ref: 563376df0c45ce1cc26200a36d99526c9943f2ba
dir: /codec/encoder/core/src/encoder_ext.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 encoder_ext.c * * \brief core encoder for SVC * * \date 7/24/2009 Created * ************************************************************************************* */ #include "encoder.h" #include "cpu.h" #include "utils.h" #include "svc_enc_golomb.h" #include "au_set.h" #include "picture_handle.h" #include "svc_base_layer_md.h" #include "svc_encode_slice.h" #include "svc_mode_decision.h" #include "decode_mb_aux.h" #include "deblocking.h" #include "ref_list_mgr_svc.h" #include "ls_defines.h" #include "crt_util_safe_x.h" // Safe CRT routines like utils for cross platforms #include "slice_multi_threading.h" #include "measure_time.h" #include "svc_set_mb_syn.h" namespace WelsEnc { int32_t WelsCodeOnePicPartition (sWelsEncCtx* pCtx, SFrameBSInfo* pFrameBsInfo, SLayerBSInfo* pLayerBsInfo, int32_t* pNalIdxInLayer, int32_t* pLayerSize, int32_t iFirstMbInPartition, // first mb inclusive in partition int32_t iEndMbInPartition, // end mb exclusive in partition int32_t iStartSliceIdx ); int32_t WelsBitRateVerification (SLogContext* pLogCtx, SSpatialLayerConfig* pLayerParam, int32_t iLayerId) { if ((pLayerParam->iSpatialBitrate <= 0) || (static_cast<float> (pLayerParam->iSpatialBitrate) < pLayerParam->fFrameRate)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "Invalid bitrate settings in layer %d, bitrate= %d at FrameRate(%f)", iLayerId, pLayerParam->iSpatialBitrate, pLayerParam->fFrameRate); return ENC_RETURN_UNSUPPORTED_PARA; } // deal with LEVEL_MAX_BR and MAX_BR setting const int32_t iLevelMaxBitrate = (pLayerParam->uiLevelIdc != LEVEL_UNKNOWN) ? (g_ksLevelLimits[pLayerParam->uiLevelIdc - 1].uiMaxBR * CpbBrNalFactor) : UNSPECIFIED_BIT_RATE; const int32_t iLevel52MaxBitrate = g_ksLevelLimits[LEVEL_NUMBER - 1].uiMaxBR * CpbBrNalFactor; if (UNSPECIFIED_BIT_RATE != iLevelMaxBitrate) { if ((pLayerParam->iMaxSpatialBitrate == UNSPECIFIED_BIT_RATE) || (pLayerParam->iMaxSpatialBitrate > iLevel52MaxBitrate)) { pLayerParam->iMaxSpatialBitrate = iLevelMaxBitrate; WelsLog (pLogCtx, WELS_LOG_INFO, "Current MaxSpatialBitrate is invalid (UNSPECIFIED_BIT_RATE or larger than LEVEL5_2) but level setting is valid, set iMaxSpatialBitrate to %d from level (%d)", pLayerParam->iMaxSpatialBitrate, pLayerParam->uiLevelIdc); } else if (pLayerParam->iMaxSpatialBitrate > iLevelMaxBitrate) { ELevelIdc iCurLevel = pLayerParam->uiLevelIdc; WelsAdjustLevel (pLayerParam); WelsLog (pLogCtx, WELS_LOG_INFO, "LevelIdc is changed from (%d) to (%d) according to the iMaxSpatialBitrate(%d)", iCurLevel, pLayerParam->uiLevelIdc, pLayerParam->iMaxSpatialBitrate); } } else if ((pLayerParam->iMaxSpatialBitrate != UNSPECIFIED_BIT_RATE) && (pLayerParam->iMaxSpatialBitrate > iLevel52MaxBitrate)) { // no level limitation, just need to check if iMaxSpatialBitrate is too big from reasonable WelsLog (pLogCtx, WELS_LOG_WARNING, "No LevelIdc setting and iMaxSpatialBitrate (%d) is considered too big to be valid, changed to UNSPECIFIED_BIT_RATE", pLayerParam->iMaxSpatialBitrate); pLayerParam->iMaxSpatialBitrate = UNSPECIFIED_BIT_RATE; } // deal with iSpatialBitrate and iMaxSpatialBitrate setting if (pLayerParam->iMaxSpatialBitrate != UNSPECIFIED_BIT_RATE) { if (pLayerParam->iMaxSpatialBitrate == pLayerParam->iSpatialBitrate) { WelsLog (pLogCtx, WELS_LOG_INFO, "Setting MaxSpatialBitrate (%d) the same at SpatialBitrate (%d) will make the actual bit rate lower than SpatialBitrate", pLayerParam->iMaxSpatialBitrate, pLayerParam->iSpatialBitrate); } else if (pLayerParam->iMaxSpatialBitrate < pLayerParam->iSpatialBitrate) { WelsLog (pLogCtx, WELS_LOG_ERROR, "MaxSpatialBitrate (%d) should be larger than SpatialBitrate (%d), considering it as error setting", pLayerParam->iMaxSpatialBitrate, pLayerParam->iSpatialBitrate); return ENC_RETURN_UNSUPPORTED_PARA; } } return ENC_RETURN_SUCCESS; } void CheckProfileSetting (SLogContext* pLogCtx, SWelsSvcCodingParam* pParam, int32_t iLayer, EProfileIdc uiProfileIdc) { SSpatialLayerConfig* pLayerInfo = &pParam->sSpatialLayers[iLayer]; if (PRO_UNKNOWN == uiProfileIdc) { pLayerInfo->uiProfileIdc = (((iLayer == SPATIAL_LAYER_0) || pParam->bSimulcastAVC) ? PRO_BASELINE : PRO_SCALABLE_BASELINE); } else { pLayerInfo->uiProfileIdc = uiProfileIdc; if ((iLayer == SPATIAL_LAYER_0) && (uiProfileIdc != PRO_BASELINE)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "doesn't support profile(%d), change to baseline profile", uiProfileIdc); pLayerInfo->uiProfileIdc = PRO_BASELINE; } if (iLayer > SPATIAL_LAYER_0) { if (pParam->bSimulcastAVC && (uiProfileIdc != PRO_BASELINE)) { pLayerInfo->uiProfileIdc = PRO_BASELINE; WelsLog (pLogCtx, WELS_LOG_WARNING, "doesn't support profile(%d) with bSimulcastAVC, change to baseline profile", uiProfileIdc); } if ((uiProfileIdc != PRO_BASELINE) || (uiProfileIdc != PRO_SCALABLE_BASELINE)) { pLayerInfo->uiProfileIdc = PRO_BASELINE; WelsLog (pLogCtx, WELS_LOG_WARNING, "doesn't support profile(%d), change to baseline profile", uiProfileIdc); } } } } void CheckLevelSetting (SLogContext* pLogCtx, SWelsSvcCodingParam* pParam, int32_t iLayer, ELevelIdc uiLevelIdc) { SSpatialLayerConfig* pLayerInfo = &pParam->sSpatialLayers[iLayer]; pLayerInfo->uiLevelIdc = uiLevelIdc; if (uiLevelIdc > LEVEL_5_2) { WelsLog (pLogCtx, WELS_LOG_INFO, "change unexpected levelidc(%d) setting to LEVEL_UNKNOWN", pLayerInfo->uiLevelIdc); pLayerInfo->uiLevelIdc = LEVEL_UNKNOWN; } } void CheckReferenceNumSetting (SLogContext* pLogCtx, SWelsSvcCodingParam* pParam, int32_t iNumRef) { int32_t iRefUpperBound = (pParam->iUsageType == CAMERA_VIDEO_REAL_TIME) ? MAX_REFERENCE_PICTURE_COUNT_NUM_CAMERA : MAX_REFERENCE_PICTURE_COUNT_NUM_SCREEN; pParam->iNumRefFrame = iNumRef; if ((iNumRef < MIN_REF_PIC_COUNT) || (iNumRef > iRefUpperBound)) { pParam->iNumRefFrame = AUTO_REF_PIC_COUNT; WelsLog (pLogCtx, WELS_LOG_WARNING, "doesn't support the number of reference frame(%d) change to auto select mode", iNumRef); } } int32_t SliceArgumentValidationFixedSliceMode (SLogContext* pLogCtx, SSliceArgument* pSliceArgument, const RC_MODES kiRCMode, const int32_t kiPicWidth, const int32_t kiPicHeight) { int32_t iCpuCores = 0; int32_t iIdx = 0; const int32_t iMbWidth = (kiPicWidth + 15) >> 4; const int32_t iMbHeight = (kiPicHeight + 15) >> 4; const int32_t iMbNumInFrame = iMbWidth * iMbHeight; bool bSingleMode = false; pSliceArgument->uiSliceSizeConstraint = 0; if (pSliceArgument->uiSliceNum == 0) { WelsCPUFeatureDetect (&iCpuCores); if (0 == iCpuCores) { // cpuid not supported or doesn't expose the number of cores, // use high level system API as followed to detect number of pysical/logic processor iCpuCores = DynamicDetectCpuCores(); } pSliceArgument->uiSliceNum = iCpuCores; } if (pSliceArgument->uiSliceNum <= 1) { WelsLog (pLogCtx, WELS_LOG_INFO, "SliceArgumentValidationFixedSliceMode(), uiSliceNum(%d) you set for SM_FIXEDSLCNUM_SLICE, now turn to SM_SINGLE_SLICE type!", pSliceArgument->uiSliceNum); bSingleMode = true; } // considering the coding efficient and performance, // iCountMbNum constraint by MIN_NUM_MB_PER_SLICE condition of multi-pSlice mode settting if (iMbNumInFrame <= MIN_NUM_MB_PER_SLICE) { WelsLog (pLogCtx, WELS_LOG_INFO, "SliceArgumentValidationFixedSliceMode(), uiSliceNum(%d) you set for SM_FIXEDSLCNUM_SLICE, now turn to SM_SINGLE_SLICE type as CountMbNum less than MIN_NUM_MB_PER_SLICE!", pSliceArgument->uiSliceNum); bSingleMode = true; } if (bSingleMode) { pSliceArgument->uiSliceMode = SM_SINGLE_SLICE; pSliceArgument->uiSliceNum = 1; for (iIdx = 0; iIdx < MAX_SLICES_NUM; iIdx++) { pSliceArgument->uiSliceMbNum[iIdx] = 0; } return ENC_RETURN_SUCCESS; } if (pSliceArgument->uiSliceNum > MAX_SLICES_NUM) { pSliceArgument->uiSliceNum = MAX_SLICES_NUM; WelsLog (pLogCtx, WELS_LOG_WARNING, "SliceArgumentValidationFixedSliceMode(), uiSliceNum exceed MAX_SLICES_NUM! So setting slice num eqaul to MAX_SLICES_NUM(%d)!", pSliceArgument->uiSliceNum); } if (kiRCMode != RC_OFF_MODE) { // multiple slices verify with gom //check uiSliceNum and set uiSliceMbNum with current uiSliceNum if (!GomValidCheckSliceNum (iMbWidth, iMbHeight, &pSliceArgument->uiSliceNum)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "SliceArgumentValidationFixedSliceMode(), unsupported setting with Resolution and uiSliceNum combination under RC on! So uiSliceNum is changed to %d!", pSliceArgument->uiSliceNum); } if (pSliceArgument->uiSliceNum <= 1 || !GomValidCheckSliceMbNum (iMbWidth, iMbHeight, pSliceArgument)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "SliceArgumentValidationFixedSliceMode(), unsupported setting with Resolution and uiSliceNum (%d) combination under RC on! Consider setting single slice with this resolution!", pSliceArgument->uiSliceNum); return ENC_RETURN_UNSUPPORTED_PARA; } } else if (!CheckFixedSliceNumMultiSliceSetting (iMbNumInFrame, pSliceArgument)) { //check uiSliceMbNum with current uiSliceNum WelsLog (pLogCtx, WELS_LOG_ERROR, "SliceArgumentValidationFixedSliceMode(), invalid uiSliceMbNum (%d) settings!,now turn to SM_SINGLE_SLICE type", pSliceArgument->uiSliceMbNum[0]); pSliceArgument->uiSliceMode = SM_SINGLE_SLICE; pSliceArgument->uiSliceNum = 1; for (iIdx = 0; iIdx < MAX_SLICES_NUM; iIdx++) { pSliceArgument->uiSliceMbNum[iIdx] = 0; } } return ENC_RETURN_SUCCESS; } /*! * \brief validate checking in parameter configuration * \pParam pParam SWelsSvcCodingParam* * \return successful - 0; otherwise none 0 for failed */ int32_t ParamValidation (SLogContext* pLogCtx, SWelsSvcCodingParam* pCfg) { const float fEpsn = 0.000001f; int32_t i = 0; assert (pCfg != NULL); if ((pCfg->iUsageType != CAMERA_VIDEO_REAL_TIME) && (pCfg->iUsageType != SCREEN_CONTENT_REAL_TIME)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidation(),Invalid usage type = %d", pCfg->iUsageType); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCfg->iUsageType == SCREEN_CONTENT_REAL_TIME) { if (pCfg->iSpatialLayerNum > 1) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidation(),Invalid the number of Spatial layer(%d)for screen content", pCfg->iSpatialLayerNum); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCfg->bEnableAdaptiveQuant) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidation(), AdaptiveQuant(%d) is not supported yet for screen content, auto turned off", pCfg->bEnableAdaptiveQuant); pCfg->bEnableAdaptiveQuant = false; } if (pCfg->bEnableSceneChangeDetect == false) { pCfg->bEnableSceneChangeDetect = true; WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidation(), screen change detection should be turned on, change bEnableSceneChangeDetect as true"); } } if (pCfg->iSpatialLayerNum > 1) { for (i = pCfg->iSpatialLayerNum - 1; i > 0; i--) { SSpatialLayerConfig* fDlpUp = &pCfg->sSpatialLayers[i]; SSpatialLayerConfig* fDlp = &pCfg->sSpatialLayers[i - 1]; if ((fDlp->iVideoWidth > fDlpUp->iVideoWidth) || (fDlp->iVideoHeight > fDlpUp->iVideoHeight)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidation,Invalid resolution layer(%d) resolution(%d x %d) should be less than the upper spatial layer resolution(%d x %d) ", i, fDlp->iVideoWidth, fDlp->iVideoHeight, fDlpUp->iVideoWidth, fDlpUp->iVideoHeight); return ENC_RETURN_UNSUPPORTED_PARA; } } } if (!CheckInRangeCloseOpen (pCfg->iLoopFilterDisableIdc, DEBLOCKING_IDC_0, DEBLOCKING_IDC_2 + 1) || !CheckInRangeCloseOpen (pCfg->iLoopFilterAlphaC0Offset, DEBLOCKING_OFFSET_MINUS, DEBLOCKING_OFFSET + 1) || !CheckInRangeCloseOpen (pCfg->iLoopFilterBetaOffset, DEBLOCKING_OFFSET_MINUS, DEBLOCKING_OFFSET + 1)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidation, Invalid iLoopFilterDisableIdc(%d) or iLoopFilterAlphaC0Offset(%d) or iLoopFilterBetaOffset(%d)!", pCfg->iLoopFilterDisableIdc, pCfg->iLoopFilterAlphaC0Offset, pCfg->iLoopFilterBetaOffset); return ENC_RETURN_UNSUPPORTED_PARA; } for (i = 0; i < pCfg->iSpatialLayerNum; ++ i) { SSpatialLayerInternal* fDlp = &pCfg->sDependencyLayers[i]; SSpatialLayerConfig* pConfig = &pCfg->sSpatialLayers[i]; if (fDlp->fOutputFrameRate > fDlp->fInputFrameRate || (fDlp->fInputFrameRate >= -fEpsn && fDlp->fInputFrameRate <= fEpsn) || (fDlp->fOutputFrameRate >= -fEpsn && fDlp->fOutputFrameRate <= fEpsn)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "Invalid settings in input frame rate(%.6f) or output frame rate(%.6f) of layer #%d config file..", fDlp->fInputFrameRate, fDlp->fOutputFrameRate, i); return ENC_RETURN_INVALIDINPUT; } if (UINT_MAX == GetLogFactor (fDlp->fOutputFrameRate, fDlp->fInputFrameRate)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "AUTO CORRECT: Invalid settings in input frame rate(%.6f) and output frame rate(%.6f) of layer #%d config file: iResult of output frame rate divided by input frame rate should be power of 2(i.e,in/pOut=2^n). \n Auto correcting Output Framerate to Input Framerate %f!\n", fDlp->fInputFrameRate, fDlp->fOutputFrameRate, i, fDlp->fInputFrameRate); fDlp->fOutputFrameRate = fDlp->fInputFrameRate; pConfig->fFrameRate = fDlp->fOutputFrameRate; } } if ((pCfg->iRCMode != RC_OFF_MODE) && (pCfg->iRCMode != RC_QUALITY_MODE) && (pCfg->iRCMode != RC_BUFFERBASED_MODE) && (pCfg->iRCMode != RC_BITRATE_MODE) && (pCfg->iRCMode != RC_TIMESTAMP_MODE)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidation(),Invalid iRCMode = %d", pCfg->iRCMode); return ENC_RETURN_UNSUPPORTED_PARA; } //bitrate setting validation if (pCfg->iRCMode != RC_OFF_MODE) { int32_t iTotalBitrate = 0; if (pCfg->iTargetBitrate <= 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "Invalid bitrate settings in total configure, bitrate= %d", pCfg->iTargetBitrate); return ENC_RETURN_INVALIDINPUT; } for (i = 0; i < pCfg->iSpatialLayerNum; ++ i) { SSpatialLayerConfig* pSpatialLayer = &pCfg->sSpatialLayers[i]; iTotalBitrate += pSpatialLayer->iSpatialBitrate; if (WelsBitRateVerification (pLogCtx, pSpatialLayer, i) != ENC_RETURN_SUCCESS) return ENC_RETURN_INVALIDINPUT; } if (iTotalBitrate > pCfg->iTargetBitrate) { WelsLog (pLogCtx, WELS_LOG_ERROR, "Invalid settings in bitrate. the sum of each layer bitrate(%d) is larger than total bitrate setting(%d)", iTotalBitrate, pCfg->iTargetBitrate); return ENC_RETURN_INVALIDINPUT; } if ((pCfg->iRCMode == RC_QUALITY_MODE) || (pCfg->iRCMode == RC_BITRATE_MODE) || (pCfg->iRCMode == RC_TIMESTAMP_MODE)) if (!pCfg->bEnableFrameSkip) WelsLog (pLogCtx, WELS_LOG_WARNING, "bEnableFrameSkip = %d,bitrate can't be controlled for RC_QUALITY_MODE,RC_BITRATE_MODE and RC_TIMESTAMP_MODE without enabling skip frame.", pCfg->bEnableFrameSkip); if (pCfg->iRCMode == RC_QUALITY_MODE) { pCfg->iMinQp = GOM_MIN_QP_MODE; pCfg->iMaxQp = GOM_MAX_QP_MODE; } else if (pCfg->iUsageType == SCREEN_CONTENT_REAL_TIME) { pCfg->iMinQp = MIN_SCREEN_QP; pCfg->iMaxQp = MAX_SCREEN_QP; } else { pCfg->iMinQp = WELS_CLIP3 (pCfg->iMinQp , GOM_MIN_QP_MODE, 51); pCfg->iMaxQp = WELS_CLIP3 (pCfg->iMaxQp , 0, 51); if (pCfg->iMaxQp <= pCfg->iMinQp) pCfg->iMaxQp = 51; } } // ref-frames validation if (((pCfg->iUsageType == CAMERA_VIDEO_REAL_TIME) || (pCfg->iUsageType == SCREEN_CONTENT_REAL_TIME)) ? WelsCheckRefFrameLimitationNumRefFirst (pLogCtx, pCfg) : WelsCheckRefFrameLimitationLevelIdcFirst (pLogCtx, pCfg)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsCheckRefFrameLimitation failed"); return ENC_RETURN_INVALIDINPUT; } return ENC_RETURN_SUCCESS; } int32_t ParamValidationExt (SLogContext* pLogCtx, SWelsSvcCodingParam* pCodingParam) { int8_t i = 0; int32_t iIdx = 0; assert (pCodingParam != NULL); if (NULL == pCodingParam) return ENC_RETURN_INVALIDINPUT; if ((pCodingParam->iUsageType != CAMERA_VIDEO_REAL_TIME) && (pCodingParam->iUsageType != SCREEN_CONTENT_REAL_TIME)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(),Invalid usage type = %d", pCodingParam->iUsageType); return ENC_RETURN_UNSUPPORTED_PARA; } if ((pCodingParam->iUsageType == SCREEN_CONTENT_REAL_TIME) && (!pCodingParam->bIsLosslessLink && pCodingParam->bEnableLongTermReference)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), setting lossy link for LTR under screen, which is not supported yet! Auto disabled LTR!"); pCodingParam->bEnableLongTermReference = false; } if (pCodingParam->iSpatialLayerNum < 1 || pCodingParam->iSpatialLayerNum > MAX_DEPENDENCY_LAYER) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), monitor invalid pCodingParam->iSpatialLayerNum: %d!", pCodingParam->iSpatialLayerNum); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCodingParam->iTemporalLayerNum < 1 || pCodingParam->iTemporalLayerNum > MAX_TEMPORAL_LEVEL) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), monitor invalid pCodingParam->iTemporalLayerNum: %d!", pCodingParam->iTemporalLayerNum); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCodingParam->uiGopSize < 1 || pCodingParam->uiGopSize > MAX_GOP_SIZE) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), monitor invalid pCodingParam->uiGopSize: %d!", pCodingParam->uiGopSize); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCodingParam->uiIntraPeriod && pCodingParam->uiIntraPeriod < pCodingParam->uiGopSize) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), uiIntraPeriod(%d) should be not less than that of uiGopSize(%d) or -1 specified!", pCodingParam->uiIntraPeriod, pCodingParam->uiGopSize); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCodingParam->uiIntraPeriod && (pCodingParam->uiIntraPeriod & (pCodingParam->uiGopSize - 1)) != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), uiIntraPeriod(%d) should be multiple of uiGopSize(%d) or -1 specified!", pCodingParam->uiIntraPeriod, pCodingParam->uiGopSize); return ENC_RETURN_UNSUPPORTED_PARA; } //about iMultipleThreadIdc, bDeblockingParallelFlag, iLoopFilterDisableIdc, & uiSliceMode // (1) Single Thread // if (THREAD==1)//single thread // no parallel_deblocking: bDeblockingParallelFlag = 0; // (2) Multi Thread: see uiSliceMode decision if (pCodingParam->iMultipleThreadIdc == 1) { //now is single thread. no parallel deblocking, set flag=0 pCodingParam->bDeblockingParallelFlag = false; } else { pCodingParam->bDeblockingParallelFlag = true; } // eSpsPpsIdStrategy checkings if (pCodingParam->iSpatialLayerNum > 1 && (!pCodingParam->bSimulcastAVC) && (SPS_LISTING & pCodingParam->eSpsPpsIdStrategy)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), eSpsPpsIdStrategy setting (%d) with multiple svc SpatialLayers (%d) not supported! eSpsPpsIdStrategy adjusted to CONSTANT_ID", pCodingParam->eSpsPpsIdStrategy, pCodingParam->iSpatialLayerNum); pCodingParam->eSpsPpsIdStrategy = CONSTANT_ID; } if (pCodingParam->iUsageType == SCREEN_CONTENT_REAL_TIME && (SPS_LISTING & pCodingParam->eSpsPpsIdStrategy)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), eSpsPpsIdStrategy setting (%d) with iUsageType (%d) not supported! eSpsPpsIdStrategy adjusted to CONSTANT_ID", pCodingParam->eSpsPpsIdStrategy, pCodingParam->iUsageType); pCodingParam->eSpsPpsIdStrategy = CONSTANT_ID; } if (pCodingParam->bSimulcastAVC && (SPS_LISTING & pCodingParam->eSpsPpsIdStrategy)) { WelsLog (pLogCtx, WELS_LOG_INFO, "ParamValidationExt(), eSpsPpsIdStrategy(%d) under bSimulcastAVC(%d) not supported yet, adjusted to INCREASING_ID", pCodingParam->eSpsPpsIdStrategy, pCodingParam->bSimulcastAVC); pCodingParam->eSpsPpsIdStrategy = INCREASING_ID; } if (pCodingParam->bSimulcastAVC && pCodingParam->bPrefixNalAddingCtrl) { WelsLog (pLogCtx, WELS_LOG_INFO, "ParamValidationExt(), bSimulcastAVC(%d) is not compatible with bPrefixNalAddingCtrl(%d) true, adjusted bPrefixNalAddingCtrl to false", pCodingParam->eSpsPpsIdStrategy, pCodingParam->bSimulcastAVC); pCodingParam->bPrefixNalAddingCtrl = false; } for (i = 0; i < pCodingParam->iSpatialLayerNum; ++ i) { SSpatialLayerConfig* pSpatialLayer = &pCodingParam->sSpatialLayers[i]; const int32_t kiPicWidth = pSpatialLayer->iVideoWidth; const int32_t kiPicHeight = pSpatialLayer->iVideoHeight; uint32_t iMbWidth = 0; uint32_t iMbHeight = 0; int32_t iMbNumInFrame = 0; uint32_t iMaxSliceNum = MAX_SLICES_NUM; int32_t iReturn = 0; if ((kiPicWidth <= 0) || (kiPicHeight <= 0) || (kiPicWidth * kiPicHeight > (MAX_MBS_PER_FRAME << 8))) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), width > 0, height > 0, width * height <= %d, invalid %d x %d in dependency layer settings!", (MAX_MBS_PER_FRAME << 8), kiPicWidth, kiPicHeight); return ENC_RETURN_UNSUPPORTED_PARA; } if ((kiPicWidth & 0x0F) != 0 || (kiPicHeight & 0x0F) != