/* * Copyright (c) 2017-2021, Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. */ //! //! \file codechal_decode_hevc_g12.cpp //! \brief Implements the decode interface extension for HEVC. //! \details Implements all functions required by CodecHal for HEVC decoding. //! #include "codechal_decoder.h" #include "codechal_secure_decode_interface.h" #include "codechal_decode_hevc_g12.h" #include "codechal_decode_hevc_long_g12.h" #include "codechal_decode_sfc_hevc_g12.h" #include "mhw_vdbox_hcp_g12_X.h" #include "mhw_vdbox_mfx_g12_X.h" #include "mhw_vdbox_g12_X.h" #include "mhw_mi_g12_X.h" #include "codechal_mmc_decode_hevc_g12.h" #include "codechal_hw_g12_X.h" #include "codechal_decode_histogram.h" #include "codechal_debug.h" #include "hal_oca_interface.h" //========================================================= MOS_STATUS CodechalDecodeHevcG12::AllocateResourcesVariableSizes () { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; uint8_t maxBitDepth = (m_is12BitHevc) ? 12: ((m_is10BitHevc) ? 10 : 8); uint8_t chromaFormatPic = m_hevcPicParams->chroma_format_idc; uint8_t chromaFormat = m_chromaFormatinProfile; CODECHAL_DECODE_ASSERT(chromaFormat >= chromaFormatPic); uint32_t widthMax = MOS_MAX(m_width, m_widthLastMaxAlloced); uint32_t heightMax = MOS_MAX(m_height, m_heightLastMaxAlloced); uint32_t frameSizeMax = MOS_MAX((m_copyDataBufferInUse ? m_copyDataBufferSize : m_dataSize), m_frameSizeMaxAlloced); uint32_t ctbLog2SizeYPic = m_hevcPicParams->log2_diff_max_min_luma_coding_block_size + m_hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3; uint32_t ctbLog2SizeY = MOS_MAX(ctbLog2SizeYPic, m_ctbLog2SizeYMax); //for Scalability if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { MHW_VDBOX_HCP_BUFFER_REALLOC_PARAMS reallocParam; MOS_ZeroMemory(&reallocParam, sizeof(reallocParam)); reallocParam.ucMaxBitDepth = maxBitDepth; reallocParam.ucChromaFormat = chromaFormat; reallocParam.dwCtbLog2SizeY = ctbLog2SizeY; reallocParam.dwCtbLog2SizeYMax = m_ctbLog2SizeYMax; reallocParam.dwPicWidth = widthMax; reallocParam.dwPicWidthAlloced = m_widthLastMaxAlloced; reallocParam.dwPicHeight = heightMax; reallocParam.dwPicHeightAlloced = m_heightLastMaxAlloced; reallocParam.dwFrameSize = frameSizeMax; reallocParam.dwFrameSizeAlloced = m_frameSizeMaxAlloced; MHW_VDBOX_HCP_BUFFER_SIZE_PARAMS hcpBufSizeParam; MOS_ZeroMemory(&hcpBufSizeParam, sizeof(hcpBufSizeParam)); hcpBufSizeParam.ucMaxBitDepth = maxBitDepth; hcpBufSizeParam.ucChromaFormat = chromaFormat; hcpBufSizeParam.dwCtbLog2SizeY = ctbLog2SizeY; hcpBufSizeParam.dwPicWidth = widthMax; hcpBufSizeParam.dwPicHeight = heightMax; hcpBufSizeParam.dwMaxFrameSize = frameSizeMax; CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_AllocateResources_VariableSizes_G12( m_scalabilityState, &hcpBufSizeParam, &reallocParam)); m_frameSizeMaxAlloced = frameSizeMax; } if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { bool isNeedBiggerSize = (widthMax > m_widthLastMaxAlloced) || (heightMax > m_heightLastMaxAlloced); bool isResourceNull = Mos_ResourceIsNull(&m_resRefBeforeLoopFilter.OsResource); if (isNeedBiggerSize || isResourceNull) { if (!isResourceNull) { DestroySurface(&m_resRefBeforeLoopFilter); } // allocate an internal temporary buffer as reference which holds pixels before in-loop filter CODECHAL_DECODE_CHK_STATUS_RETURN(AllocateResourceRefBefLoopFilter()); } } // Reallocate second level batch buffer if it is needed if (!m_cencBuf) { uint32_t count, size; if (m_isRealTile) { count = m_hevcPicParams->num_tile_columns_minus1 + 1; size = m_standardDecodeSizeNeeded * (m_decodeParams.m_numSlices + 1 + m_hevcPicParams->num_tile_rows_minus1); } else if (m_isSeparateTileDecoding) { count = 1; size = m_standardDecodeSizeNeeded * (m_decodeParams.m_numSlices + (m_hevcPicParams->num_tile_rows_minus1 + 1) * (m_hevcPicParams->num_tile_columns_minus1 + 1)); } else { count = 1; size = m_standardDecodeSizeNeeded * m_decodeParams.m_numSlices; } if ((!Mos_ResourceIsNull(&m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].OsResource) && (size > (uint32_t)m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iSize)) || (count > m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].count)) { Mhw_FreeBb(m_osInterface, &m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex], nullptr); } if (Mos_ResourceIsNull(&m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].OsResource)) { MOS_ZeroMemory(&m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex], sizeof(MHW_BATCH_BUFFER)); CODECHAL_DECODE_CHK_STATUS_RETURN(Mhw_AllocateBb( m_osInterface, &m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex], nullptr, size, count)); m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].bSecondLevel = true; } } CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeHevc::AllocateResourcesVariableSizes()); #ifdef _MMC_SUPPORTED // To WA invalid aux data caused HW issue when MMC on if (m_mmc && m_mmc->IsMmcEnabled() && MEDIA_IS_WA(m_waTable, Wa_1408785368) && !Mos_ResourceIsNull(&m_destSurface.OsResource) && m_destSurface.OsResource.bConvertedFromDDIResource) { if (m_secureDecoder && m_secureDecoder->IsAuxDataInvalid(&m_destSurface.OsResource)) { // Not use CODECHAL_DECODE_CHK_STATUS_RETURN() here to avoid adding local variable // Error can still be caught by CODECHAL_DECODE_CHK_STATUS_RETURN() in InitAuxSurface eStatus = m_secureDecoder->InitAuxSurface(&m_destSurface.OsResource, false, true); } else { CODECHAL_DECODE_VERBOSEMESSAGE("Clear CCS by VE resolve before frame %d submission", m_frameNum); CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnDecompResource(m_osInterface, &m_destSurface.OsResource)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSetGpuContext(m_osInterface, m_videoContext)); } } #endif return eStatus; } MOS_STATUS CodechalDecodeHevcG12::AllocateResourceRefBefLoopFilter() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (!Mos_ResourceIsNull(&m_resRefBeforeLoopFilter.OsResource)) { return MOS_STATUS_SUCCESS; } MOS_SURFACE surface; MOS_ZeroMemory(&surface, sizeof(MOS_SURFACE)); CODECHAL_DECODE_CHK_STATUS_MESSAGE_RETURN(AllocateSurface( &surface, m_destSurface.dwPitch, m_destSurface.dwHeight, "Reference before loop filter", m_destSurface.Format, m_destSurface.bCompressible), "Failed to allocate reference before loop filter for IBC."); m_resRefBeforeLoopFilter = surface; return eStatus; } MOS_STATUS CodechalDecodeHevcG12::AllocateHistogramSurface() { MOS_ALLOC_GFXRES_PARAMS allocParams; if (m_histogramSurface == nullptr) { m_histogramSurface = (MOS_SURFACE*)MOS_AllocAndZeroMemory(sizeof(MOS_SURFACE)); CODECHAL_DECODE_CHK_NULL_RETURN(m_histogramSurface); MOS_ZeroMemory(&allocParams, sizeof(MOS_ALLOC_GFXRES_PARAMS)); allocParams.Type = MOS_GFXRES_BUFFER; allocParams.TileType = MOS_TILE_LINEAR; allocParams.Format = Format_Buffer; allocParams.dwBytes = 256 * 4; allocParams.pBufName = "HistogramStreamOut"; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnAllocateResource( m_osInterface, &allocParams, &m_histogramSurface->OsResource)); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalGetResourceInfo( m_osInterface, m_histogramSurface)); } if(m_decodeHistogram) m_decodeHistogram->SetSrcHistogramSurface(m_histogramSurface); return