrcHeight, kiTargetHeight, kiDstStrideY, 0); VPpadding ((uint8_t*)pDstU, kiSrcWidthC, kiTargetWidthC, kiSrcHeightC, kiTargetHeightC, kiDstStrideUV, 0x80); VPpadding ((uint8_t*)pDstV, kiSrcWidthC, kiTargetWidthC, kiSrcHeightC, kiTargetHeightC, kiDstStrideUV, 0x80); } } } //*********************************************************************************************************/ } // namespace WelsSVCEnc