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), in layer #%d iWidth x iHeight(%d x %d) both should be multiple of 16, can not support with arbitrary size currently!", i, kiPicWidth, kiPicHeight); return ENC_RETURN_UNSUPPORTED_PARA; } if (pSpatialLayer->sSliceArgument.uiSliceMode >= SM_RESERVED) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceMode (%d) settings!", pSpatialLayer->sSliceArgument.uiSliceMode); return ENC_RETURN_UNSUPPORTED_PARA; } if ((pCodingParam->uiMaxNalSize != 0) && (pSpatialLayer->sSliceArgument.uiSliceMode != SM_SIZELIMITED_SLICE)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), current layer %d uiSliceMode (%d) settings may not fulfill MaxNalSize = %d", i, pSpatialLayer->sSliceArgument.uiSliceMode, pCodingParam->uiMaxNalSize); } CheckProfileSetting (pLogCtx, pCodingParam, i, pSpatialLayer->uiProfileIdc); CheckLevelSetting (pLogCtx, pCodingParam, i, pSpatialLayer->uiLevelIdc); //check pSlice settings under multi-pSlice if (kiPicWidth <= 16 && kiPicHeight <= 16) { //only have one MB, set to single_slice pSpatialLayer->sSliceArgument.uiSliceMode = SM_SINGLE_SLICE; } switch (pSpatialLayer->sSliceArgument.uiSliceMode) { case SM_SINGLE_SLICE: pSpatialLayer->sSliceArgument.uiSliceNum = 1; pSpatialLayer->sSliceArgument.uiSliceSizeConstraint = 0; for (iIdx = 0; iIdx < MAX_SLICES_NUM; iIdx++) { pSpatialLayer->sSliceArgument.uiSliceMbNum[iIdx] = 0; } break; case SM_FIXEDSLCNUM_SLICE: { iReturn = SliceArgumentValidationFixedSliceMode (pLogCtx, &pSpatialLayer->sSliceArgument, pCodingParam->iRCMode, kiPicWidth, kiPicHeight); if (iReturn) return ENC_RETURN_UNSUPPORTED_PARA; } break; case SM_RASTER_SLICE: { pSpatialLayer->sSliceArgument.uiSliceSizeConstraint = 0; iMbWidth = (kiPicWidth + 15) >> 4; iMbHeight = (kiPicHeight + 15) >> 4; iMbNumInFrame = iMbWidth * iMbHeight; iMaxSliceNum = MAX_SLICES_NUM; if (pSpatialLayer->sSliceArgument.uiSliceMbNum[0] == 0) { if (iMbHeight > iMaxSliceNum) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceNum (%d) settings more than MAX(%d)!", iMbHeight, MAX_SLICES_NUM); return ENC_RETURN_UNSUPPORTED_PARA; } pSpatialLayer->sSliceArgument.uiSliceNum = iMbHeight; for (uint32_t j = 0; j < iMbHeight; j++) { pSpatialLayer->sSliceArgument.uiSliceMbNum[j] = iMbWidth; } if (!CheckRowMbMultiSliceSetting (iMbWidth, &pSpatialLayer->sSliceArgument)) { // verify interleave mode settings WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceMbNum (%d) settings!", pSpatialLayer->sSliceArgument.uiSliceMbNum[0]); return ENC_RETURN_UNSUPPORTED_PARA; } break; } if (!CheckRasterMultiSliceSetting (iMbNumInFrame, &pSpatialLayer->sSliceArgument)) { // verify interleave mode settings WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceMbNum (%d) settings!", pSpatialLayer->sSliceArgument.uiSliceMbNum[0]); return ENC_RETURN_UNSUPPORTED_PARA; } if (pSpatialLayer->sSliceArgument.uiSliceNum <= 0 || pSpatialLayer->sSliceArgument.uiSliceNum > iMaxSliceNum) { // verify interleave mode settings WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceNum (%d) in SM_RASTER_SLICE settings!", pSpatialLayer->sSliceArgument.uiSliceNum); return ENC_RETURN_UNSUPPORTED_PARA; } if (pSpatialLayer->sSliceArgument.uiSliceNum == 1) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), pSlice setting for SM_RASTER_SLICE now turn to SM_SINGLE_SLICE!"); pSpatialLayer->sSliceArgument.uiSliceMode = SM_SINGLE_SLICE; break; } if ((pCodingParam->iRCMode != RC_OFF_MODE) && pSpatialLayer->sSliceArgument.uiSliceNum > 1) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), WARNING: GOM based RC do not support SM_RASTER_SLICE!"); } // considering the coding efficient and performance, iCountMbNum constraint by MIN_NUM_MB_PER_SLICE condition of multi-pSlice mode settting if (iMbNumInFrame <= MIN_NUM_MB_PER_SLICE) { pSpatialLayer->sSliceArgument.uiSliceMode = SM_SINGLE_SLICE; pSpatialLayer->sSliceArgument.uiSliceNum = 1; break; } } break; case SM_SIZELIMITED_SLICE: { iMbWidth = (kiPicWidth + 15) >> 4; iMbHeight = (kiPicHeight + 15) >> 4; if (pSpatialLayer->sSliceArgument.uiSliceSizeConstraint <= 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid iSliceSize (%d) settings!", pSpatialLayer->sSliceArgument.uiSliceSizeConstraint); return ENC_RETURN_UNSUPPORTED_PARA; } if (pCodingParam->uiMaxNalSize > 0) { if (pCodingParam->uiMaxNalSize < (NAL_HEADER_ADD_0X30BYTES + MAX_MACROBLOCK_SIZE_IN_BYTE)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiMaxNalSize (%d) settings! should be larger than (NAL_HEADER_ADD_0X30BYTES + MAX_MACROBLOCK_SIZE_IN_BYTE)(%d)", pCodingParam->uiMaxNalSize, (NAL_HEADER_ADD_0X30BYTES + MAX_MACROBLOCK_SIZE_IN_BYTE)); return ENC_RETURN_UNSUPPORTED_PARA; } if (pSpatialLayer->sSliceArgument.uiSliceSizeConstraint > (pCodingParam->uiMaxNalSize - NAL_HEADER_ADD_0X30BYTES)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "ParamValidationExt(), slice mode = SM_SIZELIMITED_SLICE, uiSliceSizeConstraint = %d ,uiMaxNalsize = %d, will take uiMaxNalsize!", pSpatialLayer->sSliceArgument.uiSliceSizeConstraint, pCodingParam->uiMaxNalSize); pSpatialLayer->sSliceArgument.uiSliceSizeConstraint = pCodingParam->uiMaxNalSize - NAL_HEADER_ADD_0X30BYTES; } } } break; default: { WelsLog (pLogCtx, WELS_LOG_ERROR, "ParamValidationExt(), invalid uiSliceMode (%d) settings!", pCodingParam->sSpatialLayers[0].sSliceArgument.uiSliceMode); return ENC_RETURN_UNSUPPORTED_PARA; } break; } } return ParamValidation (pLogCtx, pCodingParam); } void WelsEncoderApplyFrameRate (SWelsSvcCodingParam* pParam) { SSpatialLayerInternal* pLayerParamInternal; SSpatialLayerConfig* pLayerParam; const float kfEpsn = 0.000001f; const int32_t kiNumLayer = pParam->iSpatialLayerNum; int32_t i; const float kfMaxFrameRate = pParam->fMaxFrameRate; float fRatio; float fTargetOutputFrameRate; //set input frame rate to each layer for (i = 0; i < kiNumLayer; i++) { pLayerParamInternal = & (pParam->sDependencyLayers[i]); pLayerParam = & (pParam->sSpatialLayers[i]); fRatio = pLayerParamInternal->fOutputFrameRate / pLayerParamInternal->fInputFrameRate; if ((kfMaxFrameRate - pLayerParamInternal->fInputFrameRate) > kfEpsn || (kfMaxFrameRate - pLayerParamInternal->fInputFrameRate) < -kfEpsn) { pLayerParamInternal->fInputFrameRate = kfMaxFrameRate; fTargetOutputFrameRate = kfMaxFrameRate * fRatio; pLayerParamInternal->fOutputFrameRate = (fTargetOutputFrameRate >= 6) ? fTargetOutputFrameRate : (pLayerParamInternal->fInputFrameRate); pLayerParam->fFrameRate = pLayerParamInternal->fOutputFrameRate; //TODO:{Sijia} from design, there is no sense to have temporal layer when under 6fps even with such setting? } } } int32_t WelsEncoderApplyBitRate (SLogContext* pLogCtx, SWelsSvcCodingParam* pParam, int iLayer) { //TODO (Sijia): this is a temporary solution which keep the ratio between layers //but it is also possible to fulfill the bitrate of lower layer first SSpatialLayerConfig* pLayerParam; const int32_t iNumLayers = pParam->iSpatialLayerNum; int32_t i, iOrigTotalBitrate = 0; if (iLayer == SPATIAL_LAYER_ALL) { //read old BR for (i = 0; i < iNumLayers; i++) { iOrigTotalBitrate += pParam->sSpatialLayers[i].iSpatialBitrate; } //write new BR float fRatio = 0.0; for (i = 0; i < iNumLayers; i++) { pLayerParam = & (pParam->sSpatialLayers[i]); fRatio = pLayerParam->iSpatialBitrate / (static_cast<float> (iOrigTotalBitrate)); pLayerParam->iSpatialBitrate = static_cast<int32_t> (pParam->iTargetBitrate * fRatio); if (WelsBitRateVerification (pLogCtx, pLayerParam, i) != ENC_RETURN_SUCCESS) return ENC_RETURN_UNSUPPORTED_PARA; } } else { return WelsBitRateVerification (pLogCtx, & (pParam->sSpatialLayers[iLayer]), iLayer); } return ENC_RETURN_SUCCESS; } int32_t WelsEncoderApplyBitVaryRang (SLogContext* pLogCtx, SWelsSvcCodingParam* pParam, int32_t iRang) { SSpatialLayerConfig* pLayerParam; const int32_t iNumLayers = pParam->iSpatialLayerNum; for (int32_t i = 0; i < iNumLayers; i++) { pLayerParam = & (pParam->sSpatialLayers[i]); pLayerParam->iMaxSpatialBitrate = WELS_MIN ((int) (pLayerParam->iSpatialBitrate * (1 + iRang / 100.0)), pLayerParam->iMaxSpatialBitrate); if (WelsBitRateVerification (pLogCtx, pLayerParam, i) != ENC_RETURN_SUCCESS) return ENC_RETURN_UNSUPPORTED_PARA; WelsLog (pLogCtx, WELS_LOG_INFO, "WelsEncoderApplyBitVaryRang:UpdateMaxBitrate layerId= %d,iMaxSpatialBitrate = %d", i, pLayerParam->iMaxSpatialBitrate); } return ENC_RETURN_SUCCESS; } /*! * \brief acquire count number of layers and NALs based on configurable paramters dependency * \pParam pCtx sWelsEncCtx* * \pParam pParam SWelsSvcCodingParam* * \pParam pCountLayers pointer of count number of layers indeed * \pParam iCountNals pointer of count number of nals indeed * \return 0 - successful; otherwise failed */ static inline int32_t AcquireLayersNals (sWelsEncCtx** ppCtx, SWelsSvcCodingParam* pParam, int32_t* pCountLayers, int32_t* pCountNals) { int32_t iCountNumLayers = 0; int32_t iCountNumNals = 0; int32_t iNumDependencyLayers = 0; int32_t iDIndex = 0; if (NULL == pParam || NULL == ppCtx || NULL == *ppCtx) return 1; iNumDependencyLayers = pParam->iSpatialLayerNum; do { SSpatialLayerConfig* pDLayer = &pParam->sSpatialLayers[iDIndex]; // pDLayer->ptr_cfg = pParam; int32_t iOrgNumNals = iCountNumNals; //Note: Sep. 2010 //Review this part and suggest no change, since the memory over-use //(1) counts little to the overall performance //(2) should not be critial even under mobile case if (SM_SIZELIMITED_SLICE == pDLayer->sSliceArgument.uiSliceMode) { iCountNumNals += MAX_SLICES_NUM; // plus prefix NALs if (iDIndex == 0) iCountNumNals += MAX_SLICES_NUM; // MAX_SLICES_NUM < MAX_LAYER_NUM_OF_FRAME ensured at svc_enc_slice_segment.h if (iCountNumNals - iOrgNumNals > MAX_NAL_UNITS_IN_LAYER) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "AcquireLayersNals(), num_of_slice(%d) > existing slice(%d) at (iDid= %d), max=%d", iCountNumNals, iOrgNumNals, iDIndex, MAX_NAL_UNITS_IN_LAYER); return 1; } } else { /*if ( SM_SINGLE_SLICE != pDLayer->sSliceArgument.uiSliceMode )*/ const int32_t kiNumOfSlice = GetInitialSliceNum ((pDLayer->iVideoWidth + 0x0f) >> 4, (pDLayer->iVideoHeight + 0x0f) >> 4, &pDLayer->sSliceArgument); // NEED check iCountNals value in case multiple slices is used iCountNumNals += kiNumOfSlice; // for pSlice VCL NALs // plus prefix NALs if (iDIndex == 0) iCountNumNals += kiNumOfSlice; assert (iCountNumNals - iOrgNumNals <= MAX_NAL_UNITS_IN_LAYER); if (kiNumOfSlice > MAX_SLICES_NUM) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "AcquireLayersNals(), num_of_slice(%d) > MAX_SLICES_NUM(%d) per (iDid= %d, qid= %d) settings!", kiNumOfSlice, MAX_SLICES_NUM, iDIndex, 0); return 1; } } if (iCountNumNals - iOrgNumNals > MAX_NAL_UNITS_IN_LAYER) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "AcquireLayersNals(), num_of_nals(%d) > MAX_NAL_UNITS_IN_LAYER(%d) per (iDid= %d, qid= %d) settings!", (iCountNumNals - iOrgNumNals), MAX_NAL_UNITS_IN_LAYER, iDIndex, 0); return 1; } iCountNumLayers ++; ++ iDIndex; } while (iDIndex < iNumDependencyLayers); if (NULL == (*ppCtx)->pFuncList || NULL == (*ppCtx)->pFuncList->pParametersetStrategy) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "AcquireLayersNals(), pFuncList and pParametersetStrategy needed to be initialized first!"); return 1; } // count parasets iCountNumNals += 1 + iNumDependencyLayers + (iCountNumLayers << 1) + iCountNumLayers // plus iCountNumLayers for reserved application + (*ppCtx)->pFuncList->pParametersetStrategy->GetAllNeededParasetNum(); // to check number of layers / nals / slices dependencies, 12/8/2010 if (iCountNumLayers > MAX_LAYER_NUM_OF_FRAME) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "AcquireLayersNals(), iCountNumLayers(%d) > MAX_LAYER_NUM_OF_FRAME(%d)!", iCountNumLayers, MAX_LAYER_NUM_OF_FRAME); return 1; } if (NULL != pCountLayers) *pCountLayers = iCountNumLayers; if (NULL != pCountNals) *pCountNals = iCountNumNals; return 0; } static void InitMbInfo (sWelsEncCtx* pEnc, SMB* pList, SDqLayer* pLayer, const int32_t kiDlayerId, const int32_t kiMaxMbNum) { int32_t iMbWidth = pLayer->iMbWidth; int32_t iMbHeight = pLayer->iMbHeight; int32_t iIdx; int32_t iMbNum = iMbWidth * iMbHeight; uint32_t uiNeighborAvail; const int32_t kiOffset = (kiDlayerId & 0x01) * kiMaxMbNum; SMVUnitXY (*pLayerMvUnitBlock4x4)[MB_BLOCK4x4_NUM] = (SMVUnitXY (*)[MB_BLOCK4x4_NUM]) ( &pEnc->pMvUnitBlock4x4[MB_BLOCK4x4_NUM * kiOffset]); int8_t (*pLayerRefIndexBlock8x8)[MB_BLOCK8x8_NUM] = (int8_t (*)[MB_BLOCK8x8_NUM]) ( &pEnc->pRefIndexBlock4x4[MB_BLOCK8x8_NUM * kiOffset]); for (iIdx = 0; iIdx < iMbNum; iIdx++) { bool bLeft; bool bTop; bool bLeftTop; bool bRightTop; int32_t iLeftXY, iTopXY, iLeftTopXY, iRightTopXY; uint16_t uiSliceIdc; //[0..65535] > 36864 of LEVEL5.2 pList[iIdx].iMbX = pEnc->pStrideTab->pMbIndexX[kiDlayerId][iIdx]; pList[iIdx].iMbY = pEnc->pStrideTab->pMbIndexY[kiDlayerId][iIdx]; pList[iIdx].iMbXY = iIdx; uiSliceIdc = WelsMbToSliceIdc (pLayer, iIdx); iLeftXY = iIdx - 1; iTopXY = iIdx - iMbWidth; iLeftTopXY = iTopXY - 1; iRightTopXY = iTopXY + 1; bLeft = (pList[iIdx].iMbX > 0) && (uiSliceIdc == WelsMbToSliceIdc (pLayer, iLeftXY)); bTop = (pList[iIdx].iMbY > 0) && (uiSliceIdc == WelsMbToSliceIdc (pLayer, iTopXY)); bLeftTop = (pList[iIdx].iMbX > 0) && (pList[iIdx].iMbY > 0) && (uiSliceIdc == WelsMbToSliceIdc (pLayer, iLeftTopXY)); bRightTop = (pList[iIdx].iMbX < (iMbWidth - 1)) && (pList[iIdx].iMbY > 0) && (uiSliceIdc == WelsMbToSliceIdc (pLayer, iRightTopXY)); uiNeighborAvail = 0; if (bLeft) { uiNeighborAvail |= LEFT_MB_POS; } if (bTop) { uiNeighborAvail |= TOP_MB_POS; } if (bLeftTop) { uiNeighborAvail |= TOPLEFT_MB_POS; } if (bRightTop) { uiNeighborAvail |= TOPRIGHT_MB_POS; } pList[iIdx].uiSliceIdc = uiSliceIdc; // merge from svc_hd_opt_b for multiple slices coding pList[iIdx].uiNeighborAvail = uiNeighborAvail; uiNeighborAvail = 0; if (pList[iIdx].iMbX >= BASE_MV_MB_NMB) uiNeighborAvail |= LEFT_MB_POS; if (pList[iIdx].iMbX <= (iMbWidth - 1 - BASE_MV_MB_NMB)) uiNeighborAvail |= RIGHT_MB_POS; if (pList[iIdx].iMbY >= BASE_MV_MB_NMB) uiNeighborAvail |= TOP_MB_POS; if (pList[iIdx].iMbY <= (iMbHeight - 1 - BASE_MV_MB_NMB)) uiNeighborAvail |= BOTTOM_MB_POS; pList[iIdx].sMv = pLayerMvUnitBlock4x4[iIdx]; pList[iIdx].pRefIndex = pLayerRefIndexBlock8x8[iIdx]; pList[iIdx].pSadCost = &pEnc->pSadCostMb[iIdx]; pList[iIdx].pIntra4x4PredMode = &pEnc->pIntra4x4PredModeBlocks[iIdx * INTRA_4x4_MODE_NUM]; pList[iIdx].pNonZeroCount = &pEnc->pNonZeroCountBlocks[iIdx * MB_LUMA_CHROMA_BLOCK4x4_NUM]; } } int32_t InitMbListD (sWelsEncCtx** ppCtx) { int32_t iNumDlayer = (*ppCtx)->pSvcParam->iSpatialLayerNum; int32_t iMbSize[MAX_DEPENDENCY_LAYER] = { 0 }; int32_t iOverallMbNum = 0; int32_t iMbWidth = 0; int32_t iMbHeight = 0; int32_t i; if (iNumDlayer > MAX_DEPENDENCY_LAYER) return 1; for (i = 0; i < iNumDlayer; i++) { iMbWidth = ((*ppCtx)->pSvcParam->sSpatialLayers[i].iVideoWidth + 15) >> 4; iMbHeight = ((*ppCtx)->pSvcParam->sSpatialLayers[i].iVideoHeight + 15) >> 4; iMbSize[i] = iMbWidth * iMbHeight; iOverallMbNum += iMbSize[i]; } (*ppCtx)->ppMbListD = static_cast<SMB**> ((*ppCtx)->pMemAlign->WelsMallocz (iNumDlayer * sizeof (SMB*), "ppMbListD")); (*ppCtx)->ppMbListD[0] = NULL; WELS_VERIFY_RETURN_PROC_IF (1, (*ppCtx)->ppMbListD == NULL, FreeMemorySvc (ppCtx)); (*ppCtx)->ppMbListD[0] = static_cast<SMB*> ((*ppCtx)->pMemAlign->WelsMallocz (iOverallMbNum * sizeof (SMB), "ppMbListD[0]")); WELS_VERIFY_RETURN_PROC_IF (1, (*ppCtx)->ppMbListD[0] == NULL, FreeMemorySvc (ppCtx)); (*ppCtx)->ppDqLayerList[0]->sMbDataP = (*ppCtx)->ppMbListD[0]; InitMbInfo (*ppCtx, (*ppCtx)->ppMbListD[0], (*ppCtx)->ppDqLayerList[0], 0, iMbSize[iNumDlayer - 1]); for (i = 1; i < iNumDlayer; i++) { (*ppCtx)->ppMbListD[i] = (*ppCtx)->ppMbListD[i - 1] + iMbSize[i - 1]; (*ppCtx)->ppDqLayerList[i]->sMbDataP = (*ppCtx)->ppMbListD[i]; InitMbInfo (*ppCtx, (*ppCtx)->ppMbListD[i], (*ppCtx)->ppDqLayerList[i], i, iMbSize[iNumDlayer - 1]); } return 0; } void FreeSliceInLayer (SDqLayer* pDq, CMemoryAlign* pMa) { int32_t iIdx = 0; FreeSliceBuffer (pDq->sLayerInfo.pSliceInLayer, pDq->iMaxSliceNum, pMa, "pSliceInLayer"); for (; iIdx < MAX_THREADS_NUM; iIdx ++) { FreeSliceBuffer (pDq->sSliceThreadInfo.pSliceInThread[iIdx], pDq->sSliceThreadInfo.iMaxSliceNumInThread[iIdx], pMa, "pSliceInLayer"); } } void FreeDqLayer (SDqLayer*& pDq, CMemoryAlign* pMa) { if (NULL == pDq) { return; } FreeSliceInLayer (pDq, pMa); if (pDq->pNumSliceCodedOfPartition) { pMa->WelsFree (pDq->pNumSliceCodedOfPartition, "pNumSliceCodedOfPartition"); pDq->pNumSliceCodedOfPartition = NULL; } if (pDq->pLastCodedMbIdxOfPartition) { pMa->WelsFree (pDq->pLastCodedMbIdxOfPartition, "pLastCodedMbIdxOfPartition"); pDq->pLastCodedMbIdxOfPartition = NULL; } if (pDq->pLastMbIdxOfPartition) { pMa->WelsFree (pDq->pLastMbIdxOfPartition, "pLastMbIdxOfPartition"); pDq->pLastMbIdxOfPartition = NULL; } if (pDq->pFeatureSearchPreparation) { ReleaseFeatureSearchPreparation (pMa, pDq->pFeatureSearchPreparation->pFeatureOfBlock); pMa->WelsFree (pDq->pFeatureSearchPreparation, "pFeatureSearchPreparation"); pDq->pFeatureSearchPreparation = NULL; } UninitSlicePEncCtx (pDq, pMa); pDq->iMaxSliceNum = 0; pMa->WelsFree (pDq, "pDqLayer"); pDq = NULL; } void FreeRefList (SRefList*& pRefList, CMemoryAlign* pMa, const int iMaxNumRefFrame) { if (NULL == pRefList) { return; } int32_t iRef = 0; do { if (pRefList->pRef[iRef] != NULL) { FreePicture (pMa, &pRefList->pRef[iRef]); } ++ iRef; } while (iRef < 1 + iMaxNumRefFrame); pMa->WelsFree (pRefList, "pRefList"); pRefList = NULL; } static inline int32_t InitSliceList (sWelsEncCtx** ppCtx, SDqLayer* pDqLayer, SSlice* pSliceList, const int32_t kiMaxSliceNum, const int32_t kiDlayerIndex, CMemoryAlign* pMa) { const int32_t kiMBWidth = pDqLayer->iMbWidth; const int32_t kiMBHeight = pDqLayer->iMbHeight; SSliceArgument* pSliceArgument = & (*ppCtx)->pSvcParam->sSpatialLayers[kiDlayerIndex].sSliceArgument; int32_t iMaxSliceBufferSize = (*ppCtx)->iSliceBufferSize[kiDlayerIndex]; int32_t iSliceIdx = 0; int32_t iRet = 0; //SM_SINGLE_SLICE mode using single-thread bs writer pOut->sBsWrite //even though multi-thread is on for other layers bool bIndependenceBsBuffer = ((*ppCtx)->pSvcParam->iMultipleThreadIdc > 1 && SM_SINGLE_SLICE != pSliceArgument->uiSliceMode) ? true : false; if (iMaxSliceBufferSize <= 0 || kiMBWidth <= 0 || kiMBHeight <= 0) { return ENC_RETURN_UNEXPECTED; } while (iSliceIdx < kiMaxSliceNum) { SSlice* pSlice = pSliceList + iSliceIdx; if (NULL == pSlice) return ENC_RETURN_MEMALLOCERR; pSlice->uiSliceIdx = iSliceIdx; iRet = InitSliceBsBuffer (pSlice, & (*ppCtx)->pOut->sBsWrite, bIndependenceBsBuffer, iMaxSliceBufferSize, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; iRet = InitSliceMBInfo (pSliceArgument, pSlice, kiMBWidth, kiMBHeight, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; iRet = AllocateSliceMBBuffer (pSlice, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; ++ iSliceIdx; } return ENC_RETURN_SUCCESS; } static inline int32_t InitSliceThreadInfo (sWelsEncCtx** ppCtx, SDqLayer* pDqLayer, const int32_t kiDlayerIndex, CMemoryAlign* pMa) { SSliceThreadInfo* pSliceThreadInfo = &pDqLayer->sSliceThreadInfo; int32_t iThreadNum = (*ppCtx)->pSvcParam->iMultipleThreadIdc; int32_t iMaxSliceNumInThread = 0; int32_t iIdx = 0; int32_t iRet = 0; assert (iThreadNum > 0); iMaxSliceNumInThread = ((*ppCtx)->iMaxSliceCount / iThreadNum + 1) * 2; iMaxSliceNumInThread = WELS_MIN ((*ppCtx)->iMaxSliceCount, (int) iMaxSliceNumInThread); while (iIdx < iThreadNum) { pSliceThreadInfo->iMaxSliceNumInThread[iIdx] = iMaxSliceNumInThread; pSliceThreadInfo->iEncodedSliceNumInThread[iIdx] = 0; pSliceThreadInfo->pSliceInThread[iIdx] = (SSlice*)pMa->WelsMallocz (sizeof (SSlice) * iMaxSliceNumInThread, "pSliceInThread"); if (NULL == pSliceThreadInfo->pSliceInThread[iIdx]) return ENC_RETURN_MEMALLOCERR; iRet = InitSliceList (ppCtx, pDqLayer, pSliceThreadInfo->pSliceInThread[iIdx], iMaxSliceNumInThread, kiDlayerIndex, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; iIdx++; } for (; iIdx < MAX_THREADS_NUM; iIdx++) { pSliceThreadInfo->iMaxSliceNumInThread[iIdx] = iMaxSliceNumInThread; pSliceThreadInfo->iEncodedSliceNumInThread[iIdx] = 0; pSliceThreadInfo->pSliceInThread[iIdx] = NULL; } return ENC_RETURN_SUCCESS; } static inline int32_t InitSliceInLayer (sWelsEncCtx** ppCtx, SDqLayer* pDqLayer, const int32_t kiDlayerIndex, CMemoryAlign* pMa) { //SWelsSvcCodingParam* pParam = (*ppCtx)->pSvcParam; int32_t iRet = 0; int32_t iMaxSliceNum = pDqLayer->iMaxSliceNum; //if (pParam->iMultipleThreadIdc > 1) { // to do, will add later, slice buffer allocated based on thread mode if() else () InitSliceThreadInfo (ppCtx, pDqLayer, kiDlayerIndex, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; //} else { pDqLayer->sLayerInfo.pSliceInLayer = (SSlice*)pMa->WelsMallocz (sizeof (SSlice) * iMaxSliceNum, "pSliceInLayer"); if (NULL == pDqLayer->sLayerInfo.pSliceInLayer) return ENC_RETURN_MEMALLOCERR; InitSliceList (ppCtx, pDqLayer, pDqLayer->sLayerInfo.pSliceInLayer, iMaxSliceNum, kiDlayerIndex, pMa); if (ENC_RETURN_SUCCESS != iRet) return iRet; //} return ENC_RETURN_SUCCESS; } /*! * \brief initialize ppDqLayerList and slicepEncCtx_list due to count number of layers available * \pParam pCtx sWelsEncCtx* * \return 0 - successful; otherwise failed */ static inline int32_t InitDqLayers (sWelsEncCtx** ppCtx, SExistingParasetList* pExistingParasetList) { SWelsSvcCodingParam* pParam = NULL; SWelsSPS* pSps = NULL; SSubsetSps* pSubsetSps = NULL; SWelsPPS* pPps = NULL; CMemoryAlign* pMa = NULL; int32_t iDlayerCount = 0; int32_t iDlayerIndex = 0; int32_t iSpsId = 0; uint32_t iPpsId = 0; uint32_t iNumRef = 0; int32_t iResult = 0; if (NULL == ppCtx || NULL == *ppCtx) return 1; pMa = (*ppCtx)->pMemAlign; pParam = (*ppCtx)->pSvcParam; iDlayerCount = pParam->iSpatialLayerNum; iNumRef = pParam->iMaxNumRefFrame; const int32_t kiFeatureStrategyIndex = FME_DEFAULT_FEATURE_INDEX; const int32_t kiMe16x16 = ME_DIA_CROSS; const int32_t kiMe8x8 = ME_DIA_CROSS_FME; const int32_t kiNeedFeatureStorage = (pParam->iUsageType != SCREEN_CONTENT_REAL_TIME) ? 