MOS_STATUS_SUCCESS; } CodechalDecodeHevcG12::~CodechalDecodeHevcG12 () { CODECHAL_DECODE_FUNCTION_ENTER; if (m_sinlgePipeVeState) { MOS_FreeMemAndSetNull(m_sinlgePipeVeState); } if (m_scalabilityState) { CodecHalDecodeScalability_Destroy_G12(m_scalabilityState); MOS_FreeMemAndSetNull(m_scalabilityState); } if (!Mos_ResourceIsNull(&m_resRefBeforeLoopFilter.OsResource)) { DestroySurface(&m_resRefBeforeLoopFilter); } for (uint32_t i = 0; i < CODEC_HEVC_NUM_SECOND_BB; i++) { if (!Mos_ResourceIsNull(&m_secondLevelBatchBuffer[i].OsResource)) { Mhw_FreeBb(m_osInterface, &m_secondLevelBatchBuffer[i], nullptr); } } //Note: virtual engine interface destroy is done in MOS layer #if (_DEBUG || _RELEASE_INTERNAL) // Report real tile frame count and virtual tile frame count MOS_USER_FEATURE_VALUE_WRITE_DATA userFeatureWriteData = __NULL_USER_FEATURE_VALUE_WRITE_DATA__; userFeatureWriteData.Value.i32Data = m_rtFrameCount; userFeatureWriteData.ValueID = __MEDIA_USER_FEATURE_VALUE_ENABLE_HEVC_DECODE_RT_FRAME_COUNT_ID; MOS_UserFeature_WriteValues_ID(nullptr, &userFeatureWriteData, 1, m_osInterface->pOsContext); userFeatureWriteData.Value.i32Data = m_vtFrameCount; userFeatureWriteData.ValueID = __MEDIA_USER_FEATURE_VALUE_ENABLE_HEVC_DECODE_VT_FRAME_COUNT_ID; MOS_UserFeature_WriteValues_ID(nullptr, &userFeatureWriteData, 1, m_osInterface->pOsContext); userFeatureWriteData.Value.i32Data = m_spFrameCount; userFeatureWriteData.ValueID = __MEDIA_USER_FEATURE_VALUE_ENABLE_HEVC_DECODE_SP_FRAME_COUNT_ID; MOS_UserFeature_WriteValues_ID(nullptr, &userFeatureWriteData, 1, m_osInterface->pOsContext); #endif if (m_histogramSurface) { if (!Mos_ResourceIsNull(&m_histogramSurface->OsResource)) { m_osInterface->pfnFreeResource( m_osInterface, &m_histogramSurface->OsResource); } MOS_FreeMemory(m_histogramSurface); m_histogramSurface = nullptr; } return; } MOS_STATUS CodechalDecodeHevcG12::CheckLCUSize() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; uint16_t LCUSize = 1 << (m_hevcPicParams->log2_diff_max_min_luma_coding_block_size + m_hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3); if (m_width > CODECHAL_HEVC_MAX_DIM_FOR_MIN_LCU || m_height > CODECHAL_HEVC_MAX_DIM_FOR_MIN_LCU) { if (LCUSize == CODECHAL_HEVC_MIN_LCU) { CODECHAL_DECODE_ASSERTMESSAGE("Invalid LCU size."); return MOS_STATUS_INVALID_PARAMETER; } } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SetGpuCtxCreatOption( CodechalSetting *codecHalSetting) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (!MOS_VE_CTXBASEDSCHEDULING_SUPPORTED(m_osInterface)) { CodechalDecode::SetGpuCtxCreatOption(codecHalSetting); } else { m_gpuCtxCreatOpt = MOS_New(MOS_GPUCTX_CREATOPTIONS_ENHANCED); CODECHAL_DECODE_CHK_NULL_RETURN(m_gpuCtxCreatOpt); if (static_cast(m_mfxInterface)->IsScalabilitySupported()) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeScalability_ConstructParmsForGpuCtxCreation_g12( m_scalabilityState, (PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt, codecHalSetting)); if (((PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt)->LRCACount == 2) { m_videoContext = MOS_VE_MULTINODESCALING_SUPPORTED(m_osInterface) ? MOS_GPU_CONTEXT_VIDEO5 : MOS_GPU_CONTEXT_VDBOX2_VIDEO;; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnCreateGpuContext( m_osInterface, m_videoContext, MOS_GPU_NODE_VIDEO, m_gpuCtxCreatOpt)); MOS_GPUCTX_CREATOPTIONS