0 : ((kiFeatureStrategyIndex << 16) + ((kiMe16x16 & 0x00FF) << 8) + (kiMe8x8 & 0x00FF)); iDlayerIndex = 0; while (iDlayerIndex < iDlayerCount) { SRefList* pRefList = NULL; uint32_t i = 0; const int32_t kiWidth = pParam->sSpatialLayers[iDlayerIndex].iVideoWidth; const int32_t kiHeight = pParam->sSpatialLayers[iDlayerIndex].iVideoHeight; int32_t iPicWidth = WELS_ALIGN (kiWidth, MB_WIDTH_LUMA) + (PADDING_LENGTH << 1); // with iWidth of horizon int32_t iPicChromaWidth = iPicWidth >> 1; iPicWidth = WELS_ALIGN (iPicWidth, 32); // 32(or 16 for chroma below) to match original imp. here instead of iCacheLineSize iPicChromaWidth = WELS_ALIGN (iPicChromaWidth, 16); WelsGetEncBlockStrideOffset ((*ppCtx)->pStrideTab->pStrideEncBlockOffset[iDlayerIndex], iPicWidth, iPicChromaWidth); // pRef list pRefList = (SRefList*)pMa->WelsMallocz (sizeof (SRefList), "pRefList"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == pRefList), FreeMemorySvc (ppCtx)) do { pRefList->pRef[i] = AllocPicture (pMa, kiWidth, kiHeight, true, (iDlayerIndex == iDlayerCount - 1) ? kiNeedFeatureStorage : 0); // to use actual size of current layer WELS_VERIFY_RETURN_PROC_IF (1, (NULL == pRefList->pRef[i]), FreeRefList (pRefList, pMa, iNumRef)) ++ i; } while (i < 1 + iNumRef); pRefList->pNextBuffer = pRefList->pRef[0]; (*ppCtx)->ppRefPicListExt[iDlayerIndex] = pRefList; ++ iDlayerIndex; } iDlayerIndex = 0; while (iDlayerIndex < iDlayerCount) { SDqLayer* pDqLayer = NULL; SSpatialLayerConfig* pDlayer = &pParam->sSpatialLayers[iDlayerIndex]; SSpatialLayerInternal* pParamInternal = &pParam->sDependencyLayers[iDlayerIndex]; const int32_t kiMbW = (pDlayer->iVideoWidth + 0x0f) >> 4; const int32_t kiMbH = (pDlayer->iVideoHeight + 0x0f) >> 4; pParamInternal->iSkipFrameFlag = 0; pParamInternal->iCodingIndex = 0; pParamInternal->iFrameIndex = 0; pParamInternal->iFrameNum = 0; pParamInternal->iPOC = 0; pParamInternal->bEncCurFrmAsIdrFlag = true; // make sure first frame is IDR // pDq layers list pDqLayer = (SDqLayer*)pMa->WelsMallocz (sizeof (SDqLayer), "pDqLayer"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == pDqLayer), FreeDqLayer (pDqLayer, pMa)) // for dynamic slicing mode if (SM_SIZELIMITED_SLICE == pDlayer->sSliceArgument.uiSliceMode) { const int32_t iSize = pParam->iMultipleThreadIdc * sizeof (int32_t); pDqLayer->pNumSliceCodedOfPartition = (int32_t*)pMa->WelsMallocz (iSize, "pNumSliceCodedOfPartition"); pDqLayer->pLastCodedMbIdxOfPartition = (int32_t*)pMa->WelsMallocz (iSize, "pLastCodedMbIdxOfPartition"); pDqLayer->pLastMbIdxOfPartition = (int32_t*)pMa->WelsMallocz (iSize, "pLastMbIdxOfPartition"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == pDqLayer->pNumSliceCodedOfPartition || NULL == pDqLayer->pLastCodedMbIdxOfPartition || NULL == pDqLayer->pLastMbIdxOfPartition), FreeDqLayer (pDqLayer, pMa)) } pDqLayer->bNeedAdjustingSlicing = false; pDqLayer->iMbWidth = kiMbW; pDqLayer->iMbHeight = kiMbH; int32_t iMaxSliceNum = 1; const int32_t kiSliceNum = GetInitialSliceNum (kiMbW, kiMbH, &pDlayer->sSliceArgument); if (iMaxSliceNum < kiSliceNum) iMaxSliceNum = kiSliceNum; pDqLayer->iMaxSliceNum = iMaxSliceNum; iResult = InitSliceInLayer (ppCtx, pDqLayer, iDlayerIndex, pMa); if (iResult) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "InitDqLayers(), InitSliceInLayer failed(%d)!", iResult); FreeDqLayer (pDqLayer, pMa); return iResult; } //deblocking parameters initialization //target-layer deblocking pDqLayer->iLoopFilterDisableIdc = pParam->iLoopFilterDisableIdc; pDqLayer->iLoopFilterAlphaC0Offset = (pParam->iLoopFilterAlphaC0Offset) << 1; pDqLayer->iLoopFilterBetaOffset = (pParam->iLoopFilterBetaOffset) << 1; //parallel deblocking pDqLayer->bDeblockingParallelFlag = pParam->bDeblockingParallelFlag; //deblocking parameter adjustment if (SM_SINGLE_SLICE == pDlayer->sSliceArgument.uiSliceMode) { //iLoopFilterDisableIdc: will be 0 or 1 under single_slice if (2 == pParam->iLoopFilterDisableIdc) { pDqLayer->iLoopFilterDisableIdc = 0; } //bDeblockingParallelFlag pDqLayer->bDeblockingParallelFlag = false; } else { //multi-pSlice if (0 == pDqLayer->iLoopFilterDisableIdc) { pDqLayer->bDeblockingParallelFlag = false; } } // if (kiNeedFeatureStorage && iDlayerIndex == iDlayerCount - 1) { pDqLayer->pFeatureSearchPreparation = static_cast<SFeatureSearchPreparation*> (pMa->WelsMallocz (sizeof ( SFeatureSearchPreparation), "pFeatureSearchPreparation")); WELS_VERIFY_RETURN_PROC_IF (1, NULL == pDqLayer->pFeatureSearchPreparation, FreeMemorySvc (ppCtx)); int32_t iReturn = RequestFeatureSearchPreparation (pMa, pDlayer->iVideoWidth, pDlayer->iVideoHeight, kiNeedFeatureStorage, pDqLayer->pFeatureSearchPreparation); WELS_VERIFY_RETURN_PROC_IF (1, ENC_RETURN_SUCCESS != iReturn, FreeMemorySvc (ppCtx)); } else { pDqLayer->pFeatureSearchPreparation = NULL; } (*ppCtx)->ppDqLayerList[iDlayerIndex] = pDqLayer; ++ iDlayerIndex; } // for dynamically malloc for parameter sets memory instead of maximal items for standard to reduce size, 3/18/2010 WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pFuncList), FreeMemorySvc (ppCtx)) WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pFuncList->pParametersetStrategy), FreeMemorySvc (ppCtx)) const int32_t kiNeededSpsNum = (*ppCtx)->pFuncList->pParametersetStrategy->GetNeededSpsNum(); const int32_t kiNeededSubsetSpsNum = (*ppCtx)->pFuncList->pParametersetStrategy->GetNeededSubsetSpsNum(); (*ppCtx)->pSpsArray = (SWelsSPS*)pMa->WelsMallocz (kiNeededSpsNum * sizeof (SWelsSPS), "pSpsArray"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pSpsArray), FreeMemorySvc (ppCtx)) if (kiNeededSubsetSpsNum > 0) { (*ppCtx)->pSubsetArray = (SSubsetSps*)pMa->WelsMallocz (kiNeededSubsetSpsNum * sizeof (SSubsetSps), "pSubsetArray"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pSubsetArray), FreeMemorySvc (ppCtx)) } else { (*ppCtx)->pSubsetArray = NULL; } // PPS const int32_t kiNeededPpsNum = (*ppCtx)->pFuncList->pParametersetStrategy->GetNeededPpsNum(); (*ppCtx)->pPPSArray = (SWelsPPS*)pMa->WelsMallocz (kiNeededPpsNum * sizeof (SWelsPPS), "pPPSArray"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pPPSArray), FreeMemorySvc (ppCtx)) (*ppCtx)->pFuncList->pParametersetStrategy->LoadPrevious (pExistingParasetList, (*ppCtx)->pSpsArray, (*ppCtx)->pSubsetArray, (*ppCtx)->pPPSArray); (*ppCtx)->pDqIdcMap = (SDqIdc*)pMa->WelsMallocz (iDlayerCount * sizeof (SDqIdc), "pDqIdcMap"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pDqIdcMap), FreeMemorySvc (ppCtx)) iDlayerIndex = 0; while (iDlayerIndex < iDlayerCount) { SDqIdc* pDqIdc = & (*ppCtx)->pDqIdcMap[iDlayerIndex]; const bool bUseSubsetSps = (!pParam->bSimulcastAVC) && (iDlayerIndex > BASE_DEPENDENCY_ID); SSpatialLayerConfig* pDlayerParam = &pParam->sSpatialLayers[iDlayerIndex]; bool bSvcBaselayer = (!pParam->bSimulcastAVC) && (iDlayerCount > BASE_DEPENDENCY_ID) && (iDlayerIndex == BASE_DEPENDENCY_ID); pDqIdc->uiSpatialId = iDlayerIndex; iSpsId = (*ppCtx)->pFuncList->pParametersetStrategy->GenerateNewSps (*ppCtx, bUseSubsetSps, iDlayerIndex, iDlayerCount, iSpsId, pSps, pSubsetSps, bSvcBaselayer); WELS_VERIFY_RETURN_IF (ENC_RETURN_UNSUPPORTED_PARA, (0 > iSpsId)) if (!bUseSubsetSps) { pSps = & ((*ppCtx)->pSpsArray[iSpsId]); } else { pSubsetSps = & ((*ppCtx)->pSubsetArray[iSpsId]); } iPpsId = (*ppCtx)->pFuncList->pParametersetStrategy->InitPps ((*ppCtx), iSpsId, pSps, pSubsetSps, iPpsId, true, bUseSubsetSps, pParam->iEntropyCodingModeFlag != 0); pPps = & ((*ppCtx)->pPPSArray[iPpsId]); // Not using FMO in SVC coding so far, come back if need FMO { iResult = InitSlicePEncCtx ((*ppCtx)->ppDqLayerList[iDlayerIndex], (*ppCtx)->pMemAlign, false, pSps->iMbWidth, pSps->iMbHeight, & (pDlayerParam->sSliceArgument), pPps); if (iResult) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "InitDqLayers(), InitSlicePEncCtx failed(%d)!", iResult); FreeMemorySvc (ppCtx); return iResult; } } pDqIdc->iSpsId = iSpsId; pDqIdc->iPpsId = iPpsId; if ((pParam->bSimulcastAVC) || (bUseSubsetSps)) ++ iSpsId; ++ iPpsId; if (bUseSubsetSps) { ++ (*ppCtx)->iSubsetSpsNum; } else { ++ (*ppCtx)->iSpsNum; } ++ (*ppCtx)->iPpsNum; ++ iDlayerIndex; } (*ppCtx)->pFuncList->pParametersetStrategy->UpdateParaSetNum ((*ppCtx)); return ENC_RETURN_SUCCESS; } int32_t AllocStrideTables (sWelsEncCtx** ppCtx, const int32_t kiNumSpatialLayers) { CMemoryAlign* pMa = (*ppCtx)->pMemAlign; SWelsSvcCodingParam* pParam = (*ppCtx)->pSvcParam; SStrideTables* pPtr = NULL; int16_t* pTmpRow = NULL, *pRowX = NULL, *pRowY = NULL, *p = NULL; uint8_t* pBase = NULL; uint8_t* pBaseDec = NULL, *pBaseEnc = NULL, *pBaseMbX = NULL, *pBaseMbY = NULL; struct { int32_t iMbWidth; int32_t iCountMbNum; // count number of SMB in each spatial int32_t iSizeAllMbAlignCache; // cache line size aligned in each spatial } sMbSizeMap[MAX_DEPENDENCY_LAYER] = {{ 0 }}; int32_t iLineSizeY[MAX_DEPENDENCY_LAYER][2] = {{ 0 }}; int32_t iLineSizeUV[MAX_DEPENDENCY_LAYER][2] = {{ 0 }}; int32_t iMapSpatialIdx[MAX_DEPENDENCY_LAYER][2] = {{ 0 }}; int32_t iSizeDec = 0; int32_t iSizeEnc = 0; int32_t iCountLayersNeedCs[2] = {0}; const int32_t kiUnit1Size = 24 * sizeof (int32_t); int32_t iUnit2Size = 0; int32_t iNeedAllocSize = 0; int32_t iRowSize = 0; int16_t iMaxMbWidth = 0; int16_t iMaxMbHeight = 0; int32_t i = 0; int32_t iSpatialIdx = 0; int32_t iTemporalIdx = 0; int32_t iCntTid = 0; if (kiNumSpatialLayers <= 0 || kiNumSpatialLayers > MAX_DEPENDENCY_LAYER) return 1; pPtr = (SStrideTables*)pMa->WelsMallocz (sizeof (SStrideTables), "SStrideTables"); if (NULL == pPtr) return 1; (*ppCtx)->pStrideTab = pPtr; iCntTid = pParam->iTemporalLayerNum > 1 ? 2 : 1; iSpatialIdx = 0; while (iSpatialIdx < kiNumSpatialLayers) { const int32_t kiTmpWidth = (pParam->sSpatialLayers[iSpatialIdx].iVideoWidth + 15) >> 4; const int32_t kiTmpHeight = (pParam->sSpatialLayers[iSpatialIdx].iVideoHeight + 15) >> 4; int32_t iNumMb = kiTmpWidth * kiTmpHeight; sMbSizeMap[iSpatialIdx].iMbWidth = kiTmpWidth; sMbSizeMap[iSpatialIdx].iCountMbNum = iNumMb; iNumMb *= sizeof (int16_t); sMbSizeMap[iSpatialIdx].iSizeAllMbAlignCache = iNumMb; iUnit2Size += iNumMb; ++ iSpatialIdx; } // Adaptive size_cs, size_fdec by implementation dependency iTemporalIdx = 0; while (iTemporalIdx < iCntTid) { const bool kbBaseTemporalFlag = (iTemporalIdx == 0); iSpatialIdx = 0; while (iSpatialIdx < kiNumSpatialLayers) { SSpatialLayerConfig* fDlp = &pParam->sSpatialLayers[iSpatialIdx]; const int32_t kiWidthPad = WELS_ALIGN (fDlp->iVideoWidth, 16) + (PADDING_LENGTH << 1); iLineSizeY[iSpatialIdx][kbBaseTemporalFlag] = WELS_ALIGN (kiWidthPad, 32); iLineSizeUV[iSpatialIdx][kbBaseTemporalFlag] = WELS_ALIGN ((kiWidthPad >> 1), 16); iMapSpatialIdx[iCountLayersNeedCs[kbBaseTemporalFlag]][kbBaseTemporalFlag] = iSpatialIdx; ++ iCountLayersNeedCs[kbBaseTemporalFlag]; ++ iSpatialIdx; } ++ iTemporalIdx; } iSizeDec = kiUnit1Size * (iCountLayersNeedCs[0] + iCountLayersNeedCs[1]); iSizeEnc = kiUnit1Size * kiNumSpatialLayers; iNeedAllocSize = iSizeDec + iSizeEnc + (iUnit2Size << 1); pBase = (uint8_t*)pMa->WelsMallocz (iNeedAllocSize, "pBase"); if (NULL == pBase) { return 1; } pBaseDec = pBase; // iCountLayersNeedCs pBaseEnc = pBaseDec + iSizeDec; // iNumSpatialLayers pBaseMbX = pBaseEnc + iSizeEnc; // iNumSpatialLayers pBaseMbY = pBaseMbX + iUnit2Size; // iNumSpatialLayers iTemporalIdx = 0; while (iTemporalIdx < iCntTid) { const bool kbBaseTemporalFlag = (iTemporalIdx == 0); iSpatialIdx = 0; while (iSpatialIdx < iCountLayersNeedCs[kbBaseTemporalFlag]) { const int32_t kiActualSpatialIdx = iMapSpatialIdx[iSpatialIdx][kbBaseTemporalFlag]; const int32_t kiLumaWidth = iLineSizeY[kiActualSpatialIdx][kbBaseTemporalFlag]; const int32_t kiChromaWidth = iLineSizeUV[kiActualSpatialIdx][kbBaseTemporalFlag]; WelsGetEncBlockStrideOffset ((int32_t*)pBaseDec, kiLumaWidth, kiChromaWidth); pPtr->pStrideDecBlockOffset[kiActualSpatialIdx][kbBaseTemporalFlag] = (int32_t*)pBaseDec; pBaseDec += kiUnit1Size; ++ iSpatialIdx; } ++ iTemporalIdx; } iTemporalIdx = 0; while (iTemporalIdx < iCntTid) { const bool kbBaseTemporalFlag = (iTemporalIdx == 0); iSpatialIdx = 0; while (iSpatialIdx < kiNumSpatialLayers) { int32_t iMatchIndex = 0; bool bInMap = false; bool bMatchFlag = false; i = 0; while (i < iCountLayersNeedCs[kbBaseTemporalFlag]) { const int32_t kiActualIdx = iMapSpatialIdx[i][kbBaseTemporalFlag]; if (kiActualIdx == iSpatialIdx) { bInMap = true; break; } if (!bMatchFlag) { iMatchIndex = kiActualIdx; bMatchFlag = true; } ++ i; } if (bInMap) { ++ iSpatialIdx; continue; } // not in spatial map and assign match one to it pPtr->pStrideDecBlockOffset[iSpatialIdx][kbBaseTemporalFlag] = pPtr->pStrideDecBlockOffset[iMatchIndex][kbBaseTemporalFlag]; ++ iSpatialIdx; } ++ iTemporalIdx; } iSpatialIdx = 0; while (iSpatialIdx < kiNumSpatialLayers) { const int32_t kiAllocMbSize = sMbSizeMap[iSpatialIdx].iSizeAllMbAlignCache; pPtr->pStrideEncBlockOffset[iSpatialIdx] = (int32_t*)pBaseEnc; pPtr->pMbIndexX[iSpatialIdx] = (int16_t*)pBaseMbX; pPtr->pMbIndexY[iSpatialIdx] = (int16_t*)pBaseMbY; pBaseEnc += kiUnit1Size; pBaseMbX += kiAllocMbSize; pBaseMbY += kiAllocMbSize; ++ iSpatialIdx; } while (iSpatialIdx < MAX_DEPENDENCY_LAYER) { pPtr->pStrideDecBlockOffset[iSpatialIdx][0] = NULL; pPtr->pStrideDecBlockOffset[iSpatialIdx][1] = NULL; pPtr->pStrideEncBlockOffset[iSpatialIdx] = NULL; pPtr->pMbIndexX[iSpatialIdx] = NULL; pPtr->pMbIndexY[iSpatialIdx] = NULL; ++ iSpatialIdx; } // initialize pMbIndexX and pMbIndexY tables as below iMaxMbWidth = sMbSizeMap[kiNumSpatialLayers - 1].iMbWidth; iMaxMbWidth = WELS_ALIGN (iMaxMbWidth, 4); // 4 loops for int16_t required introduced as below iRowSize = iMaxMbWidth * sizeof (int16_t); pTmpRow = (int16_t*)pMa->WelsMallocz (iRowSize, "pTmpRow"); if (NULL == pTmpRow) { return 1; } pRowX = pTmpRow; pRowY = pRowX; // initialize pRowX & pRowY i = 0; p = pRowX; while (i < iMaxMbWidth) { *p = i; * (p + 1) = 1 + i; * (p + 2) = 2 + i; * (p + 3) = 3 + i; p += 4; i += 4; } iSpatialIdx = kiNumSpatialLayers; while (--iSpatialIdx >= 0) { int16_t* pMbIndexX = pPtr->pMbIndexX[iSpatialIdx]; const int32_t kiMbWidth = sMbSizeMap[iSpatialIdx].iMbWidth; const int32_t kiMbHeight = sMbSizeMap[iSpatialIdx].iCountMbNum / kiMbWidth; const int32_t kiLineSize = kiMbWidth * sizeof (int16_t); i = 0; while (i < kiMbHeight) { memcpy (pMbIndexX, pRowX, kiLineSize); // confirmed_safe_unsafe_usage pMbIndexX += kiMbWidth; ++ i; } } memset (pRowY, 0, iRowSize); iMaxMbHeight = sMbSizeMap[kiNumSpatialLayers - 1].iCountMbNum / sMbSizeMap[kiNumSpatialLayers - 1].iMbWidth; i = 0; for (;;) { ENFORCE_STACK_ALIGN_1D (int16_t, t, 4, 16) int32_t t32 = 0; int16_t j = 0; for (iSpatialIdx = kiNumSpatialLayers - 1; iSpatialIdx >= 0; -- iSpatialIdx) { const int32_t kiMbWidth = sMbSizeMap[iSpatialIdx].iMbWidth; const int32_t kiMbHeight = sMbSizeMap[iSpatialIdx].iCountMbNum / kiMbWidth; const int32_t kiLineSize = kiMbWidth * sizeof (int16_t); int16_t* pMbIndexY = pPtr->pMbIndexY[iSpatialIdx] + i * kiMbWidth; if (i < kiMbHeight) { memcpy (pMbIndexY, pRowY, kiLineSize); // confirmed_safe_unsafe_usage } } ++ i; if (i >= iMaxMbHeight) break; t32 = i | (i << 16); ST32 (t , t32); ST32 (t + 2, t32); p = pRowY; while (j < iMaxMbWidth) { ST64 (p, LD64 (t)); p += 4; j += 4; } } pMa->WelsFree (pTmpRow, "pTmpRow"); pTmpRow = NULL; return 0; } int32_t RequestMemoryVaaScreen (SVAAFrameInfo* pVaa, CMemoryAlign* pMa, const int32_t iNumRef, const int32_t iCountMax8x8BNum) { SVAAFrameInfoExt* pVaaExt = static_cast<SVAAFrameInfoExt*> (pVaa); pVaaExt->pVaaBlockStaticIdc[0] = (static_cast<uint8_t*> (pMa->WelsMallocz (iNumRef * iCountMax8x8BNum * sizeof ( uint8_t), "pVaa->pVaaBlockStaticIdc[0]"))); if (NULL == pVaaExt->pVaaBlockStaticIdc[0]) { return 1; } for (int32_t idx = 1; idx < iNumRef; idx++) { pVaaExt->pVaaBlockStaticIdc[idx] = pVaaExt->pVaaBlockStaticIdc[idx - 1] + iCountMax8x8BNum; } return 0; } void ReleaseMemoryVaaScreen (SVAAFrameInfo* pVaa, CMemoryAlign* pMa, const int32_t iNumRef) { SVAAFrameInfoExt* pVaaExt = static_cast<SVAAFrameInfoExt*> (pVaa); if (pVaaExt && pMa && pVaaExt->pVaaBlockStaticIdc[0]) { pMa->WelsFree (pVaaExt->pVaaBlockStaticIdc[0], "pVaa->pVaaBlockStaticIdc[0]"); for (int32_t idx = 0; idx < iNumRef; idx++) { pVaaExt->pVaaBlockStaticIdc[idx] = NULL; } } } /*! * \brief request specific memory for SVC * \pParam pEncCtx sWelsEncCtx* * \return successful - 0; otherwise none 0 for failed */ void GetMvMvdRange (SWelsSvcCodingParam* pParam, int32_t& iMvRange, int32_t& iMvdRange) { ELevelIdc iMinLevelIdc = LEVEL_5_2; int32_t iMinMv = 0; int32_t iMaxMv = 0; int32_t iFixMvRange = pParam->iUsageType ? EXPANDED_MV_RANGE : CAMERA_STARTMV_RANGE; int32_t iFixMvdRange = (pParam->iUsageType ? EXPANDED_MVD_RANGE : ((pParam->iSpatialLayerNum == 1) ? CAMERA_MVD_RANGE : CAMERA_HIGHLAYER_MVD_RANGE)); for (int32_t iLayer = 0; iLayer < pParam->iSpatialLayerNum; iLayer++) { if (pParam->sSpatialLayers[iLayer].uiLevelIdc < iMinLevelIdc) iMinLevelIdc = pParam->sSpatialLayers[iLayer].uiLevelIdc; } iMinMv = (g_ksLevelLimits[iMinLevelIdc - 1].iMinVmv) >> 2; iMaxMv = (g_ksLevelLimits[iMinLevelIdc - 1].iMaxVmv) >> 2; iMvRange = WELS_MIN (WELS_ABS (iMinMv), iMaxMv); iMvRange = WELS_MIN (iMvRange, iFixMvRange); iMvdRange = (iMvRange + 1) << 1; iMvdRange = WELS_MIN (iMvdRange, iFixMvdRange); } int32_t RequestMemorySvc (sWelsEncCtx** ppCtx, SExistingParasetList* pExistingParasetList) { SWelsSvcCodingParam* pParam = (*ppCtx)->pSvcParam; CMemoryAlign* pMa = (*ppCtx)->pMemAlign; SSpatialLayerConfig* pFinalSpatial = NULL; int32_t iCountBsLen = 0; int32_t iCountNals = 0; int32_t iMaxPicWidth = 0; int32_t iMaxPicHeight = 0; int32_t iCountMaxMbNum = 0; int32_t iIndex = 0; int32_t iCountLayers = 0; int32_t iResult = 0; float fCompressRatioThr = .5f; const int32_t kiNumDependencyLayers = pParam->iSpatialLayerNum; int32_t iVclLayersBsSizeCount = 0; int32_t iNonVclLayersBsSizeCount = 0; int32_t iTargetSpatialBsSize = 0; if (kiNumDependencyLayers < 1 || kiNumDependencyLayers > MAX_DEPENDENCY_LAYER) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc() failed due to invalid iNumDependencyLayers(%d)!", kiNumDependencyLayers); FreeMemorySvc (ppCtx); return 1; } if (pParam->uiGopSize == 0 || (pParam->uiIntraPeriod && ((pParam->uiIntraPeriod % pParam->uiGopSize) != 0))) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc() failed due to invalid uiIntraPeriod(%d) (=multipler of uiGopSize(%d)!", pParam->uiIntraPeriod, pParam->uiGopSize); FreeMemorySvc (ppCtx); return 1; } pFinalSpatial = &pParam->sSpatialLayers[kiNumDependencyLayers - 1]; iMaxPicWidth = pFinalSpatial->iVideoWidth; iMaxPicHeight = pFinalSpatial->iVideoHeight; iCountMaxMbNum = ((15 + iMaxPicWidth) >> 4) * ((15 + iMaxPicHeight) >> 4); iResult = AcquireLayersNals (ppCtx, pParam, &iCountLayers, &iCountNals); if (iResult) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), AcquireLayersNals failed(%d)!", iResult); FreeMemorySvc (ppCtx); return 1; } const int32_t kiSpsSize = (*ppCtx)->pFuncList->pParametersetStrategy->GetNeededSpsNum() * SPS_BUFFER_SIZE; const int32_t kiPpsSize = (*ppCtx)->pFuncList->pParametersetStrategy->GetNeededPpsNum() * PPS_BUFFER_SIZE; iNonVclLayersBsSizeCount = SSEI_BUFFER_SIZE + kiSpsSize + kiPpsSize; bool bDynamicSlice = false; uint32_t uiMaxSliceNumEstimation = 0; int32_t iSliceBufferSize = 0; int32_t iMaxSliceBufferSize = 0; int32_t iTotalLength = 0; int32_t iLayerBsSize = 0; iIndex = 0; while (iIndex < pParam->iSpatialLayerNum) { SSpatialLayerConfig* fDlp = &pParam->sSpatialLayers[iIndex]; fCompressRatioThr = COMPRESS_RATIO_THR; iLayerBsSize = WELS_ROUND (((3 * fDlp->iVideoWidth * fDlp->iVideoHeight) >> 1) * fCompressRatioThr) + MAX_MACROBLOCK_SIZE_IN_BYTE_x2; iLayerBsSize = WELS_ALIGN (iLayerBsSize, 4); // 4 bytes alinged iVclLayersBsSizeCount += iLayerBsSize; SSliceArgument* pSliceArgument = & (fDlp->sSliceArgument); if (pSliceArgument->uiSliceMode == SM_SIZELIMITED_SLICE) { bDynamicSlice = true; uiMaxSliceNumEstimation = WELS_MIN (AVERSLICENUM_CONSTRAINT, (iLayerBsSize / pSliceArgument->uiSliceSizeConstraint) + 1); (*ppCtx)->iMaxSliceCount = WELS_MAX ((*ppCtx)->iMaxSliceCount, (int) uiMaxSliceNumEstimation); iSliceBufferSize = (WELS_MAX (pSliceArgument->uiSliceSizeConstraint, iLayerBsSize / uiMaxSliceNumEstimation) << 1) + MAX_MACROBLOCK_SIZE_IN_BYTE_x2; } else { (*ppCtx)->iMaxSliceCount = WELS_MAX ((*ppCtx)->iMaxSliceCount, (int) pSliceArgument->uiSliceNum); iSliceBufferSize = ((iLayerBsSize / pSliceArgument->uiSliceNum) << 1) + MAX_MACROBLOCK_SIZE_IN_BYTE_x2; } iMaxSliceBufferSize = WELS_MAX (iMaxSliceBufferSize, iSliceBufferSize); (*ppCtx)->iSliceBufferSize[iIndex] = iSliceBufferSize; ++ iIndex; } iTargetSpatialBsSize = iLayerBsSize; iCountBsLen = iNonVclLayersBsSizeCount + iVclLayersBsSizeCount; iMaxSliceBufferSize = WELS_MIN (iMaxSliceBufferSize, iTargetSpatialBsSize); iTotalLength = iCountBsLen; pParam->iNumRefFrame = WELS_CLIP3 (pParam->iNumRefFrame, MIN_REF_PIC_COUNT, (pParam->iUsageType == CAMERA_VIDEO_REAL_TIME ? MAX_REFERENCE_PICTURE_COUNT_NUM_CAMERA : MAX_REFERENCE_PICTURE_COUNT_NUM_SCREEN)); // Output (*ppCtx)->pOut = (SWelsEncoderOutput*)pMa->WelsMallocz (sizeof (SWelsEncoderOutput), "SWelsEncoderOutput"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pOut), FreeMemorySvc (ppCtx)) (*ppCtx)->pOut->pBsBuffer = (uint8_t*)pMa->WelsMallocz (iCountBsLen, "pOut->pBsBuffer"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pOut->pBsBuffer), FreeMemorySvc (ppCtx)) (*ppCtx)->pOut->uiSize = iCountBsLen; (*ppCtx)->pOut->sNalList = (SWelsNalRaw*)pMa->WelsMallocz (iCountNals * sizeof (SWelsNalRaw), "pOut->sNalList"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pOut->sNalList), FreeMemorySvc (ppCtx)) (*ppCtx)->pOut->pNalLen = (int32_t*)pMa->WelsMallocz (iCountNals * sizeof (int32_t), "pOut->pNalLen"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pOut->pNalLen), FreeMemorySvc (ppCtx)) (*ppCtx)->pOut->iCountNals = iCountNals; (*ppCtx)->pOut->iNalIndex = 0; (*ppCtx)->pOut->iLayerBsIndex = 0; (*ppCtx)->pFrameBs = (uint8_t*)pMa->WelsMalloc (iTotalLength, "pFrameBs"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pFrameBs), FreeMemorySvc (ppCtx)) (*ppCtx)->iFrameBsSize = iTotalLength; (*ppCtx)->iPosBsBuffer = 0; // for pSlice bs buffers if (pParam->iMultipleThreadIdc > 1 && RequestMtResource (ppCtx, pParam, iCountBsLen, iMaxSliceBufferSize, bDynamicSlice)) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), RequestMtResource failed!"); FreeMemorySvc (ppCtx); return 1; } (*ppCtx)->pReferenceStrategy = IWelsReferenceStrategy::CreateReferenceStrategy((*ppCtx), pParam->iUsageType, pParam->bEnableLongTermReference); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pReferenceStrategy), FreeMemorySvc (ppCtx)) (*ppCtx)->pIntra4x4PredModeBlocks = static_cast<int8_t*> (pMa->WelsMallocz (iCountMaxMbNum * INTRA_4x4_MODE_NUM, "pIntra4x4PredModeBlocks")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pIntra4x4PredModeBlocks), FreeMemorySvc (ppCtx)) (*ppCtx)->pNonZeroCountBlocks = static_cast<int8_t*> (pMa->WelsMallocz (iCountMaxMbNum * MB_LUMA_CHROMA_BLOCK4x4_NUM, "pNonZeroCountBlocks")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pNonZeroCountBlocks), FreeMemorySvc (ppCtx)) (*ppCtx)->pMvUnitBlock4x4 = static_cast<SMVUnitXY*> (pMa->WelsMallocz (iCountMaxMbNum * 2 * MB_BLOCK4x4_NUM * sizeof (SMVUnitXY), "pMvUnitBlock4x4")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pMvUnitBlock4x4), FreeMemorySvc (ppCtx)) (*ppCtx)->pRefIndexBlock4x4 = static_cast<int8_t*> (pMa->WelsMallocz (iCountMaxMbNum * 2 * MB_BLOCK8x8_NUM * sizeof (int8_t), "pRefIndexBlock4x4")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pRefIndexBlock4x4), FreeMemorySvc (ppCtx)) (*ppCtx)->pSadCostMb = static_cast<int32_t*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (int32_t), "pSadCostMb")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pSadCostMb), FreeMemorySvc (ppCtx)) (*ppCtx)->iGlobalQp = 26; // global qp in default (*ppCtx)->pLtr = (SLTRState*)pMa->WelsMallocz (kiNumDependencyLayers * sizeof (SLTRState), "SLTRState"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pLtr), FreeMemorySvc (ppCtx)) int32_t i = 0; for (i = 0; i < kiNumDependencyLayers; i++) { ResetLtrState (& (*ppCtx)->pLtr[i]); } // stride tables if (AllocStrideTables (ppCtx, kiNumDependencyLayers)) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), AllocStrideTables failed!"); FreeMemorySvc (ppCtx); return 1; } //Rate control module memory allocation // only malloc once for RC pData, 12/14/2009 (*ppCtx)->pWelsSvcRc = (SWelsSvcRc*)pMa->WelsMallocz (kiNumDependencyLayers * sizeof (SWelsSvcRc), "pWelsSvcRc"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pWelsSvcRc), FreeMemorySvc (ppCtx)) //End of Rate control module memory allocation //pVaa memory allocation if (pParam->iUsageType == SCREEN_CONTENT_REAL_TIME) { (*ppCtx)->pVaa = (SVAAFrameInfoExt*)pMa->WelsMallocz (sizeof (SVAAFrameInfoExt), "pVaa"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa), FreeMemorySvc (ppCtx)) if (RequestMemoryVaaScreen ((*ppCtx)->pVaa, pMa, (*ppCtx)->pSvcParam->iMaxNumRefFrame, iCountMaxMbNum << 2)) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), RequestMemoryVaaScreen failed!"); FreeMemorySvc (ppCtx); return 1; } } else { (*ppCtx)->pVaa = (SVAAFrameInfo*)pMa->WelsMallocz (sizeof (SVAAFrameInfo), "pVaa"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa), FreeMemorySvc (ppCtx)) } if ((*ppCtx)->pSvcParam->bEnableAdaptiveQuant) { //malloc mem (*ppCtx)->pVaa->sAdaptiveQuantParam.pMotionTextureUnit = static_cast<SMotionTextureUnit*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (SMotionTextureUnit), "pVaa->sAdaptiveQuantParam.pMotionTextureUnit")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sAdaptiveQuantParam.pMotionTextureUnit), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp = static_cast<int8_t*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (int8_t), "pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp), FreeMemorySvc (ppCtx)) } (*ppCtx)->pVaa->pVaaBackgroundMbFlag = (int8_t*)pMa->WelsMallocz (iCountMaxMbNum * sizeof (int8_t), "pVaa->pVaaBackgroundMbFlag"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->pVaaBackgroundMbFlag), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sVaaCalcInfo.pSad8x8 = static_cast<int32_t (*)[4]> (pMa->WelsMallocz (iCountMaxMbNum * 4 * sizeof (int32_t), "pVaa->sVaaCalcInfo.sad8x8")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pSad8x8), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sVaaCalcInfo.pSsd16x16 = static_cast<int32_t*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (int32_t), "pVaa->sVaaCalcInfo.pSsd16x16")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pSsd16x16), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sVaaCalcInfo.pSum16x16 = static_cast<int32_t*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (int32_t), "pVaa->sVaaCalcInfo.pSum16x16")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pSum16x16), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sVaaCalcInfo.pSumOfSquare16x16 = static_cast<int32_t*> (pMa->WelsMallocz (iCountMaxMbNum * sizeof (int32_t), "pVaa->sVaaCalcInfo.pSumOfSquare16x16")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pSumOfSquare16x16), FreeMemorySvc (ppCtx)) if ((*ppCtx)->pSvcParam->bEnableBackgroundDetection) { //BGD control (*ppCtx)->pVaa->sVaaCalcInfo.pSumOfDiff8x8 = static_cast<int32_t (*)[4]> (pMa->WelsMallocz (iCountMaxMbNum * 4 * sizeof (int32_t), "pVaa->sVaaCalcInfo.pSumOfDiff8x8")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pSumOfDiff8x8), FreeMemorySvc (ppCtx)) (*ppCtx)->pVaa->sVaaCalcInfo.pMad8x8 = static_cast<uint8_t (*)[4]> (pMa->WelsMallocz (iCountMaxMbNum * 4 * sizeof (uint8_t), "pVaa->sVaaCalcInfo.pMad8x8")); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pVaa->sVaaCalcInfo.pMad8x8), FreeMemorySvc (ppCtx)) } //End of pVaa memory allocation (*ppCtx)->ppRefPicListExt = (SRefList**)pMa->WelsMallocz (kiNumDependencyLayers * sizeof (SRefList*), "ppRefPicListExt"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->ppRefPicListExt), FreeMemorySvc (ppCtx)) (*ppCtx)->ppDqLayerList = (SDqLayer**)pMa->WelsMallocz (kiNumDependencyLayers * sizeof (SDqLayer*), "ppDqLayerList"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->ppDqLayerList), FreeMemorySvc (ppCtx)) iResult = InitDqLayers (ppCtx, pExistingParasetList); if (iResult) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), InitDqLayers failed(%d)!", iResult); FreeMemorySvc (ppCtx); return iResult; } if (InitMbListD (ppCtx)) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_WARNING, "RequestMemorySvc(), InitMbListD failed!"); FreeMemorySvc (ppCtx); return 1; } int32_t iMvdRange = 0; GetMvMvdRange (pParam, (*ppCtx)->iMvRange, iMvdRange); const uint32_t kuiMvdInterTableSize = (iMvdRange << 2); //intepel*4=qpel const uint32_t kuiMvdInterTableStride = 1 + (kuiMvdInterTableSize << 1);//qpel_mv_range*2=(+/-); const uint32_t kuiMvdCacheAlignedSize = kuiMvdInterTableStride * sizeof (uint16_t); (*ppCtx)->iMvdCostTableSize = kuiMvdInterTableSize; (*ppCtx)->iMvdCostTableStride = kuiMvdInterTableStride; (*ppCtx)->pMvdCostTable = (uint16_t*)pMa->WelsMallocz (52 * kuiMvdCacheAlignedSize, "pMvdCostTable"); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == (*ppCtx)->pMvdCostTable), FreeMemorySvc (ppCtx)) MvdCostInit ((*ppCtx)->pMvdCostTable, kuiMvdInterTableStride); //should put to a better place? if ((*ppCtx)->ppRefPicListExt[0] != NULL && (*ppCtx)->ppRefPicListExt[0]->pRef[0] != NULL) (*ppCtx)->pDecPic = (*ppCtx)->ppRefPicListExt[0]->pRef[0]; else (*ppCtx)->pDecPic = NULL; // error here (*ppCtx)->pSps = & (*ppCtx)->pSpsArray[0]; (*ppCtx)->pPps = & (*ppCtx)->pPPSArray[0]; return 0; } /*! * \brief free memory in SVC core encoder * \pParam pEncCtx sWelsEncCtx* * \return none */ void FreeMemorySvc (sWelsEncCtx** ppCtx) { if (NULL != *ppCtx) { sWelsEncCtx* pCtx = *ppCtx; CMemoryAlign* pMa = pCtx->pMemAlign; SWelsSvcCodingParam* pParam = pCtx->pSvcParam; int32_t ilayer = 0; // SStrideTables if (NULL != pCtx->pStrideTab) { if (NULL != pCtx->pStrideTab->pStrideDecBlockOffset[0][1]) { pMa->WelsFree (pCtx->pStrideTab->pStrideDecBlockOffset[0][1], "pBase"); pCtx->pStrideTab->pStrideDecBlockOffset[0][1] = NULL; } pMa->WelsFree (pCtx->pStrideTab, "SStrideTables"); pCtx->pStrideTab = NULL; } // pDq idc map if (NULL != pCtx->pDqIdcMap) { pMa->WelsFree (pCtx->pDqIdcMap, "pDqIdcMap"); pCtx->pDqIdcMap = NULL; } if (NULL != pCtx->pOut) { // bs pBuffer if (NULL != pCtx->pOut->pBsBuffer) { pMa->WelsFree (pCtx->pOut->pBsBuffer, "pOut->pBsBuffer"); pCtx->pOut->pBsBuffer = NULL; } // NALs list if (NULL != pCtx->pOut->sNalList) { pMa->WelsFree (pCtx->pOut->sNalList, "pOut->sNalList"); pCtx->pOut->sNalList = NULL; } // NALs len if (NULL != pCtx->pOut->pNalLen) { pMa->WelsFree (pCtx->pOut->pNalLen, "pOut->pNalLen"); pCtx->pOut->pNalLen = NULL; } pMa->WelsFree (pCtx->pOut, "SWelsEncoderOutput"); pCtx->pOut = NULL; } if (pParam != NULL && pParam->iMultipleThreadIdc > 1) ReleaseMtResource (ppCtx); if (NULL != pCtx->pReferenceStrategy) { WELS_DELETE_OP(pCtx->pReferenceStrategy); } // frame bitstream pBuffer if (NULL != pCtx->pFrameBs) { pMa->WelsFree (pCtx->pFrameBs, "pFrameBs"); pCtx->pFrameBs = NULL; } // pSpsArray if (NULL != pCtx->pSpsArray) { pMa->WelsFree (pCtx->pSpsArray, "pSpsArray"); pCtx->pSpsArray = NULL; } // pPPSArray if (NULL != pCtx->pPPSArray) { pMa->WelsFree (pCtx->pPPSArray, "pPPSArray"); pCtx->pPPSArray = NULL; } // subset_sps_array if (NULL != pCtx->pSubsetArray) { pMa->WelsFree (pCtx->pSubsetArray, "pSubsetArray"); pCtx->pSubsetArray = NULL; } if (NULL != pCtx->pIntra4x4PredModeBlocks) { pMa->WelsFree (pCtx->pIntra4x4PredModeBlocks, "pIntra4x4PredModeBlocks"); pCtx->pIntra4x4PredModeBlocks = NULL; } if (NULL != pCtx->pNonZeroCountBlocks) { pMa->WelsFree (pCtx->pNonZeroCountBlocks, "pNonZeroCountBlocks"); pCtx->pNonZeroCountBlocks = NULL; } if (NULL != pCtx->pMvUnitBlock4x4) { pMa->WelsFree (pCtx->pMvUnitBlock4x4, "pMvUnitBlock4x4"); pCtx->pMvUnitBlock4x4 = NULL; } if (NULL != pCtx->pRefIndexBlock4x4) { pMa->WelsFree (pCtx->pRefIndexBlock4x4, "pRefIndexBlock4x4"); pCtx->pRefIndexBlock4x4 = NULL; } if (NULL != pCtx->ppMbListD) { if (NULL != pCtx->ppMbListD[0]) { pMa->WelsFree (pCtx->ppMbListD[0], "ppMbListD[0]"); (*ppCtx)->ppMbListD[0] = NULL; } pMa->WelsFree (pCtx->ppMbListD, "ppMbListD"); pCtx->ppMbListD = NULL; } if (NULL != pCtx->pSadCostMb) { pMa->WelsFree (pCtx->pSadCostMb, "pSadCostMb"); pCtx->pSadCostMb = NULL; } // SLTRState if (NULL != pCtx->pLtr) { pMa->WelsFree (pCtx->pLtr, "SLTRState"); pCtx->pLtr = NULL; } // pDq layers list ilayer = 0; if (NULL != pCtx->ppDqLayerList && pParam != NULL) { while (ilayer < pParam->iSpatialLayerNum) { SDqLayer* pDq = pCtx->ppDqLayerList[ilayer]; // pDq layers if (NULL != pDq) { FreeDqLayer (pDq, pMa); pCtx->ppDqLayerList[ilayer] = NULL; } ++ ilayer; } pMa->WelsFree (pCtx->ppDqLayerList, "ppDqLayerList"); pCtx->ppDqLayerList = NULL; } // reference picture list extension if (NULL != pCtx->ppRefPicListExt && pParam != NULL) { ilayer = 0; while (ilayer < pParam->iSpatialLayerNum) { FreeRefList (pCtx->ppRefPicListExt[ilayer], pMa, pParam->iMaxNumRefFrame); pCtx->ppRefPicListExt[ilayer] = NULL; ++ ilayer; } pMa->WelsFree (pCtx->ppRefPicListExt, "ppRefPicListExt"); pCtx->ppRefPicListExt = NULL; } // VAA if (NULL != pCtx->pVaa) { if (pCtx->pSvcParam->bEnableAdaptiveQuant) { //free mem pMa->WelsFree (pCtx->pVaa->sAdaptiveQuantParam.pMotionTextureUnit, "pVaa->sAdaptiveQuantParam.pMotionTextureUnit"); pCtx->pVaa->sAdaptiveQuantParam.pMotionTextureUnit = NULL; pMa->WelsFree (pCtx->pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp, "pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp"); pCtx->pVaa->sAdaptiveQuantParam.pMotionTextureIndexToDeltaQp = NULL; } pMa->WelsFree (pCtx->pVaa->pVaaBackgroundMbFlag, "pVaa->pVaaBackgroundMbFlag"); pCtx->pVaa->pVaaBackgroundMbFlag = NULL; pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pSad8x8, "pVaa->sVaaCalcInfo.sad8x8"); pCtx->pVaa->sVaaCalcInfo.pSad8x8 = NULL; pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pSsd16x16, "pVaa->sVaaCalcInfo.pSsd16x16"); pCtx->pVaa->sVaaCalcInfo.pSsd16x16 = NULL; pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pSum16x16, "pVaa->sVaaCalcInfo.pSum16x16"); pCtx->pVaa->sVaaCalcInfo.pSum16x16 = NULL; pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pSumOfSquare16x16, "pVaa->sVaaCalcInfo.pSumOfSquare16x16"); pCtx->pVaa->sVaaCalcInfo.pSumOfSquare16x16 = NULL; if (pCtx->pSvcParam->bEnableBackgroundDetection) { //BGD control pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pSumOfDiff8x8, "pVaa->sVaaCalcInfo.pSumOfDiff8x8"); pCtx->pVaa->sVaaCalcInfo.pSumOfDiff8x8 = NULL; pMa->WelsFree (pCtx->pVaa->sVaaCalcInfo.pMad8x8, "pVaa->sVaaCalcInfo.pMad8x8"); pCtx->pVaa->sVaaCalcInfo.pMad8x8 = NULL; } if (pCtx->pSvcParam->iUsageType == SCREEN_CONTENT_REAL_TIME) ReleaseMemoryVaaScreen (pCtx->pVaa, pMa, pCtx->pSvcParam->iMaxNumRefFrame); pMa->WelsFree (pCtx->pVaa, "pVaa"); pCtx->pVaa = NULL; } // rate control module memory free if (NULL != pCtx->pWelsSvcRc) { WelsRcFreeMemory (pCtx); pMa->WelsFree (pCtx->pWelsSvcRc, "pWelsSvcRc"); pCtx->pWelsSvcRc = NULL; } /* MVD cost tables for Inter */ if (NULL != pCtx->pMvdCostTable) { pMa->WelsFree (pCtx->pMvdCostTable, "pMvdCostTable"); pCtx->pMvdCostTable = NULL; } FreeCodingParam (&pCtx->pSvcParam, pMa); if (NULL != pCtx->pFuncList) { if (NULL != pCtx->pFuncList->pParametersetStrategy) { WELS_DELETE_OP (pCtx->pFuncList->pParametersetStrategy); } pMa->WelsFree (pCtx->pFuncList, "SWelsFuncPtrList"); pCtx->pFuncList = NULL; } #if defined(MEMORY_MONITOR) assert (pMa->WelsGetMemoryUsage() == 0); // ensure all memory free well #endif//MEMORY_MONITOR if ((*ppCtx)->pMemAlign != NULL) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_INFO, "FreeMemorySvc(), verify memory usage (%d bytes) after free..", (*ppCtx)->pMemAlign->WelsGetMemoryUsage()); WELS_DELETE_OP ((*ppCtx)->pMemAlign); } free (*ppCtx); *ppCtx = NULL; } } int32_t InitSliceSettings (SLogContext* pLogCtx, SWelsSvcCodingParam* pCodingParam, const int32_t kiCpuCores, int16_t* pMaxSliceCount) { int32_t iSpatialIdx = 0, iSpatialNum = pCodingParam->iSpatialLayerNum; uint16_t iMaxSliceCount = 0; do { SSpatialLayerConfig* pDlp = &pCodingParam->sSpatialLayers[iSpatialIdx]; SSliceArgument* pSliceArgument = &pDlp->sSliceArgument; int32_t iReturn = 0; switch (pSliceArgument->uiSliceMode) { case SM_SIZELIMITED_SLICE: iMaxSliceCount = AVERSLICENUM_CONSTRAINT; break; // go through for SM_SIZELIMITED_SLICE? case SM_FIXEDSLCNUM_SLICE: { iReturn = SliceArgumentValidationFixedSliceMode (pLogCtx, &pDlp->sSliceArgument, pCodingParam->iRCMode, pDlp->iVideoWidth, pDlp->iVideoHeight); if (iReturn) return ENC_RETURN_UNSUPPORTED_PARA; if (pSliceArgument->uiSliceNum > iMaxSliceCount) { iMaxSliceCount = pSliceArgument->uiSliceNum; } } break; case SM_SINGLE_SLICE: if (pSliceArgument->uiSliceNum > iMaxSliceCount) iMaxSliceCount = pSliceArgument->uiSliceNum; break; case SM_RASTER_SLICE: if (pSliceArgument->uiSliceNum > iMaxSliceCount) iMaxSliceCount = pSliceArgument->uiSliceNum; break; default: break; } ++ iSpatialIdx; } while (iSpatialIdx < iSpatialNum); pCodingParam->iMultipleThreadIdc = WELS_MIN (kiCpuCores, iMaxSliceCount); if (pCodingParam->iLoopFilterDisableIdc == 0 && pCodingParam->iMultipleThreadIdc != 1) // Loop filter requested to be enabled, with threading enabled pCodingParam->iLoopFilterDisableIdc = 2; // Disable loop filter on slice boundaries since that's not allowed with multithreading *pMaxSliceCount = iMaxSliceCount; return ENC_RETURN_SUCCESS; } /*! * \brief log output for cpu features/capabilities */ void OutputCpuFeaturesLog (SLogContext* pLogCtx, uint32_t uiCpuFeatureFlags, uint32_t uiCpuCores, int32_t iCacheLineSize) { // welstracer output WelsLog (pLogCtx, WELS_LOG_INFO, "WELS CPU features/capacities (0x%x) detected: \t" "HTT: %c, " "MMX: %c, " "MMXEX: %c, " "SSE: %c, " "SSE2: %c, " "SSE3: %c, " "SSSE3: %c, " "SSE4.1: %c, " "SSE4.2: %c, " "AVX: %c, " "FMA: %c, " "X87-FPU: %c, " "3DNOW: %c, " "3DNOWEX: %c, " "ALTIVEC: %c, " "CMOV: %c, " "MOVBE: %c, " "AES: %c, " "NUMBER OF LOGIC PROCESSORS ON CHIP: %d, " "CPU CACHE LINE SIZE (BYTES): %d", uiCpuFeatureFlags, (uiCpuFeatureFlags & WELS_CPU_HTT) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_MMX) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_MMXEXT) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSE) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSE2) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSE3) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSSE3) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSE41) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_SSE42) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_AVX) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_FMA) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_FPU) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_3DNOW) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_3DNOWEXT) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_ALTIVEC) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_CMOV) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_MOVBE) ? 'Y' : 'N', (uiCpuFeatureFlags & WELS_CPU_AES) ? 'Y' : 'N', uiCpuCores, iCacheLineSize); } /* * * status information output */ #if defined(STAT_OUTPUT) void StatOverallEncodingExt (sWelsEncCtx* pCtx) { int8_t i = 0; int8_t j = 0; for (i = 0; i < pCtx->pSvcParam->iSpatialLayerNum; i++) { fprintf (stdout, "\nDependency layer : %d\n", i); fprintf (stdout, "Quality layer : %d\n", j); { const int32_t iCount = pCtx->sStatData[i][j].sSliceData.iSliceCount[I_SLICE] + pCtx->sStatData[i][j].sSliceData.iSliceCount[P_SLICE] + pCtx->sStatData[i][j].sSliceData.iSliceCount[B_SLICE]; #if defined(MB_TYPES_CHECK) if (iCount > 0) { int32_t iCountNumIMb = pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][Intra4x4] + pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][Intra16x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][7]; int32_t iCountNumPMb = pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Intra4x4] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Intra16x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][7] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x8] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x8] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][10] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][PSkip]; int32_t count_p_mbL0 = pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x8] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x8] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][10]; int32_t iMbCount = iCountNumIMb + iCountNumPMb; if (iMbCount > 0) { fprintf (stderr, "SVC: overall Slices MBs: %d Avg\nI4x4: %.3f%% I16x16: %.3f%% IBL: %.3f%%\nP16x16: %.3f%% P16x8: %.3f%% P8x16: %.3f%% P8x8: %.3f%% SUBP8x8: %.3f%% PSKIP: %.3f%%\nILP(All): %.3f%% ILP(PL0): %.3f%% BLSKIP(PL0): %.3f%% RP(PL0): %.3f%%\n", iMbCount, (100.0f * (pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][Intra4x4] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Intra4x4]) / iMbCount), (100.0f * (pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][Intra16x16] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Intra16x16]) / iMbCount), (100.0f * (pCtx->sStatData[i][j].sSliceData.iMbCount[I_SLICE][7] + pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][7]) / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x16] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter16x8] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x16] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][Inter8x8] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][10] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][PSkip] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][11] / iMbCount), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][11] / count_p_mbL0), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][8] / count_p_mbL0), (100.0f * pCtx->sStatData[i][j].sSliceData.iMbCount[P_SLICE][9] / count_p_mbL0) ); } } #endif //#if defined(MB_TYPES_CHECK) if (iCount > 0) { fprintf (stdout, "SVC: overall PSNR Y: %2.3f U: %2.3f V: %2.3f kb/s: %.1f fps: %.3f\n\n", (pCtx->sStatData[i][j].sQualityStat.rYPsnr[I_SLICE] + pCtx->sStatData[i][j].sQualityStat.rYPsnr[P_SLICE] + pCtx->sStatData[i][j].sQualityStat.rYPsnr[B_SLICE]) / (float) (iCount), (pCtx->sStatData[i][j].sQualityStat.rUPsnr[I_SLICE] + pCtx->sStatData[i][j].sQualityStat.rUPsnr[P_SLICE] + pCtx->sStatData[i][j].sQualityStat.rUPsnr[B_SLICE]) / (float) (iCount), (pCtx->sStatData[i][j].sQualityStat.rVPsnr[I_SLICE] + pCtx->sStatData[i][j].sQualityStat.rVPsnr[P_SLICE] + pCtx->sStatData[i][j].sQualityStat.rVPsnr[B_SLICE]) / (float) (iCount), 1.0f * pCtx->pSvcParam->sDependencyLayers[i].fOutputFrameRate * (pCtx->sStatData[i][j].sSliceData.iSliceSize[I_SLICE] + pCtx->sStatData[i][j].sSliceData.iSliceSize[P_SLICE] + pCtx->sStatData[i][j].sSliceData.iSliceSize[B_SLICE]) / (float) ( iCount + pCtx->pWelsSvcRc[i].iSkipFrameNum) / 1000, 1.0f * pCtx->pSvcParam->sDependencyLayers[i].fOutputFrameRate); } } } } #endif int32_t GetMultipleThreadIdc (SLogContext* pLogCtx, SWelsSvcCodingParam* pCodingParam, int16_t& iSliceNum, int32_t& iCacheLineSize, uint32_t& uiCpuFeatureFlags) { // for cpu features detection, Only detect once?? int32_t uiCpuCores = 0; // number of logic processors on physical processor package, zero logic processors means HTT not supported uiCpuFeatureFlags = WelsCPUFeatureDetect (&uiCpuCores); // detect cpu capacity features #ifdef X86_ASM if (uiCpuFeatureFlags & WELS_CPU_CACHELINE_128) iCacheLineSize = 128; else if (uiCpuFeatureFlags & WELS_CPU_CACHELINE_64) iCacheLineSize = 64; else if (uiCpuFeatureFlags & WELS_CPU_CACHELINE_32) iCacheLineSize = 32; else if (uiCpuFeatureFlags & WELS_CPU_CACHELINE_16) iCacheLineSize = 16; OutputCpuFeaturesLog (pLogCtx, uiCpuFeatureFlags, uiCpuCores, iCacheLineSize); #else iCacheLineSize = 16; // 16 bytes aligned in default #endif//X86_ASM if (0 == pCodingParam->iMultipleThreadIdc && uiCpuCores == 0) { // cpuid not supported or doesn't expose the number of cores, // use high level system API as followed to detect number of pysical/logic processor uiCpuCores = DynamicDetectCpuCores(); } if (0 == pCodingParam->iMultipleThreadIdc) pCodingParam->iMultipleThreadIdc = (uiCpuCores > 0) ? uiCpuCores : 1; // So far so many cpu cores up to MAX_THREADS_NUM mean for server platforms, // for client application here it is constrained by maximal to MAX_THREADS_NUM pCodingParam->iMultipleThreadIdc = WELS_CLIP3 (pCodingParam->iMultipleThreadIdc, 1, MAX_THREADS_NUM); uiCpuCores = pCodingParam->iMultipleThreadIdc; if (InitSliceSettings (pLogCtx, pCodingParam, uiCpuCores, &iSliceNum)) { WelsLog (pLogCtx, WELS_LOG_ERROR, "GetMultipleThreadIdc(), InitSliceSettings failed."); return 1; } return 0; } /*! * \brief uninitialize Wels encoder core library * \pParam pEncCtx sWelsEncCtx* * \return none */ void WelsUninitEncoderExt (sWelsEncCtx** ppCtx) { if (NULL == ppCtx || NULL == *ppCtx) return; WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_INFO, "WelsUninitEncoderExt(), pCtx= %p, iMultipleThreadIdc= %d.", (void*) (*ppCtx), (*ppCtx)->pSvcParam->iMultipleThreadIdc); #if defined(STAT_OUTPUT) StatOverallEncodingExt (*ppCtx); #endif if ((*ppCtx)->pSvcParam->iMultipleThreadIdc > 1 && (*ppCtx)->pSliceThreading != NULL) { const int32_t iThreadCount = (*ppCtx)->pSvcParam->iMultipleThreadIdc; int32_t iThreadIdx = 0; while (iThreadIdx < iThreadCount) { int res = 0; if ((*ppCtx)->pSliceThreading->pThreadHandles[iThreadIdx]) { WelsEventSignal (& (*ppCtx)->pSliceThreading->pExitEncodeEvent[iThreadIdx]); WelsEventSignal (& (*ppCtx)->pSliceThreading->pThreadMasterEvent[iThreadIdx]); res = WelsThreadJoin ((*ppCtx)->pSliceThreading->pThreadHandles[iThreadIdx]); // waiting thread exit WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_INFO, "WelsUninitEncoderExt(), pthread_join(pThreadHandles%d) return %d..", iThreadIdx, res); (*ppCtx)->pSliceThreading->pThreadHandles[iThreadIdx] = 0; } ++ iThreadIdx; } } if ((*ppCtx)->pVpp) { (*ppCtx)->pVpp->FreeSpatialPictures (*ppCtx); WELS_DELETE_OP ((*ppCtx)->pVpp); } FreeMemorySvc (ppCtx); *ppCtx = NULL; } /*! * \brief initialize Wels avc encoder core library * \pParam ppCtx sWelsEncCtx** * \pParam pParam SWelsSvcCodingParam* * \return successful - 0; otherwise none 0 for failed */ int32_t WelsInitEncoderExt (sWelsEncCtx** ppCtx, SWelsSvcCodingParam* pCodingParam, SLogContext* pLogCtx, SExistingParasetList* pExistingParasetList) { sWelsEncCtx* pCtx = NULL; int32_t iRet = 0; int16_t iSliceNum = 1; // number of slices used int32_t iCacheLineSize = 16; // on chip cache line size in byte uint32_t uiCpuFeatureFlags = 0; if (NULL == ppCtx || NULL == pCodingParam) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), NULL == ppCtx(0x%p) or NULL == pCodingParam(0x%p).", (void*)ppCtx, (void*)pCodingParam); return 1; } iRet = ParamValidationExt (pLogCtx, pCodingParam); if (iRet != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), ParamValidationExt failed return %d.", iRet); return iRet; } iRet = pCodingParam->DetermineTemporalSettings(); if (iRet != ENC_RETURN_SUCCESS) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), DetermineTemporalSettings failed return %d (check in/out frame rate and temporal layer setting! -- in/out = 2^x, x <= temppral_layer_num)", iRet); return iRet; } iRet = GetMultipleThreadIdc (pLogCtx, pCodingParam, iSliceNum, iCacheLineSize, uiCpuFeatureFlags); if (iRet != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), GetMultipleThreadIdc failed return %d.", iRet); return iRet; } *ppCtx = NULL; pCtx = static_cast<sWelsEncCtx*> (malloc (sizeof (sWelsEncCtx))); WELS_VERIFY_RETURN_IF (1, (NULL == pCtx)) memset (pCtx, 0, sizeof (sWelsEncCtx)); pCtx->sLogCtx = *pLogCtx; pCtx->pMemAlign = new CMemoryAlign (iCacheLineSize); WELS_VERIFY_RETURN_PROC_IF (1, (NULL == pCtx->pMemAlign), WelsUninitEncoderExt (&pCtx)) iRet = AllocCodingParam (&pCtx->pSvcParam, pCtx->pMemAlign); if (iRet != 0) { WelsUninitEncoderExt (&pCtx); return iRet; } memcpy (pCtx->pSvcParam, pCodingParam, sizeof (SWelsSvcCodingParam)); // confirmed_safe_unsafe_usage pCtx->pFuncList = (SWelsFuncPtrList*)pCtx->pMemAlign->WelsMallocz (sizeof (SWelsFuncPtrList), "SWelsFuncPtrList"); if (NULL == pCtx->pFuncList) { WelsUninitEncoderExt (&pCtx); return 1; } InitFunctionPointers (pCtx, pCtx->pSvcParam, uiCpuFeatureFlags); pCtx->iActiveThreadsNum = pCodingParam->iMultipleThreadIdc; pCtx->iMaxSliceCount = iSliceNum; iRet = RequestMemorySvc (&pCtx, pExistingParasetList); if (iRet != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), RequestMemorySvc failed return %d.", iRet); WelsUninitEncoderExt (&pCtx); return iRet; } if (pCodingParam->iEntropyCodingModeFlag) WelsCabacInit (pCtx); WelsRcInitModule (pCtx, pCtx->pSvcParam->iRCMode); pCtx->pVpp = new CWelsPreProcess (pCtx); if (pCtx->pVpp == NULL) { iRet = 1; WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), pOut of memory in case new CWelsPreProcess()."); WelsUninitEncoderExt (&pCtx); return iRet; } if ((iRet = pCtx->pVpp->AllocSpatialPictures (pCtx, pCtx->pSvcParam)) != 0) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsInitEncoderExt(), pVPP alloc spatial pictures failed"); WelsUninitEncoderExt (&pCtx); return iRet; } #if defined(MEMORY_MONITOR) WelsLog (pLogCtx, WELS_LOG_INFO, "WelsInitEncoderExt() exit, overall memory usage: %llu bytes", static_cast<unsigned long long> (sizeof (sWelsEncCtx) /* requested size from malloc() or new operator */ + pCtx->pMemAlign->WelsGetMemoryUsage()) /* requested size from CMemoryAlign::WelsMalloc() */ ); #endif//MEMORY_MONITOR pCtx->iStatisticsLogInterval = STATISTICS_LOG_INTERVAL_MS; pCtx->uiLastTimestamp = -1; *ppCtx = pCtx; WelsLog (pLogCtx, WELS_LOG_DEBUG, "WelsInitEncoderExt(), pCtx= 0x%p.", (void*)pCtx); return 0; } /*! * \brief get temporal level due to configuration and coding context */ int32_t GetTemporalLevel (SSpatialLayerInternal* fDlp, const int32_t kiFrameNum, const int32_t kiGopSize) { const int32_t kiCodingIdx = kiFrameNum & (kiGopSize - 1); return fDlp->uiCodingIdx2TemporalId[kiCodingIdx]; } void DynslcUpdateMbNeighbourInfoListForAllSlices (SDqLayer* pCurDq, SMB* pMbList) { SSliceCtx* pSliceCtx = &pCurDq->sSliceEncCtx; const int32_t kiMbWidth = pSliceCtx->iMbWidth; const int32_t kiEndMbInSlice = pSliceCtx->iMbNumInFrame - 1; int32_t iIdx = 0; do { SMB* pMb = &pMbList[iIdx]; UpdateMbNeighbor (pCurDq, pMb, kiMbWidth, WelsMbToSliceIdc (pCurDq, pMb->iMbXY)); ++ iIdx; } while (iIdx <= kiEndMbInSlice); } /* * TUNE back if number of picture partition decision algorithm based on past if available */ int32_t PicPartitionNumDecision (sWelsEncCtx* pCtx) { int32_t iPartitionNum = 1; if (pCtx->pSvcParam->iMultipleThreadIdc > 1) { iPartitionNum = pCtx->pSvcParam->iMultipleThreadIdc; } return iPartitionNum; } void WelsInitCurrentQBLayerMltslc (sWelsEncCtx* pCtx) { //pData init SDqLayer* pCurDq = pCtx->pCurDqLayer; //mb_neighbor DynslcUpdateMbNeighbourInfoListForAllSlices (pCurDq, pCurDq->sMbDataP); } void UpdateSlicepEncCtxWithPartition (SDqLayer* pCurDq, int32_t iPartitionNum) { SSliceCtx* pSliceCtx = &pCurDq->sSliceEncCtx; SSlice* pSliceInLayer = pCurDq->sLayerInfo.pSliceInLayer; const int32_t kiMbNumInFrame = pSliceCtx->iMbNumInFrame; int32_t iCountMbNumPerPartition = kiMbNumInFrame; int32_t iAssignableMbLeft = kiMbNumInFrame; int32_t iFirstMbIdx = 0; int32_t i/*, j*/; if (iPartitionNum <= 0) iPartitionNum = 1; else if (iPartitionNum > AVERSLICENUM_CONSTRAINT) iPartitionNum = AVERSLICENUM_CONSTRAINT; // AVERSLICENUM_CONSTRAINT might be variable, however not fixed by MACRO iCountMbNumPerPartition /= iPartitionNum; pSliceCtx->iSliceNumInFrame = iPartitionNum; i = 0; while (i < iPartitionNum) { if (i + 1 == iPartitionNum) { pSliceInLayer[i].iCountMbNumInSlice = iAssignableMbLeft; } else { pSliceInLayer[i].iCountMbNumInSlice = iCountMbNumPerPartition; } pSliceInLayer[i].sSliceHeaderExt.sSliceHeader.iFirstMbInSlice = iFirstMbIdx; WelsSetMemMultiplebytes_c (pSliceCtx->pOverallMbMap + iFirstMbIdx, i, pSliceInLayer[i].iCountMbNumInSlice, sizeof (uint16_t)); // for next partition(or pSlice) iFirstMbIdx += pSliceInLayer[i].iCountMbNumInSlice; iAssignableMbLeft -= pSliceInLayer[i].iCountMbNumInSlice; ++ i; } } void WelsInitCurrentDlayerMltslc (sWelsEncCtx* pCtx, int32_t iPartitionNum) { SDqLayer* pCurDq = pCtx->pCurDqLayer; SSliceCtx* pSliceCtx = &pCurDq->sSliceEncCtx; UpdateSlicepEncCtxWithPartition (pCurDq, iPartitionNum); if (I_SLICE == pCtx->eSliceType) { //check if uiSliceSizeConstraint too small #define byte_complexIMBat26 (60) uint8_t iCurDid = pCtx->uiDependencyId; uint32_t uiFrmByte = 0; if (pCtx->pSvcParam->iRCMode != RC_OFF_MODE) { //RC case uiFrmByte = ( ((uint32_t) (pCtx->pSvcParam->sSpatialLayers[iCurDid].iSpatialBitrate) / (uint32_t) (pCtx->pSvcParam->sDependencyLayers[iCurDid].fInputFrameRate)) >> 3); } else { //fixed QP case const int32_t iTtlMbNumInFrame = pSliceCtx->iMbNumInFrame; int32_t iQDeltaTo26 = (26 - pCtx->pSvcParam->sSpatialLayers[iCurDid].iDLayerQp); uiFrmByte = (iTtlMbNumInFrame * byte_complexIMBat26); if (iQDeltaTo26 > 0) { //smaller QP than 26 uiFrmByte = (uint32_t) (uiFrmByte * ((float)iQDeltaTo26 / 4)); } else if (iQDeltaTo26 < 0) { //larger QP than 26 iQDeltaTo26 = ((-iQDeltaTo26) >> 2); //delta mod 4 uiFrmByte = (uiFrmByte >> (iQDeltaTo26)); //if delta 4, byte /2 } } //MINPACKETSIZE_CONSTRAINT if (pSliceCtx->uiSliceSizeConstraint < (uint32_t) (uiFrmByte//suppose 16 byte per mb at average / (pSliceCtx->iMaxSliceNumConstraint)) ) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_WARNING, "Set-SliceConstraint(%d) too small for current resolution (MB# %d) under QP/BR!", pSliceCtx->uiSliceSizeConstraint, pSliceCtx->iMbNumInFrame ); } } WelsInitCurrentQBLayerMltslc (pCtx); } /*! * \brief initialize current layer */ void WelsInitCurrentLayer (sWelsEncCtx* pCtx, const int32_t kiWidth, const int32_t kiHeight) { SWelsSvcCodingParam* pParam = pCtx->pSvcParam; SPicture* pEncPic = pCtx->pEncPic; SPicture* pDecPic = pCtx->pDecPic; SDqLayer* pCurDq = pCtx->pCurDqLayer; SSlice* pBaseSlice = &pCurDq->sLayerInfo.pSliceInLayer[0]; SSlice* pSlice = NULL; const uint8_t kiCurDid = pCtx->uiDependencyId; const bool kbUseSubsetSpsFlag = (!pParam->bSimulcastAVC) && (kiCurDid > BASE_DEPENDENCY_ID); SSpatialLayerConfig* fDlp = &pParam->sSpatialLayers[kiCurDid]; SNalUnitHeaderExt* pNalHdExt = &pCurDq->sLayerInfo.sNalHeaderExt; SNalUnitHeader* pNalHd = &pNalHdExt->sNalUnitHeader; SDqIdc* pDqIdc = &pCtx->pDqIdcMap[kiCurDid]; int32_t iIdx = 0; int32_t iSliceCount = 0; SSpatialLayerInternal* pParamInternal = &pParam->sDependencyLayers[kiCurDid]; if (NULL == pCurDq) return; pCurDq->pDecPic = pDecPic; if (fDlp->sSliceArgument.uiSliceMode == SM_SIZELIMITED_SLICE) // need get extra slices for update iSliceCount = GetInitialSliceNum (pCurDq->iMbWidth, pCurDq->iMbHeight, &fDlp->sSliceArgument); else iSliceCount = GetCurrentSliceNum (pCurDq); assert (iSliceCount > 0); int32_t iCurPpsId = pDqIdc->iPpsId; int32_t iCurSpsId = pDqIdc->iSpsId; iCurPpsId = pCtx->pFuncList->pParametersetStrategy->GetCurrentPpsId (iCurPpsId, WELS_ABS (pCtx->uiIdrPicId - 1) % MAX_PPS_COUNT); pBaseSlice->sSliceHeaderExt.sSliceHeader.iPpsId = iCurPpsId; pCurDq->sLayerInfo.pPpsP = pBaseSlice->sSliceHeaderExt.sSliceHeader.pPps = &pCtx->pPPSArray[iCurPpsId]; pBaseSlice->sSliceHeaderExt.sSliceHeader.iSpsId = iCurSpsId; if (kbUseSubsetSpsFlag) { pCurDq->sLayerInfo.pSubsetSpsP = &pCtx->pSubsetArray[iCurSpsId]; pCurDq->sLayerInfo.pSpsP = pBaseSlice->sSliceHeaderExt.sSliceHeader.pSps = &pCurDq->sLayerInfo.pSubsetSpsP->pSps; } else { pCurDq->sLayerInfo.pSubsetSpsP = NULL; pCurDq->sLayerInfo.pSpsP = pBaseSlice->sSliceHeaderExt.sSliceHeader.pSps = &pCtx->pSpsArray[iCurSpsId]; } pBaseSlice->bSliceHeaderExtFlag = (NAL_UNIT_CODED_SLICE_EXT == pCtx->eNalType); pSlice = pBaseSlice; iIdx = 1; while (iIdx < iSliceCount) { ++ pSlice; pSlice->sSliceHeaderExt.sSliceHeader.iPpsId = pBaseSlice->sSliceHeaderExt.sSliceHeader.iPpsId; pSlice->sSliceHeaderExt.sSliceHeader.pPps = pBaseSlice->sSliceHeaderExt.sSliceHeader.pPps; pSlice->sSliceHeaderExt.sSliceHeader.iSpsId = pBaseSlice->sSliceHeaderExt.sSliceHeader.iSpsId; pSlice->sSliceHeaderExt.sSliceHeader.pSps = pBaseSlice->sSliceHeaderExt.sSliceHeader.pSps; pSlice->bSliceHeaderExtFlag = pBaseSlice->bSliceHeaderExtFlag; ++ iIdx; } memset (pNalHdExt, 0, sizeof (SNalUnitHeaderExt)); pNalHd->uiNalRefIdc = pCtx->eNalPriority; pNalHd->eNalUnitType = pCtx->eNalType; pNalHdExt->uiDependencyId = kiCurDid; pNalHdExt->bDiscardableFlag = (pCtx->bNeedPrefixNalFlag) ? (pNalHd->uiNalRefIdc == NRI_PRI_LOWEST) : false; pNalHdExt->bIdrFlag = (pParamInternal->iFrameNum == 0) && ((pCtx->eNalType == NAL_UNIT_CODED_SLICE_IDR) || (pCtx->eSliceType == I_SLICE)); pNalHdExt->uiTemporalId = pCtx->uiTemporalId; // pEncPic pData pCurDq->pEncData[0] = pEncPic->pData[0]; pCurDq->pEncData[1] = pEncPic->pData[1]; pCurDq->pEncData[2] = pEncPic->pData[2]; pCurDq->iEncStride[0] = pEncPic->iLineSize[0]; pCurDq->iEncStride[1] = pEncPic->iLineSize[1]; pCurDq->iEncStride[2] = pEncPic->iLineSize[2]; // cs pData pCurDq->pCsData[0] = pDecPic->pData[0]; pCurDq->pCsData[1] = pDecPic->pData[1]; pCurDq->pCsData[2] = pDecPic->pData[2]; pCurDq->iCsStride[0] = pDecPic->iLineSize[0]; pCurDq->iCsStride[1] = pDecPic->iLineSize[1]; pCurDq->iCsStride[2] = pDecPic->iLineSize[2]; if (pCurDq->pRefLayer != NULL) { pCurDq->bBaseLayerAvailableFlag = true; } else { pCurDq->bBaseLayerAvailableFlag = false; } if (pCtx->pTaskManage) { pCtx->pTaskManage->InitFrame (kiCurDid); } } static inline void SetFastCodingFunc (SWelsFuncPtrList* pFuncList) { pFuncList->pfIntraFineMd = WelsMdIntraFinePartitionVaa; pFuncList->sSampleDealingFuncs.pfMdCost = pFuncList->sSampleDealingFuncs.pfSampleSad; pFuncList->sSampleDealingFuncs.pfIntra16x16Combined3 = pFuncList->sSampleDealingFuncs.pfIntra16x16Combined3Sad; pFuncList->sSampleDealingFuncs.pfIntra8x8Combined3 = pFuncList->sSampleDealingFuncs.pfIntra8x8Combined3Sad; } static inline void SetNormalCodingFunc (SWelsFuncPtrList* pFuncList) { pFuncList->pfIntraFineMd = WelsMdIntraFinePartition; pFuncList->sSampleDealingFuncs.pfMdCost = pFuncList->sSampleDealingFuncs.pfSampleSatd; pFuncList->sSampleDealingFuncs.pfIntra16x16Combined3 = pFuncList->sSampleDealingFuncs.pfIntra16x16Combined3Satd; pFuncList->sSampleDealingFuncs.pfIntra8x8Combined3 = pFuncList->sSampleDealingFuncs.pfIntra8x8Combined3Satd; pFuncList->sSampleDealingFuncs.pfIntra4x4Combined3 = pFuncList->sSampleDealingFuncs.pfIntra4x4Combined3Satd; } bool SetMeMethod (const uint8_t uiMethod, PSearchMethodFunc& pSearchMethodFunc) { switch (uiMethod) { case ME_DIA: pSearchMethodFunc = WelsDiamondSearch; break; case ME_CROSS: pSearchMethodFunc = WelsMotionCrossSearch; break; case ME_DIA_CROSS: pSearchMethodFunc = WelsDiamondCrossSearch; break; case ME_DIA_CROSS_FME: pSearchMethodFunc = WelsDiamondCrossFeatureSearch; break; case ME_FULL: pSearchMethodFunc = WelsDiamondSearch; return false; default: pSearchMethodFunc = WelsDiamondSearch; return false; } return true; } void PreprocessSliceCoding (sWelsEncCtx* pCtx) { SDqLayer* pCurLayer = pCtx->pCurDqLayer; //const bool kbBaseAvail = pCurLayer->bBaseLayerAvailableFlag; const bool kbHighestSpatialLayer = (pCtx->pSvcParam->iSpatialLayerNum == (pCurLayer->sLayerInfo.sNalHeaderExt.uiDependencyId + 1)); SWelsFuncPtrList* pFuncList = pCtx->pFuncList; SLogContext* pLogCtx = & (pCtx->sLogCtx); /* function pointers conditional assignment under sWelsEncCtx, layer_mb_enc_rec (in stack) is exclusive */ if ((pCtx->pSvcParam->iUsageType == CAMERA_VIDEO_REAL_TIME && kbHighestSpatialLayer) || (pCtx->pSvcParam->iUsageType == SCREEN_CONTENT_REAL_TIME && P_SLICE == pCtx->eSliceType && kbHighestSpatialLayer) //TODO: here is for sync with the origin code, consider the design again with more tests ) { SetFastCodingFunc (pFuncList); } else { SetNormalCodingFunc (pFuncList); } if (P_SLICE == pCtx->eSliceType) { for (int i = 0; i < BLOCK_STATIC_IDC_ALL; i++) { pFuncList->pfMotionSearch[i] = WelsMotionEstimateSearch; } pFuncList->pfSearchMethod[BLOCK_16x16] = pFuncList->pfSearchMethod[BLOCK_16x8] = pFuncList->pfSearchMethod[BLOCK_8x16] = pFuncList->pfSearchMethod[BLOCK_8x8] = pFuncList->pfSearchMethod[BLOCK_4x4] = pFuncList->pfSearchMethod[BLOCK_8x4] = pFuncList->pfSearchMethod[BLOCK_4x8] = WelsDiamondSearch; pFuncList->pfFirstIntraMode = WelsMdFirstIntraMode; pFuncList->sSampleDealingFuncs.pfMeCost = pCtx->pFuncList->sSampleDealingFuncs.pfSampleSatd; pFuncList->pfSetScrollingMv = SetScrollingMvToMdNull; if (kbHighestSpatialLayer) { pFuncList->pfCalculateSatd = NotCalculateSatdCost; pFuncList->pfInterFineMd = WelsMdInterFinePartitionVaa; } else { pFuncList->pfCalculateSatd = CalculateSatdCost; pFuncList->pfInterFineMd = WelsMdInterFinePartition; } } else { pFuncList->sSampleDealingFuncs.pfMeCost = NULL; } //to init at each frame will be needed when dealing with hybrid content (camera+screen) if (pCtx->pSvcParam->iUsageType == SCREEN_CONTENT_REAL_TIME) { if (P_SLICE == pCtx->eSliceType) { //MD related func pointers pFuncList->pfInterFineMd = WelsMdInterFinePartitionVaaOnScreen; //ME related func pointers SVAAFrameInfoExt* pVaaExt = static_cast<SVAAFrameInfoExt*> (pCtx->pVaa); if (pVaaExt->sScrollDetectInfo.bScrollDetectFlag && (pVaaExt->sScrollDetectInfo.iScrollMvX | pVaaExt->sScrollDetectInfo.iScrollMvY)) { pFuncList->pfSetScrollingMv = SetScrollingMvToMd; } else { pFuncList->pfSetScrollingMv = SetScrollingMvToMdNull; } pFuncList->pfMotionSearch[NO_STATIC] = WelsMotionEstimateSearch; pFuncList->pfMotionSearch[COLLOCATED_STATIC] = WelsMotionEstimateSearchStatic; pFuncList->pfMotionSearch[SCROLLED_STATIC] = WelsMotionEstimateSearchScrolled; //ME16x16 if (!SetMeMethod (ME_DIA_CROSS, pFuncList->pfSearchMethod[BLOCK_16x16])) { WelsLog (pLogCtx, WELS_LOG_WARNING, "SetMeMethod(BLOCK_16x16) ME_DIA_CROSS unsuccessful, switched to default search"); } //ME8x8 SFeatureSearchPreparation* pFeatureSearchPreparation = pCurLayer->pFeatureSearchPreparation; if (pFeatureSearchPreparation) { pFeatureSearchPreparation->iHighFreMbCount = 0; //calculate bFMESwitchFlag SVAAFrameInfoExt* pVaaExt = static_cast<SVAAFrameInfoExt*> (pCtx->pVaa); const int32_t kiMbSize = pCurLayer->iMbHeight * pCurLayer->iMbWidth; pFeatureSearchPreparation->bFMESwitchFlag = CalcFMESwitchFlag (pFeatureSearchPreparation->uiFMEGoodFrameCount, pFeatureSearchPreparation->iHighFreMbCount * 100 / kiMbSize, pCtx->pVaa->sVaaCalcInfo.iFrameSad / kiMbSize, pVaaExt->sScrollDetectInfo.bScrollDetectFlag); //PerformFMEPreprocess SScreenBlockFeatureStorage* pScreenBlockFeatureStorage = pCurLayer->pRefPic->pScreenBlockFeatureStorage; pFeatureSearchPreparation->pRefBlockFeature = pScreenBlockFeatureStorage; if (pFeatureSearchPreparation->bFMESwitchFlag && !pScreenBlockFeatureStorage->bRefBlockFeatureCalculated) { SPicture* pRef = (pCtx->pSvcParam->bEnableLongTermReference ? pCurLayer->pRefOri[0] : pCurLayer->pRefPic); PerformFMEPreprocess (pFuncList, pRef, pFeatureSearchPreparation->pFeatureOfBlock, pScreenBlockFeatureStorage); } //assign ME pointer if (pFeatureSearchPreparation->bFMESwitchFlag && pScreenBlockFeatureStorage->bRefBlockFeatureCalculated && (!pScreenBlockFeatureStorage->iIs16x16)) { if (!SetMeMethod (ME_DIA_CROSS_FME, pFuncList->pfSearchMethod[BLOCK_8x8])) { WelsLog (pLogCtx, WELS_LOG_WARNING, "SetMeMethod(BLOCK_8x8) ME_DIA_CROSS_FME unsuccessful, switched to default search"); } } //assign UpdateFMESwitch pointer if (pFeatureSearchPreparation->bFMESwitchFlag) { pFuncList->pfUpdateFMESwitch = UpdateFMESwitch; } else { pFuncList->pfUpdateFMESwitch = UpdateFMESwitchNull; } }//if (pFeatureSearchPreparation) } else { //reset some status when at I_SLICE pCurLayer->pFeatureSearchPreparation->bFMESwitchFlag = true; pCurLayer->pFeatureSearchPreparation->uiFMEGoodFrameCount = FMESWITCH_DEFAULT_GOODFRAME_NUM; } } // update some layer dependent variable to save judgements in mb-level pCurLayer->bSatdInMdFlag = ((pFuncList->sSampleDealingFuncs.pfMeCost == pFuncList->sSampleDealingFuncs.pfSampleSatd) && (pFuncList->sSampleDealingFuncs.pfMdCost == pFuncList->sSampleDealingFuncs.pfSampleSatd)); const int32_t kiCurDid = pCtx->uiDependencyId; const int32_t kiCurTid = pCtx->uiTemporalId; if (pCurLayer->bDeblockingParallelFlag && (pCurLayer->iLoopFilterDisableIdc != 1) #if !defined(ENABLE_FRAME_DUMP) && (NRI_PRI_LOWEST != pCtx->eNalPriority) && (pCtx->pSvcParam->sDependencyLayers[kiCurDid].iHighestTemporalId == 0 || kiCurTid < pCtx->pSvcParam->sDependencyLayers[kiCurDid].iHighestTemporalId) #endif// !ENABLE_FRAME_DUMP ) { pFuncList->pfDeblocking.pfDeblockingFilterSlice = DeblockingFilterSliceAvcbase; } else { pFuncList->pfDeblocking.pfDeblockingFilterSlice = DeblockingFilterSliceAvcbaseNull; } } /*! * \brief swap pDq layers between current pDq layer and reference pDq layer */ static inline void WelsSwapDqLayers (sWelsEncCtx* pCtx, const int32_t kiNextDqIdx) { // swap and assign reference SDqLayer* pTmpLayer = pCtx->ppDqLayerList[kiNextDqIdx]; SDqLayer* pRefLayer = pCtx->pCurDqLayer; pCtx->pCurDqLayer = pTmpLayer; pCtx->pCurDqLayer->pRefLayer = pRefLayer; } /*! * \brief prefetch reference picture after WelsBuildRefList */ static inline void PrefetchReferencePicture (sWelsEncCtx* pCtx, const EVideoFrameType keFrameType) { SSlice* pSliceBase = &pCtx->pCurDqLayer->sLayerInfo.pSliceInLayer[0]; const int32_t kiSliceCount = GetCurrentSliceNum (pCtx->pCurDqLayer); int32_t iIdx = 0; uint8_t uiRefIdx = -1; assert (kiSliceCount > 0); if (keFrameType != videoFrameTypeIDR) { assert (pCtx->iNumRef0 > 0); pCtx->pRefPic = pCtx->pRefList0[0]; // always get item 0 due to reordering done pCtx->pCurDqLayer->pRefPic = pCtx->pRefPic; uiRefIdx = 0; // reordered reference iIndex } else { // safe for IDR coding pCtx->pRefPic = NULL; pCtx->pCurDqLayer->pRefPic = NULL; } iIdx = 0; while (iIdx < kiSliceCount) { pSliceBase->sSliceHeaderExt.sSliceHeader.uiRefIndex = uiRefIdx; ++ pSliceBase; ++ iIdx; } } int32_t WelsWriteOneSPS (sWelsEncCtx* pCtx, const int32_t kiSpsIdx, int32_t& iNalSize) { int iNal = pCtx->pOut->iNalIndex; WelsLoadNal (pCtx->pOut, NAL_UNIT_SPS, NRI_PRI_HIGHEST); WelsWriteSpsNal (&pCtx->pSpsArray[kiSpsIdx], &pCtx->pOut->sBsWrite, pCtx->pFuncList->pParametersetStrategy->GetSpsIdOffsetList (PARA_SET_TYPE_AVCSPS)); WelsUnloadNal (pCtx->pOut); int32_t iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[iNal], NULL, pCtx->iFrameBsSize - pCtx->iPosBsBuffer,//available buffer to be written, so need to substract the used length pCtx->pFrameBs + pCtx->iPosBsBuffer, &iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pCtx->iPosBsBuffer += iNalSize; return ENC_RETURN_SUCCESS; } int32_t WelsWriteOnePPS (sWelsEncCtx* pCtx, const int32_t kiPpsIdx, int32_t& iNalSize) { //TODO int32_t iNal = pCtx->pOut->iNalIndex; /* generate picture parameter set */ WelsLoadNal (pCtx->pOut, NAL_UNIT_PPS, NRI_PRI_HIGHEST); WelsWritePpsSyntax (&pCtx->pPPSArray[kiPpsIdx], &pCtx->pOut->sBsWrite, pCtx->pFuncList->pParametersetStrategy); WelsUnloadNal (pCtx->pOut); int32_t iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[iNal], NULL, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pCtx->iPosBsBuffer += iNalSize; return ENC_RETURN_SUCCESS; } /*! * \brief write all parameter sets introduced in SVC extension * \return writing results, success or error */ int32_t WelsWriteParameterSets (sWelsEncCtx* pCtx, int32_t* pNalLen, int32_t* pNumNal, int32_t* pTotalLength) { int32_t iSize = 0; int32_t iNal = 0; int32_t iIdx = 0; int32_t iId = 0; int32_t iCountNal = 0; int32_t iNalLength = 0; int32_t iReturn = ENC_RETURN_SUCCESS; if (NULL == pCtx || NULL == pNalLen || NULL == pNumNal || NULL == pCtx->pFuncList->pParametersetStrategy) return ENC_RETURN_UNEXPECTED; *pTotalLength = 0; /* write all SPS */ iIdx = 0; while (iIdx < pCtx->iSpsNum) { pCtx->pFuncList->pParametersetStrategy->Update (pCtx->pSpsArray[iIdx].uiSpsId, PARA_SET_TYPE_AVCSPS); /* generate sequence parameters set */ iId = pCtx->pFuncList->pParametersetStrategy->GetSpsIdx (iIdx); WelsWriteOneSPS (pCtx, iId, iNalLength); pNalLen[iCountNal] = iNalLength; iSize += iNalLength; ++ iIdx; ++ iCountNal; } /* write all Subset SPS */ iIdx = 0; while (iIdx < pCtx->iSubsetSpsNum) { iNal = pCtx->pOut->iNalIndex; pCtx->pFuncList->pParametersetStrategy->Update (pCtx->pSubsetArray[iIdx].pSps.uiSpsId, PARA_SET_TYPE_SUBSETSPS); iId = iIdx; /* generate Subset SPS */ WelsLoadNal (pCtx->pOut, NAL_UNIT_SUBSET_SPS, NRI_PRI_HIGHEST); WelsWriteSubsetSpsSyntax (&pCtx->pSubsetArray[iId], &pCtx->pOut->sBsWrite, pCtx->pFuncList->pParametersetStrategy->GetSpsIdOffsetList (PARA_SET_TYPE_SUBSETSPS)); WelsUnloadNal (pCtx->pOut); iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[iNal], NULL, pCtx->iFrameBsSize - pCtx->iPosBsBuffer,//available buffer to be written, so need to substract the used length pCtx->pFrameBs + pCtx->iPosBsBuffer, &iNalLength); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pNalLen[iCountNal] = iNalLength; pCtx->iPosBsBuffer += iNalLength; iSize += iNalLength; ++ iIdx; ++ iCountNal; } pCtx->pFuncList->pParametersetStrategy->UpdatePpsList (pCtx); iIdx = 0; while (iIdx < pCtx->iPpsNum) { pCtx->pFuncList->pParametersetStrategy->Update (pCtx->pPPSArray[iIdx].iPpsId, PARA_SET_TYPE_PPS); WelsWriteOnePPS (pCtx, iIdx, iNalLength); pNalLen[iCountNal] = iNalLength; iSize += iNalLength; ++ iIdx; ++ iCountNal; } *pNumNal = iCountNal; *pTotalLength = iSize; return ENC_RETURN_SUCCESS; } static inline int32_t AddPrefixNal (sWelsEncCtx* pCtx, SLayerBSInfo* pLayerBsInfo, int32_t* pNalLen, int32_t* pNalIdxInLayer, const EWelsNalUnitType keNalType, const EWelsNalRefIdc keNalRefIdc, int32_t& iPayloadSize) { int32_t iReturn = ENC_RETURN_SUCCESS; iPayloadSize = 0; if (keNalRefIdc != NRI_PRI_LOWEST) { WelsLoadNal (pCtx->pOut, NAL_UNIT_PREFIX, keNalRefIdc); WelsWriteSVCPrefixNal (&pCtx->pOut->sBsWrite, keNalRefIdc, (NAL_UNIT_CODED_SLICE_IDR == keNalType)); WelsUnloadNal (pCtx->pOut); iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[pCtx->pOut->iNalIndex - 1], &pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &pNalLen[*pNalIdxInLayer]); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) iPayloadSize = pNalLen[*pNalIdxInLayer]; pCtx->iPosBsBuffer += iPayloadSize; (*pNalIdxInLayer) ++; } else { // No Prefix NAL Unit RBSP syntax here, but need add NAL Unit Header extension WelsLoadNal (pCtx->pOut, NAL_UNIT_PREFIX, keNalRefIdc); // No need write any syntax of prefix NAL Unit RBSP here WelsUnloadNal (pCtx->pOut); iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[pCtx->pOut->iNalIndex - 1], &pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &pNalLen[*pNalIdxInLayer]); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) iPayloadSize = pNalLen[*pNalIdxInLayer]; pCtx->iPosBsBuffer += iPayloadSize; (*pNalIdxInLayer) ++; } return ENC_RETURN_SUCCESS; } int32_t WritePadding (sWelsEncCtx* pCtx, int32_t iLen, int32_t& iSize) { int32_t i = 0; int32_t iNal = 0; SBitStringAux* pBs = NULL; int32_t iNalLen; iSize = 0; iNal = pCtx->pOut->iNalIndex; pBs = &pCtx->pOut->sBsWrite; // SBitStringAux instance for non VCL NALs decoding if ((pBs->pEndBuf - pBs->pCurBuf) < iLen || iNal >= pCtx->pOut->iCountNals) { #if GOM_TRACE_FLAG WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "[RC] paddingcal pBuffer overflow, bufferlen=%lld, paddinglen=%d, iNalIdx= %d, iCountNals= %d", static_cast<long long int> (pBs->pEndBuf - pBs->pCurBuf), iLen, iNal, pCtx->pOut->iCountNals); #endif return ENC_RETURN_MEMOVERFLOWFOUND; } WelsLoadNal (pCtx->pOut, NAL_UNIT_FILLER_DATA, NRI_PRI_LOWEST); for (i = 0; i < iLen; i++) { BsWriteBits (pBs, 8, 0xff); } BsRbspTrailingBits (pBs); WelsUnloadNal (pCtx->pOut); int32_t iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[iNal], NULL, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &iNalLen); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pCtx->iPosBsBuffer += iNalLen; iSize += iNalLen; return ENC_RETURN_SUCCESS; } /* * Force coding IDR as follows */ int32_t ForceCodingIDR (sWelsEncCtx* pCtx) { if (NULL == pCtx) return 1; for (int32_t iDid = 0; iDid < pCtx->pSvcParam->iSpatialLayerNum; iDid++) { SSpatialLayerInternal* pParamInternal = &pCtx->pSvcParam->sDependencyLayers[iDid]; pParamInternal->iCodingIndex = 0; pParamInternal->iSkipFrameFlag = 0; pParamInternal->iFrameIndex = 0; pParamInternal->iFrameNum = 0; pParamInternal->iPOC = 0; pParamInternal->bEncCurFrmAsIdrFlag = true; } pCtx->bCheckWindowStatusRefreshFlag = false; WelsLog (&pCtx->sLogCtx, WELS_LOG_INFO, "ForceCodingIDR at InputFrameCount=%d\n", pCtx->sEncoderStatistics[0].uiInputFrameCount); return 0; } int32_t WelsEncoderEncodeParameterSets (sWelsEncCtx* pCtx, void* pDst) { if (NULL == pCtx || NULL == pDst) { return ENC_RETURN_UNEXPECTED; } SFrameBSInfo* pFbi = (SFrameBSInfo*)pDst; SLayerBSInfo* pLayerBsInfo = &pFbi->sLayerInfo[0]; int32_t iCountNal = 0; int32_t iTotalLength = 0; pLayerBsInfo->pBsBuf = pCtx->pFrameBs; pLayerBsInfo->pNalLengthInByte = pCtx->pOut->pNalLen; InitBits (&pCtx->pOut->sBsWrite, pCtx->pOut->pBsBuffer, pCtx->pOut->uiSize); pCtx->iPosBsBuffer = 0; int32_t iReturn = WelsWriteParameterSets (pCtx, &pLayerBsInfo->pNalLengthInByte[0], &iCountNal, &iTotalLength); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->uiSpatialId = 0; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeInvalid; //pCtx->eLastNalPriority = NRI_PRI_HIGHEST; pFbi->iLayerNum = 1; pFbi->eFrameType = videoFrameTypeInvalid; WelsEmms(); return ENC_RETURN_SUCCESS; } int32_t GetSubSequenceId (sWelsEncCtx* pCtx, EVideoFrameType eFrameType) { int32_t iSubSeqId = 0; if (eFrameType == videoFrameTypeIDR) iSubSeqId = 0; else if (eFrameType == videoFrameTypeI) iSubSeqId = 1; else if (eFrameType == videoFrameTypeP) { if (pCtx->bCurFrameMarkedAsSceneLtr) iSubSeqId = 2; else iSubSeqId = 3 + pCtx->uiTemporalId; //T0:3 T1:4 T2:5 T3:6 } else iSubSeqId = 3 + MAX_TEMPORAL_LAYER_NUM; return iSubSeqId; } // writing parasets for (simulcast) svc int32_t WriteSsvcParaset (sWelsEncCtx* pCtx, const int32_t kiSpatialNum, SLayerBSInfo*& pLayerBsInfo, int32_t& iLayerNum, int32_t& iFrameSize) { int32_t iNonVclSize = 0, iCountNal = 0, iReturn = ENC_RETURN_SUCCESS; iReturn = WelsWriteParameterSets (pCtx, &pLayerBsInfo->pNalLengthInByte[0], &iCountNal, &iNonVclSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->uiSpatialId = 0; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeIDR; //point to next pLayerBsInfo ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; //update for external countings ++ iLayerNum; iFrameSize += iNonVclSize; return iReturn; } // writing parasets for simulcast avc int32_t WriteSavcParaset (sWelsEncCtx* pCtx, const int32_t iIdx, SLayerBSInfo*& pLayerBsInfo, int32_t& iLayerNum, int32_t& iFrameSize) { int32_t iNonVclSize = 0, iCountNal = 0, iReturn = ENC_RETURN_SUCCESS; // write SPS iNonVclSize = 0; //writing one NAL int32_t iNalSize = 0; iCountNal = 0; if (pCtx->pFuncList->pParametersetStrategy) { pCtx->pFuncList->pParametersetStrategy->Update (pCtx->pSpsArray[iIdx].uiSpsId, PARA_SET_TYPE_AVCSPS); } iReturn = WelsWriteOneSPS (pCtx, iIdx, iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->pNalLengthInByte[iCountNal] = iNalSize; iNonVclSize += iNalSize; iCountNal = 1; //finish writing one NAL pLayerBsInfo->uiSpatialId = iIdx; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeIDR; //point to next pLayerBsInfo ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; //update for external countings ++ iLayerNum; // write PPS //TODO: under new strategy, will PPS be correctly updated? //writing one NAL iNalSize = 0; iCountNal = 0; if (pCtx->pFuncList->pParametersetStrategy) { pCtx->pFuncList->pParametersetStrategy->Update (pCtx->pPPSArray[iIdx].iPpsId, PARA_SET_TYPE_PPS); } iReturn = WelsWriteOnePPS (pCtx, iIdx, iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->pNalLengthInByte[iCountNal] = iNalSize; iNonVclSize += iNalSize; iCountNal = 1; //finish writing one NAL pLayerBsInfo->uiSpatialId = iIdx; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeIDR; //point to next pLayerBsInfo ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; //update for external countings ++ iLayerNum; // to check number of layers / nals / slices dependencies if (iLayerNum > MAX_LAYER_NUM_OF_FRAME) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WriteSavcParaset(), iLayerNum(%d) > MAX_LAYER_NUM_OF_FRAME(%d)!", iLayerNum, MAX_LAYER_NUM_OF_FRAME); return 1; } iFrameSize += iNonVclSize; return iReturn; } //cover the logic of simulcast avc + sps_pps_listing int32_t WriteSavcParaset_Listing (sWelsEncCtx* pCtx, const int32_t kiSpatialNum, SLayerBSInfo*& pLayerBsInfo, int32_t& iLayerNum, int32_t& iFrameSize) { int32_t iNonVclSize = 0, iCountNal = 0, iReturn = ENC_RETURN_SUCCESS; // write SPS iNonVclSize = 0; for (int32_t iSpatialId = 0; iSpatialId < kiSpatialNum; iSpatialId++) { iCountNal = 0; for (int32_t iIdx = 0; iIdx < pCtx->iSpsNum; iIdx++) { //writing one NAL int32_t iNalSize = 0; iReturn = WelsWriteOneSPS (pCtx, iIdx, iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->pNalLengthInByte[iCountNal] = iNalSize; iNonVclSize += iNalSize; iCountNal ++; //finish writing one NAL } pLayerBsInfo->uiSpatialId = iSpatialId; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeIDR; //point to next pLayerBsInfo ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; //update for external countings ++ iLayerNum; } // write PPS pCtx->pFuncList->pParametersetStrategy->UpdatePpsList (pCtx); //TODO: under new strategy, will PPS be correctly updated? for (int32_t iSpatialId = 0; iSpatialId < kiSpatialNum; iSpatialId++) { iCountNal = 0; for (int32_t iIdx = 0; iIdx < pCtx->iPpsNum; iIdx++) { //writing one NAL int32_t iNalSize = 0; iReturn = WelsWriteOnePPS (pCtx, iIdx, iNalSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) pLayerBsInfo->pNalLengthInByte[iCountNal] = iNalSize; iNonVclSize += iNalSize; iCountNal ++; //finish writing one NAL } pLayerBsInfo->uiSpatialId = iSpatialId; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = iCountNal; pLayerBsInfo->eFrameType = videoFrameTypeIDR; //point to next pLayerBsInfo ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; //update for external countings ++ iLayerNum; } // to check number of layers / nals / slices dependencies if (iLayerNum > MAX_LAYER_NUM_OF_FRAME) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WriteSavcParaset(), iLayerNum(%d) > MAX_LAYER_NUM_OF_FRAME(%d)!", iLayerNum, MAX_LAYER_NUM_OF_FRAME); return ENC_RETURN_UNEXPECTED; } iFrameSize += iNonVclSize; return iReturn; } void StackBackEncoderStatus (sWelsEncCtx* pEncCtx, EVideoFrameType keFrameType) { SSpatialLayerInternal* pParamInternal = &pEncCtx->pSvcParam->sDependencyLayers[pEncCtx->uiDependencyId]; // for bitstream writing pEncCtx->iPosBsBuffer = 0; // reset bs pBuffer position pEncCtx->pOut->iNalIndex = 0; // reset NAL index pEncCtx->pOut->iLayerBsIndex = 0; // reset index of Layer Bs InitBits (&pEncCtx->pOut->sBsWrite, pEncCtx->pOut->pBsBuffer, pEncCtx->pOut->uiSize); if ((keFrameType == videoFrameTypeP) || (keFrameType == videoFrameTypeI)) { pParamInternal->iFrameIndex --; if (pParamInternal->iPOC != 0) { pParamInternal->iPOC -= 2; } else { pParamInternal->iPOC = (1 << pEncCtx->pSps->iLog2MaxPocLsb) - 2; } LoadBackFrameNum (pEncCtx, pEncCtx->uiDependencyId); pEncCtx->eNalType = NAL_UNIT_CODED_SLICE; pEncCtx->eSliceType = P_SLICE; //pEncCtx->eNalPriority = pEncCtx->eLastNalPriority; //not need this since eNalPriority will be updated at the beginning of coding a frame } else if (keFrameType == videoFrameTypeIDR) { pEncCtx->uiIdrPicId --; //set the next frame to be IDR ForceCodingIDR (pEncCtx); } else { // B pictures are not supported now, any else? assert (0); } // no need to stack back RC info since the info is still useful for later RQ model calculation // no need to stack back MB slicing info for dynamic balancing, since the info is still refer-able } void ClearFrameBsInfo (sWelsEncCtx* pCtx, SFrameBSInfo* pFbi) { pFbi->sLayerInfo[0].pBsBuf = pCtx->pFrameBs; pFbi->sLayerInfo[0].pNalLengthInByte = pCtx->pOut->pNalLen; for (int i = 0; i < pFbi->iLayerNum; i++) { pFbi->sLayerInfo[i].iNalCount = 0; pFbi->sLayerInfo[i].eFrameType = videoFrameTypeSkip; } pFbi->iLayerNum = 0; pFbi->iFrameSizeInBytes = 0; } EVideoFrameType PrepareEncodeFrame (sWelsEncCtx* pCtx, SLayerBSInfo*& pLayerBsInfo, int32_t iSpatialNum , int8_t& iCurDid, int32_t& iCurTid, int32_t& iLayerNum, int32_t& iFrameSize, long long uiTimeStamp) { SWelsSvcCodingParam* pSvcParam = pCtx->pSvcParam; SSpatialPicIndex* pSpatialIndexMap = &pCtx->sSpatialIndexMap[0]; if (!pSvcParam->bSimulcastAVC) { pCtx->iSkipFrameFlag = false; for (int32_t iDid = 0; iDid < iSpatialNum; iDid++) { if (pCtx->pSvcParam->sDependencyLayers[ (pSpatialIndexMap + iDid)->iDid].iSkipFrameFlag) pCtx->iSkipFrameFlag = 1; } } EVideoFrameType eFrameType = DecideFrameType (pCtx, iSpatialNum, iCurDid); if (eFrameType == videoFrameTypeSkip) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_DEBUG, "[Rc] Frame timestamp = %lld, skip one frame due to target_br, continual skipped %d frames", uiTimeStamp, pCtx->iContinualSkipFrames); if (pSvcParam->bSimulcastAVC) { if (pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip) pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip (pCtx, iCurDid); } else { if (pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip) { for (int32_t i = 0; i < iSpatialNum; i++) { pCtx->pSvcParam->sDependencyLayers[i].iSkipFrameFlag = false; pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip (pCtx, (pSpatialIndexMap + i)->iDid); } } } } else { if (pCtx->pFuncList->pfRc.pfWelsCheckSkipBasedMaxbr) { bool bSkip = pCtx->pFuncList->pfRc.pfWelsCheckSkipBasedMaxbr (pCtx, iSpatialNum, eFrameType, (uint32_t)uiTimeStamp); if (bSkip) { eFrameType = videoFrameTypeSkip; pLayerBsInfo->eFrameType = videoFrameTypeSkip; WelsLog (& (pCtx->sLogCtx), WELS_LOG_DEBUG, "[Rc] Frame timestamp = %lld, skip one frame due to max_br, continual skipped %d frames", uiTimeStamp, pCtx->iContinualSkipFrames); } } } if (eFrameType != videoFrameTypeSkip) { SSpatialLayerInternal* pParamInternal = &pSvcParam->sDependencyLayers[iCurDid]; pCtx->iContinualSkipFrames = 0; iCurTid = GetTemporalLevel (&pSvcParam->sDependencyLayers[iCurDid], pParamInternal->iCodingIndex, pSvcParam->uiGopSize); //skip this spatial layer if (iCurTid == INVALID_TEMPORAL_ID) { pParamInternal->iCodingIndex ++; eFrameType = videoFrameTypeSkip; pLayerBsInfo->eFrameType = videoFrameTypeSkip; } else { pCtx->uiTemporalId = iCurTid; if (eFrameType == videoFrameTypeIDR) { // write parameter sets bitstream or SEI/SSEI (if any) here // TODO: use function pointer instead if (! (SPS_LISTING & pCtx->pSvcParam->eSpsPpsIdStrategy)) { if (pSvcParam->bSimulcastAVC) { pCtx->iEncoderError = WriteSavcParaset (pCtx, iCurDid, pLayerBsInfo, iLayerNum, iFrameSize); ++ pCtx->uiIdrPicId; } else { pCtx->iEncoderError = WriteSsvcParaset (pCtx, iSpatialNum, pLayerBsInfo, iLayerNum, iFrameSize); ++ pCtx->uiIdrPicId; } } else { pCtx->iEncoderError = WriteSavcParaset_Listing (pCtx, iSpatialNum, pLayerBsInfo, iLayerNum, iFrameSize); ++ pCtx->uiIdrPicId; } } } } return eFrameType; } /*! * \brief core svc encoding process * * \pParam pCtx sWelsEncCtx*, encoder context * \pParam pFbi FrameBSInfo* * \pParam pSrcPic Source Picture * \return EFrameType (videoFrameTypeIDR/videoFrameTypeI/videoFrameTypeP) */ int32_t WelsEncoderEncodeExt (sWelsEncCtx* pCtx, SFrameBSInfo* pFbi, const SSourcePicture* pSrcPic) { if (pCtx == NULL) { return ENC_RETURN_MEMALLOCERR; } SLayerBSInfo* pLayerBsInfo = &pFbi->sLayerInfo[0]; SWelsSvcCodingParam* pSvcParam = pCtx->pSvcParam; SSpatialPicIndex* pSpatialIndexMap = &pCtx->sSpatialIndexMap[0]; #if defined(ENABLE_FRAME_DUMP) || defined(ENABLE_PSNR_CALC) SPicture* fsnr = NULL; #endif//ENABLE_FRAME_DUMP || ENABLE_PSNR_CALC SPicture* pEncPic = NULL; // to be decided later int32_t iDidList[MAX_DEPENDENCY_LAYER] = {0}; int32_t iLayerNum = 0; int32_t iLayerSize = 0; int32_t iSpatialNum = 0; // available count number of spatial layers due to frame size changed in this given frame int32_t iSpatialIdx = 0; // iIndex of spatial layers due to frame size changed in this given frame int32_t iFrameSize = 0; int32_t iNalIdxInLayer = 0; int32_t iCountNal = 0; EVideoFrameType eFrameType = videoFrameTypeInvalid; int32_t iCurWidth = 0; int32_t iCurHeight = 0; EWelsNalUnitType eNalType = NAL_UNIT_UNSPEC_0; EWelsNalRefIdc eNalRefIdc = NRI_PRI_LOWEST; int8_t iCurDid = 0; int32_t iCurTid = 0; bool bAvcBased = false; SLogContext* pLogCtx = & (pCtx->sLogCtx); #if defined(ENABLE_PSNR_CALC) float fSnrY = .0f, fSnrU = .0f, fSnrV = .0f; #endif//ENABLE_PSNR_CALC #if defined(_DEBUG) int32_t i = 0, j = 0, k = 0; #endif//_DEBUG pCtx->iEncoderError = ENC_RETURN_SUCCESS; pCtx->bCurFrameMarkedAsSceneLtr = false; pFbi->eFrameType = videoFrameTypeSkip; pFbi->iLayerNum = 0; // for initialization pFbi->uiTimeStamp = GetTimestampForRc (pSrcPic->uiTimeStamp, pCtx->uiLastTimestamp, pCtx->pSvcParam->sSpatialLayers[pCtx->pSvcParam->iSpatialLayerNum - 1].fFrameRate); for (int32_t iNalIdx = 0; iNalIdx < MAX_LAYER_NUM_OF_FRAME; iNalIdx++) { pFbi->sLayerInfo[iNalIdx].eFrameType = videoFrameTypeSkip; } // perform csc/denoise/downsample/padding, generate spatial layers iSpatialNum = pCtx->pVpp->BuildSpatialPicList (pCtx, pSrcPic); if (pCtx->pFuncList->pfRc.pfWelsUpdateMaxBrWindowStatus) { pCtx->pFuncList->pfRc.pfWelsUpdateMaxBrWindowStatus (pCtx, iSpatialNum, pFbi->uiTimeStamp); } if (iSpatialNum < 1) { for (int32_t iDidIdx = 0; iDidIdx < pSvcParam->iSpatialLayerNum; iDidIdx++) { SSpatialLayerInternal* pParamInternal = &pSvcParam->sDependencyLayers[iDidIdx]; pParamInternal->iCodingIndex ++; } pFbi->eFrameType = videoFrameTypeSkip; pLayerBsInfo->eFrameType = videoFrameTypeSkip; WelsLog (& (pCtx->sLogCtx), WELS_LOG_DEBUG, "[Rc] Frame timestamp = %lld, skip one frame due to preprocessing return (temporal layer settings or else), continual skipped %d frames", pSrcPic->uiTimeStamp, pCtx->iContinualSkipFrames); return ENC_RETURN_SUCCESS; } InitBitStream (pCtx); pLayerBsInfo->pBsBuf = pCtx->pFrameBs ; pLayerBsInfo->pNalLengthInByte = pCtx->pOut->pNalLen; pCtx->pCurDqLayer = pCtx->ppDqLayerList[pSpatialIndexMap->iDid]; pCtx->pCurDqLayer->pRefLayer = NULL; if (!pSvcParam->bSimulcastAVC) { eFrameType = PrepareEncodeFrame (pCtx, pLayerBsInfo, iSpatialNum , iCurDid, iCurTid, iLayerNum, iFrameSize, pFbi->uiTimeStamp); if (eFrameType == videoFrameTypeSkip) { pFbi->eFrameType = videoFrameTypeSkip; pLayerBsInfo->eFrameType = videoFrameTypeSkip; return ENC_RETURN_SUCCESS; } } while (iSpatialIdx < iSpatialNum) { iCurDid = (pSpatialIndexMap + iSpatialIdx)->iDid; SSpatialLayerConfig* pParam = &pSvcParam->sSpatialLayers[iCurDid]; SSpatialLayerInternal* pParamInternal = &pSvcParam->sDependencyLayers[iCurDid]; int32_t iDecompositionStages = pSvcParam->sDependencyLayers[iCurDid].iDecompositionStages; pCtx->pCurDqLayer = pCtx->ppDqLayerList[iCurDid]; pCtx->uiDependencyId = iCurDid; if (pSvcParam->bSimulcastAVC) { eFrameType = PrepareEncodeFrame (pCtx, pLayerBsInfo, iSpatialNum , iCurDid, iCurTid, iLayerNum, iFrameSize, pFbi->uiTimeStamp); if (eFrameType == videoFrameTypeSkip) { pLayerBsInfo->eFrameType = videoFrameTypeSkip; ++iSpatialIdx; continue; } } InitFrameCoding (pCtx, eFrameType, iCurDid); pCtx->pVpp->AnalyzeSpatialPic (pCtx, iCurDid); pCtx->pEncPic = pEncPic = (pSpatialIndexMap + iSpatialIdx)->pSrc; pCtx->pEncPic->iPictureType = pCtx->eSliceType; pCtx->pEncPic->iFramePoc = pParamInternal->iPOC; iCurWidth = pParam->iVideoWidth; iCurHeight = pParam->iVideoHeight; iDidList[iSpatialIdx] = iCurDid; // Encoding this picture might mulitiple sQualityStat layers potentially be encoded as followed switch (pParam->sSliceArgument.uiSliceMode) { case SM_FIXEDSLCNUM_SLICE: { if ((iCurDid > 0) && (pSvcParam->iMultipleThreadIdc > 1) && (pSvcParam->bUseLoadBalancing && pSvcParam->iMultipleThreadIdc >= pSvcParam->sSpatialLayers[iCurDid].sSliceArgument.uiSliceNum) ) AdjustEnhanceLayer (pCtx, iCurDid); break; } case SM_SIZELIMITED_SLICE: { int32_t iPicIPartitionNum = PicPartitionNumDecision (pCtx); // MT compatibility pCtx->iActiveThreadsNum = iPicIPartitionNum; // we try to active number of threads, equal to number of picture partitions WelsInitCurrentDlayerMltslc (pCtx, iPicIPartitionNum); break; } default: { break; } } /* coding each spatial layer, only one sQualityStat layer within spatial support */ int32_t iSliceCount = 1; if (iLayerNum >= MAX_LAYER_NUM_OF_FRAME) { // check available layer_bs_info writing as follows WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iLayerNum(%d) overflow(max:%d)!", iLayerNum, MAX_LAYER_NUM_OF_FRAME); return ENC_RETURN_UNSUPPORTED_PARA; } iNalIdxInLayer = 0; bAvcBased = ((pSvcParam->bSimulcastAVC) || (iCurDid == BASE_DEPENDENCY_ID)); pCtx->bNeedPrefixNalFlag = ((!pSvcParam->bSimulcastAVC) && (bAvcBased && (pSvcParam->bPrefixNalAddingCtrl || (pSvcParam->iSpatialLayerNum > 1)))); if (eFrameType == videoFrameTypeP) { eNalType = bAvcBased ? NAL_UNIT_CODED_SLICE : NAL_UNIT_CODED_SLICE_EXT; } else if (eFrameType == videoFrameTypeIDR) { eNalType = bAvcBased ? NAL_UNIT_CODED_SLICE_IDR : NAL_UNIT_CODED_SLICE_EXT; } if (iCurTid == 0 || pCtx->eSliceType == I_SLICE) eNalRefIdc = NRI_PRI_HIGHEST; else if (iCurTid == iDecompositionStages) eNalRefIdc = NRI_PRI_LOWEST; else if (1 + iCurTid == iDecompositionStages) eNalRefIdc = NRI_PRI_LOW; else // more details for other temporal layers? eNalRefIdc = NRI_PRI_HIGHEST; pCtx->eNalType = eNalType; pCtx->eNalPriority = eNalRefIdc; pCtx->pDecPic = pCtx->ppRefPicListExt[iCurDid]->pNextBuffer; #if defined(ENABLE_FRAME_DUMP) || defined(ENABLE_PSNR_CALC) fsnr = pCtx->pDecPic; #endif//#if defined(ENABLE_FRAME_DUMP) || defined(ENABLE_PSNR_CALC) pCtx->pDecPic->iPictureType = pCtx->eSliceType; pCtx->pDecPic->iFramePoc = pParamInternal->iPOC; WelsInitCurrentLayer (pCtx, iCurWidth, iCurHeight); pCtx->pReferenceStrategy->MarkPic (); if (!pCtx->pReferenceStrategy->BuildRefList (pParamInternal->iPOC, 0)) { WelsLog (pLogCtx, WELS_LOG_WARNING, "WelsEncoderEncodeExt(), WelsBuildRefList failed for P frames, pCtx->iNumRef0= %d. ForceCodingIDR!", pCtx->iNumRef0); eFrameType = videoFrameTypeIDR; pCtx->iEncoderError = ENC_RETURN_CORRECTED; break; } if (pCtx->eSliceType != I_SLICE) { pCtx->pReferenceStrategy->AfterBuildRefList (); } #ifdef LONG_TERM_REF_DUMP DumpRef (pCtx); #endif if (pSvcParam->iRCMode != RC_OFF_MODE) pCtx->pVpp->AnalyzePictureComplexity (pCtx, pCtx->pEncPic, ((pCtx->eSliceType == P_SLICE) && (pCtx->iNumRef0 > 0)) ? pCtx->pRefList0[0] : NULL, iCurDid, (pCtx->eSliceType == P_SLICE) && pSvcParam->bEnableBackgroundDetection); WelsUpdateRefSyntax (pCtx, pParamInternal->iPOC, eFrameType); //get reordering syntax used for writing slice header and transmit to encoder. PrefetchReferencePicture (pCtx, eFrameType); // update reference picture for current pDq layer pCtx->pFuncList->pfRc.pfWelsRcPictureInit (pCtx, pFbi->uiTimeStamp); PreprocessSliceCoding (pCtx); // MUST be called after pfWelsRcPictureInit() and WelsInitCurrentLayer() //TODO Complexity Calculation here for screen content iLayerSize = 0; if (SM_SINGLE_SLICE == pParam->sSliceArgument.uiSliceMode) { // only one slice within a sQualityStat layer int32_t iSliceSize = 0; int32_t iPayloadSize = 0; if (pCtx->bNeedPrefixNalFlag) { pCtx->iEncoderError = AddPrefixNal (pCtx, pLayerBsInfo, &pLayerBsInfo->pNalLengthInByte[0], &iNalIdxInLayer, eNalType, eNalRefIdc, iPayloadSize); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) iLayerSize += iPayloadSize; } WelsLoadNal (pCtx->pOut, eNalType, eNalRefIdc); pCtx->iEncoderError = WelsCodeOneSlice (pCtx, 0, eNalType); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) WelsUnloadNal (pCtx->pOut); pCtx->iEncoderError = WelsEncodeNal (&pCtx->pOut->sNalList[pCtx->pOut->iNalIndex - 1], &pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) iSliceSize = pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]; iLayerSize += iSliceSize; pCtx->iPosBsBuffer += iSliceSize; pLayerBsInfo->uiLayerType = VIDEO_CODING_LAYER; pLayerBsInfo->uiSpatialId = iCurDid; pLayerBsInfo->uiTemporalId = iCurTid; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->iNalCount = ++ iNalIdxInLayer; pLayerBsInfo->eFrameType = eFrameType; } // for dynamic slicing single threading.. else if ((SM_SIZELIMITED_SLICE == pParam->sSliceArgument.uiSliceMode) && (pSvcParam->iMultipleThreadIdc <= 1)) { const int32_t kiLastMbInFrame = pCtx->pCurDqLayer->sSliceEncCtx.iMbNumInFrame; pCtx->iEncoderError = WelsCodeOnePicPartition (pCtx, pFbi, pLayerBsInfo, &iNalIdxInLayer, &iLayerSize, 0, kiLastMbInFrame, 0); pLayerBsInfo->eFrameType = eFrameType; WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) } else { //other multi-slice uiSliceMode // THREAD_FULLY_FIRE_MODE/THREAD_PICK_UP_MODE for any mode of non-SM_SIZELIMITED_SLICE if ((SM_SIZELIMITED_SLICE != pParam->sSliceArgument.uiSliceMode) && (pSvcParam->iMultipleThreadIdc > 1)) { iSliceCount = GetCurrentSliceNum (pCtx->pCurDqLayer); if (iLayerNum + 1 >= MAX_LAYER_NUM_OF_FRAME) { // check available layer_bs_info for further writing as followed WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iLayerNum(%d) overflow(max:%d) at iDid= %d uiSliceMode= %d, iSliceCount= %d!", iLayerNum, MAX_LAYER_NUM_OF_FRAME, iCurDid, pParam->sSliceArgument.uiSliceMode, iSliceCount); return ENC_RETURN_UNSUPPORTED_PARA; } if (iSliceCount <= 1) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iSliceCount(%d) from GetCurrentSliceNum() is untrusted due stack/heap crupted!", iSliceCount); return ENC_RETURN_UNEXPECTED; } //note: the old codes are removed at commit: 3e0ee69 pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->uiLayerType = VIDEO_CODING_LAYER; pLayerBsInfo->uiSpatialId = pCtx->uiDependencyId; pLayerBsInfo->uiTemporalId = pCtx->uiTemporalId; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->iNalCount = 0; pLayerBsInfo->eFrameType = eFrameType; pCtx->pTaskManage->ExecuteTasks(); if (pCtx->iEncoderError) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), multi-slice (mode %d) encoding error!", pParam->sSliceArgument.uiSliceMode); return pCtx->iEncoderError; } iLayerSize = AppendSliceToFrameBs (pCtx, pLayerBsInfo, iSliceCount); } // THREAD_FULLY_FIRE_MODE && SM_SIZELIMITED_SLICE else if ((SM_SIZELIMITED_SLICE == pParam->sSliceArgument.uiSliceMode) && (pSvcParam->iMultipleThreadIdc > 1)) { const int32_t kiPartitionCnt = pCtx->iActiveThreadsNum; #if 0 //TODO: temporarily use this to keep old codes for a while, will remove old codes later int32_t iRet = 0; // to fire slice coding threads iRet = FiredSliceThreads (pCtx, &pCtx->pSliceThreading->pThreadPEncCtx[0], &pCtx->pSliceThreading->pReadySliceCodingEvent[0], &pCtx->pSliceThreading->pThreadMasterEvent[0], pFbi, kiPartitionCnt, &pCtx->pCurDqLayer->sSliceEncCtx, true); if (iRet) { WelsLog (pLogCtx, WELS_LOG_ERROR, "[MT] WelsEncoderEncodeExt(), FiredSliceThreads return(%d) failed and exit encoding frame, iSliceCount= %d, uiSliceMode= %d, iMultipleThreadIdc= %d!!", iRet, iSliceCount, pParam->sSliceArgument.uiSliceMode, pSvcParam->iMultipleThreadIdc); return ENC_RETURN_UNEXPECTED; } WelsMultipleEventsWaitAllBlocking (kiPartitionCnt, &pCtx->pSliceThreading->pSliceCodedEvent[0], &pCtx->pSliceThreading->pSliceCodedMasterEvent); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) #else int32_t iEndMbIdx = pCtx->pCurDqLayer->sSliceEncCtx.iMbNumInFrame; for (int32_t iIdx = kiPartitionCnt - 1; iIdx >= 0; --iIdx) { const int32_t iFirstMbIdx = pCtx->pCurDqLayer->sLayerInfo.pSliceInLayer[iIdx].sSliceHeaderExt.sSliceHeader.iFirstMbInSlice; pCtx->pSliceThreading->pThreadPEncCtx[iIdx].iStartMbIndex = iFirstMbIdx; pCtx->pSliceThreading->pThreadPEncCtx[iIdx].iEndMbIndex = iEndMbIdx; iEndMbIdx = iFirstMbIdx; } //TODO: use a function to remove duplicate code here and ln3994 int32_t iLayerBsIdx = pCtx->pOut->iLayerBsIndex; SLayerBSInfo* pLbi = &pFbi->sLayerInfo[iLayerBsIdx]; pLbi->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLbi->uiLayerType = VIDEO_CODING_LAYER; pLbi->uiSpatialId = pCtx->uiDependencyId; pLbi->uiTemporalId = pCtx->uiTemporalId; pLbi->uiQualityId = 0; pLbi->iNalCount = 0; pLbi->eFrameType = eFrameType; int32_t iIdx = 0; while (iIdx < kiPartitionCnt) { pCtx->pSliceThreading->pThreadPEncCtx[iIdx].pFrameBsInfo = pFbi; pCtx->pSliceThreading->pThreadPEncCtx[iIdx].iSliceIndex = iIdx; SetOneSliceBsBufferUnderMultithread (pCtx, iIdx, iIdx); ++ iIdx; } pCtx->pTaskManage->ExecuteTasks(); if (pCtx->iEncoderError) { WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), multi-slice (mode %d) encoding error = %d!", pParam->sSliceArgument.uiSliceMode, pCtx->iEncoderError); return pCtx->iEncoderError; } #endif iLayerSize = AppendSliceToFrameBs (pCtx, pLayerBsInfo, kiPartitionCnt); } else { // for non-dynamic-slicing mode single threading branch.. const bool bNeedPrefix = pCtx->bNeedPrefixNalFlag; int32_t iSliceIdx = 0; iSliceCount = GetCurrentSliceNum (pCtx->pCurDqLayer); while (iSliceIdx < iSliceCount) { int32_t iSliceSize = 0; int32_t iPayloadSize = 0; if (bNeedPrefix) { pCtx->iEncoderError = AddPrefixNal (pCtx, pLayerBsInfo, &pLayerBsInfo->pNalLengthInByte[0], &iNalIdxInLayer, eNalType, eNalRefIdc, iPayloadSize); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) iLayerSize += iPayloadSize; } WelsLoadNal (pCtx->pOut, eNalType, eNalRefIdc); pCtx->iEncoderError = WelsCodeOneSlice (pCtx, iSliceIdx, eNalType); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) WelsUnloadNal (pCtx->pOut); pCtx->iEncoderError = WelsEncodeNal (&pCtx->pOut->sNalList[pCtx->pOut->iNalIndex - 1], &pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) iSliceSize = pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]; pCtx->iPosBsBuffer += iSliceSize; iLayerSize += iSliceSize; #if defined(SLICE_INFO_OUTPUT) fprintf (stderr, "@slice=%-6d sliceType:%c idc:%d size:%-6d\n", iSliceIdx, (pCtx->eSliceType == P_SLICE ? 'P' : 'I'), eNalRefIdc, iSliceSize); #endif//SLICE_INFO_OUTPUT ++ iNalIdxInLayer; ++ iSliceIdx; } pLayerBsInfo->uiLayerType = VIDEO_CODING_LAYER; pLayerBsInfo->uiSpatialId = iCurDid; pLayerBsInfo->uiTemporalId = iCurTid; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->iNalCount = iNalIdxInLayer; pLayerBsInfo->eFrameType = eFrameType; } } if (NULL != pCtx->pFuncList->pfRc.pfWelsRcPostFrameSkipping && pCtx->pFuncList->pfRc.pfWelsRcPostFrameSkipping (pCtx, iCurDid, pFbi->uiTimeStamp)) { StackBackEncoderStatus (pCtx, eFrameType); ClearFrameBsInfo (pCtx, pFbi); iFrameSize = 0; iLayerSize = 0; iLayerNum = 0; if (pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip) { pCtx->pFuncList->pfRc.pfWelsUpdateBufferWhenSkip (pCtx, iSpatialNum); } WelsRcPostFrameSkippedUpdate (pCtx, iCurDid); WelsLog (& (pCtx->sLogCtx), WELS_LOG_INFO, "[Rc] Frame timestamp = %lld, skip one frame due to post skip, continual skipped %d frames", pFbi->uiTimeStamp, pCtx->iContinualSkipFrames); pCtx->iEncoderError = ENC_RETURN_SUCCESS; return ENC_RETURN_SUCCESS; } // deblocking filter if ( (!pCtx->pCurDqLayer->bDeblockingParallelFlag) && #if !defined(ENABLE_FRAME_DUMP) ((eNalRefIdc != NRI_PRI_LOWEST) && (pSvcParam->sDependencyLayers[iCurDid].iHighestTemporalId == 0 || iCurTid < pSvcParam->sDependencyLayers[iCurDid].iHighestTemporalId)) && #endif//!ENABLE_FRAME_DUMP true ) { PerformDeblockingFilter (pCtx); } pCtx->pFuncList->pfRc.pfWelsRcPictureInfoUpdate (pCtx, iLayerSize); RcTraceFrameBits (pCtx, pFbi->uiTimeStamp); pCtx->pDecPic->iFrameAverageQp = pCtx->pWelsSvcRc[iCurDid].iAverageFrameQp; //update scc related pCtx->pFuncList->pfUpdateFMESwitch (pCtx->pCurDqLayer); // reference picture list update if (eNalRefIdc != NRI_PRI_LOWEST) { if (!pCtx->pReferenceStrategy->UpdateRefList ()) { WelsLog (pLogCtx, WELS_LOG_WARNING, "WelsEncoderEncodeExt(), WelsUpdateRefList failed. ForceCodingIDR!"); //the above is to set the next frame to be IDR pCtx->iEncoderError = ENC_RETURN_CORRECTED; break; } } iFrameSize += iLayerSize; //check MinCr { int32_t iImageSize = (pParam->iVideoWidth * pParam->iVideoHeight * 3) >> 1; int32_t iMinCr = g_ksLevelLimits[pParam->uiLevelIdc - 1].uiMinCR; if (iFrameSize > (iImageSize / iMinCr)) WelsLog (pLogCtx, WELS_LOG_WARNING, "WelsEncoderEncodeExt()MinCr Checking,codec bitstream size is larger than Level limitation"); } #ifdef ENABLE_FRAME_DUMP if (iCurDid + 1 < pSvcParam->iSpatialLayerNum) { DumpDependencyRec (fsnr, &pSvcParam->sDependencyLayers[iCurDid].sRecFileName[0], iCurDid, pCtx->bDependencyRecFlag[iCurDid], pCtx->pCurDqLayer); pCtx->bDependencyRecFlag[iCurDid] = true; } #endif//ENABLE_FRAME_DUMP #if defined(ENABLE_PSNR_CALC) fSnrY = WelsCalcPsnr (fsnr->pData[0], fsnr->iLineSize[0], pEncPic->pData[0], pEncPic->iLineSize[0], iCurWidth, iCurHeight); fSnrU = WelsCalcPsnr (fsnr->pData[1], fsnr->iLineSize[1], pEncPic->pData[1], pEncPic->iLineSize[1], (iCurWidth >> 1), (iCurHeight >> 1)); fSnrV = WelsCalcPsnr (fsnr->pData[2], fsnr->iLineSize[2], pEncPic->pData[2], pEncPic->iLineSize[2], (iCurWidth >> 1), (iCurHeight >> 1)); #endif//ENABLE_PSNR_CALC #if defined(LAYER_INFO_OUTPUT) fprintf (stderr, "%2s %5d: %-5d %2s T%1d D%1d Q%-2d QP%3d Y%2.2f U%2.2f V%2.2f %8d bits\n", (iSpatialIdx == 0) ? "#AU" : " ", pCtx->iPOC, pCtx->iFrameNum, (eFrameType == videoFrameTypeI || eFrameType == videoFrameTypeIDR) ? "I" : "P", iCurTid, iCurDid, 0, pCtx->pWelsSvcRc[pCtx->uiDependencyId].iAverageFrameQp, fSnrY, fSnrU, fSnrV, (iLayerSize << 3)); #endif//LAYER_INFO_OUTPUT #if defined(STAT_OUTPUT) #if defined(ENABLE_PSNR_CALC) { pCtx->sStatData[iCurDid][0].sQualityStat.rYPsnr[pCtx->eSliceType] += fSnrY; pCtx->sStatData[iCurDid][0].sQualityStat.rUPsnr[pCtx->eSliceType] += fSnrU; pCtx->sStatData[iCurDid][0].sQualityStat.rVPsnr[pCtx->eSliceType] += fSnrV; } #endif//ENABLE_PSNR_CALC #if defined(MB_TYPES_CHECK) //091025, frame output if (pCtx->eSliceType == P_SLICE) { pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Intra4x4] += pCtx->sPerInfo.iMbCount[P_SLICE][Intra4x4]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Intra16x16] += pCtx->sPerInfo.iMbCount[P_SLICE][Intra16x16]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Inter16x16] += pCtx->sPerInfo.iMbCount[P_SLICE][Inter16x16]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Inter16x8] += pCtx->sPerInfo.iMbCount[P_SLICE][Inter16x8]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Inter8x16] += pCtx->sPerInfo.iMbCount[P_SLICE][Inter8x16]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][Inter8x8] += pCtx->sPerInfo.iMbCount[P_SLICE][Inter8x8]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][PSkip] += pCtx->sPerInfo.iMbCount[P_SLICE][PSkip]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][8] += pCtx->sPerInfo.iMbCount[P_SLICE][8]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][9] += pCtx->sPerInfo.iMbCount[P_SLICE][9]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][10] += pCtx->sPerInfo.iMbCount[P_SLICE][10]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[P_SLICE][11] += pCtx->sPerInfo.iMbCount[P_SLICE][11]; } else if (pCtx->eSliceType == I_SLICE) { pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[I_SLICE][Intra4x4] += pCtx->sPerInfo.iMbCount[I_SLICE][Intra4x4]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[I_SLICE][Intra16x16] += pCtx->sPerInfo.iMbCount[I_SLICE][Intra16x16]; pCtx->sStatData[iCurDid][0].sSliceData.iMbCount[I_SLICE][7] += pCtx->sPerInfo.iMbCount[I_SLICE][7]; } memset (pCtx->sPerInfo.iMbCount[P_SLICE], 0, 18 * sizeof (int32_t)); memset (pCtx->sPerInfo.iMbCount[I_SLICE], 0, 18 * sizeof (int32_t)); #endif//MB_TYPES_CHECK { ++ pCtx->sStatData[iCurDid][0].sSliceData.iSliceCount[pCtx->eSliceType]; // for multiple slices coding pCtx->sStatData[iCurDid][0].sSliceData.iSliceSize[pCtx->eSliceType] += (iLayerSize << 3); // bits } #endif//STAT_OUTPUT iCountNal = pLayerBsInfo->iNalCount; ++ iLayerNum; ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + iCountNal; if (pSvcParam->iPaddingFlag && pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingSize > 0) { int32_t iPaddingNalSize = 0; pCtx->iEncoderError = WritePadding (pCtx, pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingSize, iPaddingNalSize); WELS_VERIFY_RETURN_IFNEQ (pCtx->iEncoderError, ENC_RETURN_SUCCESS) #if GOM_TRACE_FLAG WelsLog (pLogCtx, WELS_LOG_INFO, "[RC] dependency ID = %d,encoding_qp = %d Padding: %d", pCtx->uiDependencyId, pCtx->iGlobalQp, pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingSize); #endif if (iPaddingNalSize <= 0) return ENC_RETURN_UNEXPECTED; pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingBitrateStat += pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingSize; pCtx->pWelsSvcRc[pCtx->uiDependencyId].iPaddingSize = 0; pLayerBsInfo->uiSpatialId = 0; pLayerBsInfo->uiTemporalId = 0; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->uiLayerType = NON_VIDEO_CODING_LAYER; pLayerBsInfo->iNalCount = 1; pLayerBsInfo->pNalLengthInByte[0] = iPaddingNalSize; pLayerBsInfo->eFrameType = eFrameType; ++ pLayerBsInfo; ++ pCtx->pOut->iLayerBsIndex; pLayerBsInfo->pBsBuf = pCtx->pFrameBs + pCtx->iPosBsBuffer; pLayerBsInfo->pNalLengthInByte = (pLayerBsInfo - 1)->pNalLengthInByte + 1; ++ iLayerNum; iFrameSize += iPaddingNalSize; } if ((pParam->sSliceArgument.uiSliceMode == SM_FIXEDSLCNUM_SLICE) && pSvcParam->bUseLoadBalancing && pSvcParam->iMultipleThreadIdc > 1 && pSvcParam->iMultipleThreadIdc >= pParam->sSliceArgument.uiSliceNum) { CalcSliceComplexRatio (pCtx->pCurDqLayer); #if defined(MT_DEBUG) TrackSliceComplexities (pCtx, iCurDid); #endif//#if defined(MT_DEBUG) } pCtx->eLastNalPriority[iCurDid] = eNalRefIdc; ++ iSpatialIdx; if (iCurDid + 1 < pSvcParam->iSpatialLayerNum) { //for next layer, note that iSpatialIdx has been ++ so it is pointer to next layer WelsSwapDqLayers (pCtx, (pSpatialIndexMap + iSpatialIdx)->iDid); } if (pCtx->pVpp->UpdateSpatialPictures (pCtx, pSvcParam, iCurTid, iCurDid) != 0) { ForceCodingIDR (pCtx); WelsLog (pLogCtx, WELS_LOG_WARNING, "WelsEncoderEncodeExt(), Logic Error Found in Preprocess updating. ForceCodingIDR!"); //the above is to set the next frame IDR pFbi->eFrameType = eFrameType; pLayerBsInfo->eFrameType = eFrameType; return ENC_RETURN_CORRECTED; } if (pSvcParam->bEnableLongTermReference && ((pCtx->pLtr[pCtx->uiDependencyId].bLTRMarkingFlag && (pCtx->pLtr[pCtx->uiDependencyId].iLTRMarkMode == LTR_DIRECT_MARK)) || eFrameType == videoFrameTypeIDR)) { pCtx->bRefOfCurTidIsLtr[iCurDid][iCurTid] = true; } ++ pParamInternal->iCodingIndex; }//end of (iSpatialIdx/iSpatialNum) if (ENC_RETURN_CORRECTED == pCtx->iEncoderError) { pCtx->pVpp->UpdateSpatialPictures (pCtx, pSvcParam, iCurTid, (pSpatialIndexMap + iSpatialIdx)->iDid); ForceCodingIDR (pCtx); WelsLog (pLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), Logic Error Found in temporal level. ForceCodingIDR!"); //the above is to set the next frame IDR pFbi->eFrameType = eFrameType; pLayerBsInfo->eFrameType = eFrameType; return ENC_RETURN_CORRECTED; } #if defined(MT_DEBUG) TrackSliceConsumeTime (pCtx, iDidList, iSpatialNum); #endif//MT_DEBUG if (pSvcParam->iMultipleThreadIdc > 1 && iDidList[0] == BASE_DEPENDENCY_ID && (pSvcParam->sSpatialLayers[0].sSliceArgument.uiSliceMode == SM_FIXEDSLCNUM_SLICE) && pSvcParam->bUseLoadBalancing && pSvcParam->iMultipleThreadIdc >= pSvcParam->sSpatialLayers[0].sSliceArgument.uiSliceNum && ((pSvcParam->sSpatialLayers[iDidList[iSpatialNum - 1]].sSliceArgument.uiSliceMode == SM_FIXEDSLCNUM_SLICE)) && pSvcParam->iMultipleThreadIdc >= pSvcParam->sSpatialLayers[iDidList[iSpatialNum - 1]].sSliceArgument.uiSliceNum) { AdjustBaseLayer (pCtx); } #ifdef ENABLE_FRAME_DUMP DumpRecFrame (fsnr, &pSvcParam->sDependencyLayers[pSvcParam->iSpatialLayerNum - 1].sRecFileName[0], pSvcParam->iSpatialLayerNum - 1, pCtx->bRecFlag, pCtx->pCurDqLayer); // pDecPic: final reconstruction output pCtx->bRecFlag = true; #endif//ENABLE_FRAME_DUMP // to check number of layers / nals / slices dependencies if (iLayerNum > MAX_LAYER_NUM_OF_FRAME) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iLayerNum(%d) > MAX_LAYER_NUM_OF_FRAME(%d)!", iLayerNum, MAX_LAYER_NUM_OF_FRAME); return 1; } pFbi->iLayerNum = iLayerNum; pFbi->iSubSeqId = GetSubSequenceId (pCtx, eFrameType); WelsLog (pLogCtx, WELS_LOG_DEBUG, "WelsEncoderEncodeExt() OutputInfo iLayerNum = %d,iSubSeqId = %d,iFrameSize = %d", iLayerNum, pFbi->iSubSeqId, iFrameSize); for (int32_t i = 0; i < iLayerNum; i++) WelsLog (pLogCtx, WELS_LOG_DEBUG, "WelsEncoderEncodeExt() OutputInfo iLayerId = %d,iNalType = %d,iNalCount = %d, first Nal Length=%d,uiSpatialId = %d,uiTemporalId = %d", i, pFbi->sLayerInfo[i].uiLayerType, pFbi->sLayerInfo[i].iNalCount, pFbi->sLayerInfo[i].pNalLengthInByte[0], pFbi->sLayerInfo[i].uiSpatialId, pFbi->sLayerInfo[i].uiTemporalId); WelsEmms(); pLayerBsInfo->eFrameType = eFrameType; pFbi->iFrameSizeInBytes = iFrameSize; pFbi->eFrameType = eFrameType; for (int32_t k = 0; k < pFbi->iLayerNum; k++) { if (pFbi->eFrameType != pFbi->sLayerInfo[k].eFrameType) { pFbi->eFrameType = videoFrameTypeIPMixed; } } #ifdef _DEBUG if (pFbi->iLayerNum > MAX_LAYER_NUM_OF_FRAME) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iLayerNum(%d) > MAX_LAYER_NUM_OF_FRAME(%d)!", pFbi->iLayerNum, MAX_LAYER_NUM_OF_FRAME); return ENC_RETURN_UNEXPECTED; } int32_t iTotalNal = 0; for (int32_t k = 0; k < pFbi->iLayerNum; k++) { iTotalNal += pFbi->sLayerInfo[k].iNalCount; if ((pCtx->iActiveThreadsNum > 1) && (MAX_NAL_UNITS_IN_LAYER < pFbi->sLayerInfo[k].iNalCount)) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iCountNumNals(%d) > MAX_NAL_UNITS_IN_LAYER(%d) under multi-thread(%d) NOT supported!", pFbi->sLayerInfo[k].iNalCount, MAX_NAL_UNITS_IN_LAYER), pCtx->iActiveThreadsNum; return ENC_RETURN_UNEXPECTED; } } if (iTotalNal > pCtx->pOut->iCountNals) { WelsLog (& pCtx->sLogCtx, WELS_LOG_ERROR, "WelsEncoderEncodeExt(), iTotalNal(%d) > iCountNals(%d)!", iTotalNal, pCtx->pOut->iCountNals); return ENC_RETURN_UNEXPECTED; } #endif return ENC_RETURN_SUCCESS; } /*! * \brief Wels SVC encoder parameters adjustment * SVC adjustment results in new requirement in memory blocks adjustment */ int32_t WelsEncoderParamAdjust (sWelsEncCtx** ppCtx, SWelsSvcCodingParam* pNewParam) { SWelsSvcCodingParam* pOldParam = NULL; int32_t iReturn = ENC_RETURN_SUCCESS; int8_t iIndexD = 0; bool bNeedReset = false; int16_t iSliceNum = 1; // number of slices used int32_t iCacheLineSize = 16; // on chip cache line size in byte uint32_t uiCpuFeatureFlags = 0; if (NULL == ppCtx || NULL == *ppCtx || NULL == pNewParam) return 1; /* Check validation in new parameters */ iReturn = ParamValidationExt (& (*ppCtx)->sLogCtx, pNewParam); if (iReturn != ENC_RETURN_SUCCESS) return iReturn; iReturn = GetMultipleThreadIdc (& (*ppCtx)->sLogCtx, pNewParam, iSliceNum, iCacheLineSize, uiCpuFeatureFlags); if (iReturn != ENC_RETURN_SUCCESS) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "WelsEncoderParamAdjust(), GetMultipleThreadIdc failed return %d.", iReturn); return iReturn; } pOldParam = (*ppCtx)->pSvcParam; if (pOldParam->iUsageType != pNewParam->iUsageType) { WelsLog (& (*ppCtx)->sLogCtx, WELS_LOG_ERROR, "WelsEncoderParamAdjust(), does not expect in-middle change of iUsgaeType from %d to %d", pOldParam->iUsageType, pNewParam->iUsageType); return ENC_RETURN_UNSUPPORTED_PARA; } /* Decide whether need reset for IDR frame based on adjusting prarameters changed */ /* Temporal levels, spatial settings and/ or quality settings changed need update parameter sets related. */ bNeedReset = (pOldParam == NULL) || (pOldParam->bSimulcastAVC != pNewParam->bSimulcastAVC) || (pOldParam->iSpatialLayerNum != pNewParam->iSpatialLayerNum) || (pOldParam->iPicWidth != pNewParam->iPicWidth || pOldParam->iPicHeight != pNewParam->iPicHeight) || (pOldParam->SUsedPicRect.iWidth != pNewParam->SUsedPicRect.iWidth || pOldParam->SUsedPicRect.iHeight != pNewParam->SUsedPicRect.iHeight) || (pOldParam->bEnableLongTermReference != pNewParam->bEnableLongTermReference) || (pOldParam->iLTRRefNum != pNewParam->iLTRRefNum) || (pOldParam->iMultipleThreadIdc != pNewParam->iMultipleThreadIdc) || (pOldParam->bEnableBackgroundDetection != pNewParam->bEnableBackgroundDetection) || (pOldParam->bEnableAdaptiveQuant != pNewParam->bEnableAdaptiveQuant) || (pOldParam->eSpsPpsIdStrategy != pNewParam->eSpsPpsIdStrategy); if (pNewParam->iMaxNumRefFrame > pOldParam->iMaxNumRefFrame) { bNeedReset = true; } if (!bNeedReset) { // Check its picture resolutions/quality settings respectively in each dependency layer iIndexD = 0; assert (pOldParam->iSpatialLayerNum == pNewParam->iSpatialLayerNum); do { const SSpatialLayerInternal* kpOldDlp = &pOldParam->sDependencyLayers[iIndexD]; const SSpatialLayerInternal* kpNewDlp = &pNewParam->sDependencyLayers[iIndexD]; float fT1 = .0f; float fT2 = .0f; // check frame size settings if (pOldParam->sSpatialLayers[iIndexD].iVideoWidth != pNewParam->sSpatialLayers[iIndexD].iVideoWidth || pOldParam->sSpatialLayers[iIndexD].iVideoHeight != pNewParam->sSpatialLayers[iIndexD].iVideoHeight || kpOldDlp->iActualWidth != kpNewDlp->iActualWidth || kpOldDlp->iActualHeight != kpNewDlp->iActualHeight) { bNeedReset = true; break; } if (pOldParam->sSpatialLayers[iIndexD].sSliceArgument.uiSliceMode != pNewParam->sSpatialLayers[iIndexD].sSliceArgument.uiSliceMode || pOldParam->sSpatialLayers[iIndexD].sSliceArgument.uiSliceNum != pNewParam->sSpatialLayers[iIndexD].sSliceArgument.uiSliceNum) { bNeedReset = true; break; } // check frame rate // we can not check whether corresponding fFrameRate is equal or not, // only need to check d_max/d_min and max_fr/d_max whether it is equal or not if (kpNewDlp->fInputFrameRate > EPSN && kpOldDlp->fInputFrameRate > EPSN) fT1 = kpNewDlp->fOutputFrameRate / kpNewDlp->fInputFrameRate - kpOldDlp->fOutputFrameRate / kpOldDlp->fInputFrameRate; if (kpNewDlp->fOutputFrameRate > EPSN && kpOldDlp->fOutputFrameRate > EPSN) fT2 = pNewParam->fMaxFrameRate / kpNewDlp->fOutputFrameRate - pOldParam->fMaxFrameRate / kpOldDlp->fOutputFrameRate; if (fT1 > EPSN || fT1 < -EPSN || fT2 > EPSN || fT2 < -EPSN) { bNeedReset = true; break; } ++ iIndexD; } while (iIndexD < pOldParam->iSpatialLayerNum); } if (bNeedReset) { SLogContext sLogCtx = (*ppCtx)->sLogCtx; int32_t iOldSpsPpsIdStrategy = pOldParam->eSpsPpsIdStrategy; SParaSetOffsetVariable sTmpPsoVariable[PARA_SET_TYPE]; int32_t iTmpPpsIdList[MAX_DQ_LAYER_NUM * MAX_PPS_COUNT]; uint16_t uiTmpIdrPicId = (*ppCtx)->uiIdrPicId;//this is for LTR! SEncoderStatistics sTempEncoderStatistics[MAX_DEPENDENCY_LAYER]; memcpy (sTempEncoderStatistics, (*ppCtx)->sEncoderStatistics, sizeof (sTempEncoderStatistics)); SExistingParasetList sExistingParasetList; SExistingParasetList* pExistingParasetList = NULL; if (((CONSTANT_ID != iOldSpsPpsIdStrategy) && (CONSTANT_ID != pNewParam->eSpsPpsIdStrategy))) { (*ppCtx)->pFuncList->pParametersetStrategy->OutputCurrentStructure (sTmpPsoVariable, iTmpPpsIdList, (*ppCtx), &sExistingParasetList); if ((SPS_LISTING & iOldSpsPpsIdStrategy) && (SPS_LISTING & pNewParam->eSpsPpsIdStrategy)) { pExistingParasetList = &sExistingParasetList; } } WelsUninitEncoderExt (ppCtx); /* Update new parameters */ if (WelsInitEncoderExt (ppCtx, pNewParam, &sLogCtx, pExistingParasetList)) return 1; //if WelsInitEncoderExt succeed //for LTR (*ppCtx)->uiIdrPicId = uiTmpIdrPicId ;//this is for LTR!; //this is for LTR! //for sEncoderStatistics memcpy ((*ppCtx)->sEncoderStatistics, sTempEncoderStatistics, sizeof (sTempEncoderStatistics)); //load back the needed structure for eSpsPpsIdStrategy if (((CONSTANT_ID != iOldSpsPpsIdStrategy) && (CONSTANT_ID != pNewParam->eSpsPpsIdStrategy)) || ((SPS_PPS_LISTING == iOldSpsPpsIdStrategy) && (SPS_PPS_LISTING == pNewParam->eSpsPpsIdStrategy))) { (*ppCtx)->pFuncList->pParametersetStrategy->LoadPreviousStructure (sTmpPsoVariable, iTmpPpsIdList); } } else { /* maybe adjustment introduced in bitrate or little settings adjustment and so on.. */ pNewParam->iNumRefFrame = WELS_CLIP3 (pNewParam->iNumRefFrame, MIN_REF_PIC_COUNT, (pNewParam->iUsageType == CAMERA_VIDEO_REAL_TIME ? MAX_REFERENCE_PICTURE_COUNT_NUM_CAMERA : MAX_REFERENCE_PICTURE_COUNT_NUM_SCREEN)); pNewParam->iLoopFilterDisableIdc = WELS_CLIP3 (pNewParam->iLoopFilterDisableIdc, 0, 6); pNewParam->iLoopFilterAlphaC0Offset = WELS_CLIP3 (pNewParam->iLoopFilterAlphaC0Offset, -6, 6); pNewParam->iLoopFilterBetaOffset = WELS_CLIP3 (pNewParam->iLoopFilterBetaOffset, -6, 6); pNewParam->fMaxFrameRate = WELS_CLIP3 (pNewParam->fMaxFrameRate, MIN_FRAME_RATE, MAX_FRAME_RATE); // we can not use direct struct based memcpy due some fields need keep unchanged as before pOldParam->fMaxFrameRate = pNewParam->fMaxFrameRate; // maximal frame rate [Hz / fps] pOldParam->iComplexityMode = pNewParam->iComplexityMode; // color space of input sequence pOldParam->uiIntraPeriod = pNewParam->uiIntraPeriod; // intra period (multiple of GOP size as desired) pOldParam->eSpsPpsIdStrategy = pNewParam->eSpsPpsIdStrategy; pOldParam->bPrefixNalAddingCtrl = pNewParam->bPrefixNalAddingCtrl; pOldParam->iNumRefFrame = pNewParam->iNumRefFrame; // number of reference frame used pOldParam->uiGopSize = pNewParam->uiGopSize; if (pOldParam->iTemporalLayerNum != pNewParam->iTemporalLayerNum) { pOldParam->iTemporalLayerNum = pNewParam->iTemporalLayerNum; for (int32_t iIndexD = 0; iIndexD < MAX_DEPENDENCY_LAYER; iIndexD++) pOldParam->sDependencyLayers[iIndexD].iCodingIndex = 0; } pOldParam->iDecompStages = pNewParam->iDecompStages; /* denoise control */ pOldParam->bEnableDenoise = pNewParam->bEnableDenoise; /* background detection control */ pOldParam->bEnableBackgroundDetection = pNewParam->bEnableBackgroundDetection; /* adaptive quantization control */ pOldParam->bEnableAdaptiveQuant = pNewParam->bEnableAdaptiveQuant; /* int32_t term reference control */ pOldParam->bEnableLongTermReference = pNewParam->bEnableLongTermReference; pOldParam->iLtrMarkPeriod = pNewParam->iLtrMarkPeriod; // keep below values unchanged as before pOldParam->bEnableSSEI = pNewParam->bEnableSSEI; pOldParam->bSimulcastAVC = pNewParam->bSimulcastAVC; pOldParam->bEnableFrameCroppingFlag = pNewParam->bEnableFrameCroppingFlag; // enable frame cropping flag /* Motion search */ /* Deblocking loop filter */ pOldParam->iLoopFilterDisableIdc = pNewParam->iLoopFilterDisableIdc; // 0: on, 1: off, 2: on except for slice boundaries pOldParam->iLoopFilterAlphaC0Offset = pNewParam->iLoopFilterAlphaC0Offset;// AlphaOffset: valid range [-6, 6], default 0 pOldParam->iLoopFilterBetaOffset = pNewParam->iLoopFilterBetaOffset; // BetaOffset: valid range [-6, 6], default 0 /* Rate Control */ pOldParam->iRCMode = pNewParam->iRCMode; pOldParam->iTargetBitrate = pNewParam->iTargetBitrate; // overall target bitrate introduced in RC module pOldParam->iPaddingFlag = pNewParam->iPaddingFlag; /* Layer definition */ pOldParam->bPrefixNalAddingCtrl = pNewParam->bPrefixNalAddingCtrl; // d iIndexD = 0; do { SSpatialLayerInternal* pOldDlpInternal = &pOldParam->sDependencyLayers[iIndexD]; SSpatialLayerInternal* pNewDlpInternal = &pNewParam->sDependencyLayers[iIndexD]; SSpatialLayerConfig* pOldDlp = &pOldParam->sSpatialLayers[iIndexD]; SSpatialLayerConfig* pNewDlp = &pNewParam->sSpatialLayers[iIndexD]; pOldDlpInternal->fInputFrameRate = pNewDlpInternal->fInputFrameRate; // input frame rate pOldDlpInternal->fOutputFrameRate = pNewDlpInternal->fOutputFrameRate; // output frame rate pOldDlp->iSpatialBitrate = pNewDlp->iSpatialBitrate; pOldDlp->iMaxSpatialBitrate = pNewDlp->iMaxSpatialBitrate; pOldDlp->uiProfileIdc = pNewDlp->uiProfileIdc; // value of profile IDC (0 for auto-detection) pOldDlp->iDLayerQp = pNewDlp->iDLayerQp; /* Derived variants below */ pOldDlpInternal->iTemporalResolution = pNewDlpInternal->iTemporalResolution; pOldDlpInternal->iDecompositionStages = pNewDlpInternal->iDecompositionStages; memcpy (pOldDlpInternal->uiCodingIdx2TemporalId, pNewDlpInternal->uiCodingIdx2TemporalId, sizeof (pOldDlpInternal->uiCodingIdx2TemporalId)); // confirmed_safe_unsafe_usage ++ iIndexD; } while (iIndexD < pOldParam->iSpatialLayerNum); } /* Any else initialization/reset for rate control here? */ return 0; } int32_t WelsEncoderApplyLTR (SLogContext* pLogCtx, sWelsEncCtx** ppCtx, SLTRConfig* pLTRValue) { SWelsSvcCodingParam sConfig; int32_t iNumRefFrame = 1; int32_t iRet = 0; memcpy (&sConfig, (*ppCtx)->pSvcParam, sizeof (SWelsSvcCodingParam)); sConfig.bEnableLongTermReference = pLTRValue->bEnableLongTermReference; sConfig.iLTRRefNum = pLTRValue->iLTRRefNum; int32_t uiGopSize = 1 << (sConfig.iTemporalLayerNum - 1); if (sConfig.iUsageType == SCREEN_CONTENT_REAL_TIME) { if (sConfig.bEnableLongTermReference) { sConfig.iLTRRefNum = LONG_TERM_REF_NUM_SCREEN;//WELS_CLIP3 (sConfig.iLTRRefNum, 1, LONG_TERM_REF_NUM_SCREEN); iNumRefFrame = WELS_MAX (1, WELS_LOG2 (uiGopSize)) + sConfig.iLTRRefNum; } else { sConfig.iLTRRefNum = 0; iNumRefFrame = WELS_MAX (1, uiGopSize >> 1); } } else { if (sConfig.bEnableLongTermReference) { sConfig.iLTRRefNum = LONG_TERM_REF_NUM;//WELS_CLIP3 (sConfig.iLTRRefNum, 1, LONG_TERM_REF_NUM); } else { sConfig.iLTRRefNum = 0; } iNumRefFrame = ((uiGopSize >> 1) > 1) ? ((uiGopSize >> 1) + sConfig.iLTRRefNum) : (MIN_REF_PIC_COUNT + sConfig.iLTRRefNum); iNumRefFrame = WELS_CLIP3 (iNumRefFrame, MIN_REF_PIC_COUNT, MAX_REFERENCE_PICTURE_COUNT_NUM_CAMERA); } if (iNumRefFrame > sConfig.iMaxNumRefFrame) { WelsLog (pLogCtx, WELS_LOG_WARNING, " CWelsH264SVCEncoder::SetOption LTR flag = %d and number = %d: Required number of reference increased to %d and iMaxNumRefFrame is adjusted (from %d)", sConfig.bEnableLongTermReference, sConfig.iLTRRefNum, iNumRefFrame, sConfig.iMaxNumRefFrame); sConfig.iMaxNumRefFrame = iNumRefFrame; } if (sConfig.iNumRefFrame < iNumRefFrame) { WelsLog (pLogCtx, WELS_LOG_WARNING, " CWelsH264SVCEncoder::SetOption LTR flag = %d and number = %d, Required number of reference increased from Old = %d to New = %d because of LTR setting", sConfig.bEnableLongTermReference, sConfig.iLTRRefNum, sConfig.iNumRefFrame, iNumRefFrame); sConfig.iNumRefFrame = iNumRefFrame; } WelsLog (pLogCtx, WELS_LOG_INFO, "CWelsH264SVCEncoder::SetOption enable LTR = %d,ltrnum = %d", sConfig.bEnableLongTermReference, sConfig.iLTRRefNum); iRet = WelsEncoderParamAdjust (ppCtx, &sConfig); return iRet; } int32_t FrameBsRealloc (sWelsEncCtx* pCtx, SFrameBSInfo* pFrameBsInfo, SLayerBSInfo* pLayerBsInfo) { CMemoryAlign* pMA = pCtx->pMemAlign; SDqLayer* pCurLayer = pCtx->pCurDqLayer; int32_t iCountNals = pCtx->pOut->iCountNals; int32_t iMaxSliceNumOld = pCurLayer->sSliceEncCtx.iMaxSliceNumConstraint; int32_t iMaxSliceNum = iMaxSliceNumOld; iCountNals += iMaxSliceNum * (pCtx->pSvcParam->iSpatialLayerNum + pCtx->bNeedPrefixNalFlag); iMaxSliceNum *= SLICE_NUM_EXPAND_COEF; SWelsNalRaw* pNalList = (SWelsNalRaw*)pMA->WelsMallocz (iCountNals * sizeof (SWelsNalRaw), "pOut->sNalList"); if (NULL == pNalList) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::DynSliceRealloc: pNalList is NULL"); return ENC_RETURN_MEMALLOCERR; } memcpy (pNalList, pCtx->pOut->sNalList, sizeof (SWelsNalRaw) * pCtx->pOut->iCountNals); pMA->WelsFree (pCtx->pOut->sNalList, "pOut->sNalList"); pCtx->pOut->sNalList = pNalList; int32_t* pNalLen = (int32_t*)pMA->WelsMallocz (iCountNals * sizeof (int32_t), "pOut->pNalLen"); if (NULL == pNalLen) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::DynSliceRealloc: pNalLen is NULL"); return ENC_RETURN_MEMALLOCERR; } memcpy (pNalLen, pCtx->pOut->pNalLen, sizeof (int32_t) * pCtx->pOut->iCountNals); pMA->WelsFree (pCtx->pOut->pNalLen, "pOut->pNalLen"); pCtx->pOut->pNalLen = pNalLen; pCtx->pOut->iCountNals = iCountNals; SLayerBSInfo* pLBI1, *pLBI2; pLBI1 = &pFrameBsInfo->sLayerInfo[0]; pLBI1->pNalLengthInByte = pCtx->pOut->pNalLen; while (pLBI1 != pLayerBsInfo) { pLBI2 = pLBI1; ++ pLBI1; pLBI1->pNalLengthInByte = pLBI2->pNalLengthInByte + pLBI2->iNalCount; } return ENC_RETURN_SUCCESS; } int32_t SliceBufferRealloc (sWelsEncCtx* pCtx) { CMemoryAlign* pMA = pCtx->pMemAlign; SDqLayer* pCurLayer = pCtx->pCurDqLayer; int32_t iMaxSliceNumOld = pCurLayer->sSliceEncCtx.iMaxSliceNumConstraint; int32_t iMaxSliceNum = iMaxSliceNumOld; iMaxSliceNum *= SLICE_NUM_EXPAND_COEF; SSlice* pSlice = (SSlice*)pMA->WelsMallocz (sizeof (SSlice) * iMaxSliceNum, "Slice"); if (NULL == pSlice) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::DynSliceRealloc: pSlice is NULL"); return ENC_RETURN_MEMALLOCERR; } memcpy (pSlice, pCurLayer->sLayerInfo.pSliceInLayer, sizeof (SSlice) * iMaxSliceNumOld); int32_t uiSliceIdx; uiSliceIdx = iMaxSliceNumOld; SSlice* pBaseSlice = &pCurLayer->sLayerInfo.pSliceInLayer[0]; SSliceHeaderExt* pBaseSHExt = &pBaseSlice->sSliceHeaderExt; SSlice* pSliceIdx = &pSlice[uiSliceIdx]; const int32_t kiCurDid = pCtx->uiDependencyId; const int32_t kiBitsPerMb = WELS_DIV_ROUND (pCtx->pWelsSvcRc[kiCurDid].iTargetBits * INT_MULTIPLY, pCtx->pWelsSvcRc[kiCurDid].iNumberMbFrame); while (uiSliceIdx < iMaxSliceNum) { SSliceHeaderExt* pSHExt = &pSliceIdx->sSliceHeaderExt; pSliceIdx->uiSliceIdx = uiSliceIdx; if (pCtx->pSvcParam->iMultipleThreadIdc > 1) pSliceIdx->pSliceBsa = &pSliceIdx->sSliceBs.sBsWrite; else pSliceIdx->pSliceBsa = &pCtx->pOut->sBsWrite; if (AllocMbCacheAligned (&pSliceIdx->sMbCacheInfo, pMA)) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::DynSliceRealloc: realloc MbCache not successful at slice_idx=%d (max-slice=%d)", uiSliceIdx, iMaxSliceNum); return ENC_RETURN_MEMALLOCERR; } pSliceIdx->bSliceHeaderExtFlag = pBaseSlice->bSliceHeaderExtFlag; pSHExt->sSliceHeader.iPpsId = pBaseSHExt->sSliceHeader.iPpsId; pSHExt->sSliceHeader.pPps = pBaseSHExt->sSliceHeader.pPps; pSHExt->sSliceHeader.iSpsId = pBaseSHExt->sSliceHeader.iSpsId; pSHExt->sSliceHeader.pSps = pBaseSHExt->sSliceHeader.pSps; pSHExt->sSliceHeader.uiRefCount = pCtx->iNumRef0; memcpy (&pSHExt->sSliceHeader.sRefMarking, &pBaseSHExt->sSliceHeader.sRefMarking, sizeof (SRefPicMarking)); memcpy (&pSHExt->sSliceHeader.sRefReordering, &pBaseSHExt->sSliceHeader.sRefReordering, sizeof (SRefPicListReorderSyntax)); pSliceIdx->sSlicingOverRc.iComplexityIndexSlice = 0; pSliceIdx->sSlicingOverRc.iCalculatedQpSlice = pCtx->iGlobalQp; pSliceIdx->sSlicingOverRc.iTotalQpSlice = 0; pSliceIdx->sSlicingOverRc.iTotalMbSlice = 0; pSliceIdx->sSlicingOverRc.iTargetBitsSlice = WELS_DIV_ROUND (kiBitsPerMb * pSlice[uiSliceIdx].iCountMbNumInSlice, INT_MULTIPLY); pSliceIdx->sSlicingOverRc.iFrameBitsSlice = 0; pSliceIdx->sSlicingOverRc.iGomBitsSlice = 0; pSliceIdx++; uiSliceIdx++; } pMA->WelsFree (pCurLayer->sLayerInfo.pSliceInLayer, "Slice"); pCurLayer->sLayerInfo.pSliceInLayer = pSlice; if (pCtx->iMaxSliceCount < iMaxSliceNum) pCtx->iMaxSliceCount = iMaxSliceNum; pCurLayer->sSliceEncCtx.iMaxSliceNumConstraint = iMaxSliceNum; pCurLayer->iMaxSliceNum = iMaxSliceNum; return ENC_RETURN_SUCCESS; } int32_t DynSliceRealloc (sWelsEncCtx* pCtx, SFrameBSInfo* pFrameBsInfo, SLayerBSInfo* pLayerBsInfo) { int32_t iRet = 0; iRet = FrameBsRealloc (pCtx, pFrameBsInfo, pLayerBsInfo); if (ENC_RETURN_SUCCESS != iRet) return iRet; iRet = SliceBufferRealloc (pCtx); return iRet; } int32_t WelsCodeOnePicPartition (sWelsEncCtx* pCtx, SFrameBSInfo* pFrameBSInfo, SLayerBSInfo* pLayerBsInfo, int32_t* pNalIdxInLayer, int32_t* pLayerSize, int32_t iFirstMbInPartition, // first mb inclusive in partition int32_t iEndMbInPartition, // end mb exclusive in partition int32_t iStartSliceIdx ) { SDqLayer* pCurLayer = pCtx->pCurDqLayer; SSliceCtx* pSliceCtx = &pCurLayer->sSliceEncCtx; SSlice* pSliceInLayer = pCurLayer->sLayerInfo.pSliceInLayer; SSlice* pStartSlice = &pSliceInLayer[iStartSliceIdx]; int32_t iNalIdxInLayer = *pNalIdxInLayer; int32_t iSliceIdx = iStartSliceIdx; const int32_t kiSliceStep = pCtx->iActiveThreadsNum; const int32_t kiPartitionId = iStartSliceIdx % kiSliceStep; int32_t iPartitionBsSize = 0; int32_t iAnyMbLeftInPartition = iEndMbInPartition - iFirstMbInPartition; const EWelsNalUnitType keNalType = pCtx->eNalType; const EWelsNalRefIdc keNalRefIdc = pCtx->eNalPriority; const bool kbNeedPrefix = pCtx->bNeedPrefixNalFlag; const int32_t kiSliceIdxStep = pCtx->iActiveThreadsNum; int32_t iReturn = ENC_RETURN_SUCCESS; //init { pStartSlice->sSliceHeaderExt.sSliceHeader.iFirstMbInSlice = iFirstMbInPartition; pCurLayer->pNumSliceCodedOfPartition[kiPartitionId] = 1; // one slice per partition intialized, dynamic slicing inside pCurLayer->pLastMbIdxOfPartition[kiPartitionId] = iEndMbInPartition - 1; } pCurLayer->pLastCodedMbIdxOfPartition[kiPartitionId] = 0; while (iAnyMbLeftInPartition > 0) { int32_t iSliceSize = 0; int32_t iPayloadSize = 0; if (iSliceIdx >= (pSliceCtx->iMaxSliceNumConstraint - kiSliceIdxStep)) { // insufficient memory in pSliceInLayer[] if (pCtx->iActiveThreadsNum == 1) { //only single thread support re-alloc now if (DynSliceRealloc (pCtx, pFrameBSInfo, pLayerBsInfo)) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::WelsCodeOnePicPartition: DynSliceRealloc not successful"); return ENC_RETURN_MEMALLOCERR; } } else if (iSliceIdx >= pSliceCtx->iMaxSliceNumConstraint) { WelsLog (& (pCtx->sLogCtx), WELS_LOG_ERROR, "CWelsH264SVCEncoder::WelsCodeOnePicPartition: iSliceIdx(%d) over iMaxSliceNumConstraint(%d)", iSliceIdx, pSliceCtx->iMaxSliceNumConstraint); return ENC_RETURN_MEMALLOCERR; } } if (kbNeedPrefix) { iReturn = AddPrefixNal (pCtx, pLayerBsInfo, &pLayerBsInfo->pNalLengthInByte[0], &iNalIdxInLayer, keNalType, keNalRefIdc, iPayloadSize); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) iPartitionBsSize += iPayloadSize; } WelsLoadNal (pCtx->pOut, keNalType, keNalRefIdc); iReturn = WelsCodeOneSlice (pCtx, iSliceIdx, keNalType); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) WelsUnloadNal (pCtx->pOut); iReturn = WelsEncodeNal (&pCtx->pOut->sNalList[pCtx->pOut->iNalIndex - 1], &pCtx->pCurDqLayer->sLayerInfo.sNalHeaderExt, pCtx->iFrameBsSize - pCtx->iPosBsBuffer, pCtx->pFrameBs + pCtx->iPosBsBuffer, &pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]); WELS_VERIFY_RETURN_IFNEQ (iReturn, ENC_RETURN_SUCCESS) iSliceSize = pLayerBsInfo->pNalLengthInByte[iNalIdxInLayer]; pCtx->iPosBsBuffer += iSliceSize; iPartitionBsSize += iSliceSize; #if defined(SLICE_INFO_OUTPUT) fprintf (stderr, "@slice=%-6d sliceType:%c idc:%d size:%-6d\n", iSliceIdx, (pCtx->eSliceType == P_SLICE ? 'P' : 'I'), keNalRefIdc, iSliceSize); #endif//SLICE_INFO_OUTPUT ++ iNalIdxInLayer; iSliceIdx += kiSliceStep; //if uiSliceIdx is not continuous iAnyMbLeftInPartition = iEndMbInPartition - (1 + pCurLayer->pLastCodedMbIdxOfPartition[kiPartitionId]); } *pLayerSize = iPartitionBsSize; *pNalIdxInLayer = iNalIdxInLayer; // slice based packing??? pLayerBsInfo->uiLayerType = VIDEO_CODING_LAYER; pLayerBsInfo->uiSpatialId = pCtx->uiDependencyId; pLayerBsInfo->uiTemporalId = pCtx->uiTemporalId; pLayerBsInfo->uiQualityId = 0; pLayerBsInfo->iNalCount = iNalIdxInLayer; return ENC_RETURN_SUCCESS; } } // namespace WelsEnc