createOption; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnCreateGpuContext( m_osInterface, MOS_GPU_CONTEXT_VIDEO, m_videoGpuNode, &createOption)); } else if (((PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt)->LRCACount == 3) { m_videoContext = MOS_VE_MULTINODESCALING_SUPPORTED(m_osInterface) ? MOS_GPU_CONTEXT_VIDEO7 : MOS_GPU_CONTEXT_VDBOX2_VIDEO2; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnCreateGpuContext( m_osInterface, m_videoContext, MOS_GPU_NODE_VIDEO, m_gpuCtxCreatOpt)); MOS_GPUCTX_CREATOPTIONS createOption; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnCreateGpuContext( m_osInterface, MOS_GPU_CONTEXT_VIDEO, m_videoGpuNode, &createOption)); } else { m_videoContext = MOS_GPU_CONTEXT_VIDEO; } } else { bool sfcInUse = (codecHalSetting->sfcInUseHinted && codecHalSetting->downsamplingHinted && (MEDIA_IS_SKU(m_skuTable, FtrSFCPipe) && !MEDIA_IS_SKU(m_skuTable, FtrDisableVDBox2SFC))); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_ConstructParmsForGpuCtxCreation( m_sinlgePipeVeState, (PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt, sfcInUse)); m_videoContext = MOS_GPU_CONTEXT_VIDEO; } } return eStatus; } uint32_t CodechalDecodeHevcG12::GetDmemBufferSize() { return MOS_ALIGN_CEIL(sizeof(HUC_HEVC_S2L_BSS_G12), CODECHAL_CACHELINE_SIZE); } MOS_STATUS CodechalDecodeHevcG12::SetHucDmemS2LPictureBss( PHUC_HEVC_S2L_PIC_BSS hucHevcS2LPicBss) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(hucHevcS2LPicBss); CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeHevc::SetHucDmemS2LPictureBss(hucHevcS2LPicBss)); if (m_hevcExtPicParams) { hucHevcS2LPicBss->high_precision_offsets_enabled_flag = m_hevcExtPicParams->PicRangeExtensionFlags.fields.high_precision_offsets_enabled_flag; hucHevcS2LPicBss->chroma_qp_offset_list_enabled_flag = m_hevcExtPicParams->PicRangeExtensionFlags.fields.chroma_qp_offset_list_enabled_flag; } else { hucHevcS2LPicBss->high_precision_offsets_enabled_flag = 0; hucHevcS2LPicBss->chroma_qp_offset_list_enabled_flag = 0; } PHUC_HEVC_S2L_PIC_BSS_G12 hucHevcS2LPicBssG12 = static_cast(hucHevcS2LPicBss); hucHevcS2LPicBssG12->IsRealTileEnable = 0; if (m_isRealTile) { hucHevcS2LPicBssG12->IsRealTileEnable = 1; hucHevcS2LPicBssG12->BatchBufferSize = m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iSize; hucHevcS2LPicBssG12->NumScalablePipes = m_scalabilityState->ucScalablePipeNum; } else if (CodecHalDecodeNeedsTileDecoding(m_hevcPicParams, m_hevcSccPicParams)) { hucHevcS2LPicBssG12->NumScalablePipes = 1; } hucHevcS2LPicBssG12->IsSCCIBCMode = CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams); hucHevcS2LPicBssG12->IsSCCPLTMode = CodecHalDecodeIsSCCPLTMode(m_hevcSccPicParams); if (hucHevcS2LPicBssG12->IsSCCIBCMode) { uint8_t i = 0, k = 0; for (i = 0; i < CODEC_MAX_NUM_REF_FRAME_HEVC; i++) { if (hucHevcS2LPicBssG12->PicOrderCntValList[i] == hucHevcS2LPicBssG12->CurrPicOrderCntVal) { break; } } for (k = 0; k < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; k++) { if (hucHevcS2LPicBssG12->RefPicSetLtCurr[k] == 0xFF) { hucHevcS2LPicBssG12->RefPicSetLtCurr[k] = i; break; } } } if (hucHevcS2LPicBssG12->IsSCCPLTMode) { hucHevcS2LPicBssG12->PredictorPaletteSize = m_hevcSccPicParams->PredictorPaletteSize; MOS_SecureMemcpy(hucHevcS2LPicBssG12->PredictorPaletteEntries, sizeof(hucHevcS2LPicBssG12->PredictorPaletteEntries), m_hevcSccPicParams->PredictorPaletteEntries, sizeof(m_hevcSccPicParams->PredictorPaletteEntries)); } else { hucHevcS2LPicBssG12->PredictorPaletteSize = 0; MOS_ZeroMemory(hucHevcS2LPicBssG12->PredictorPaletteEntries, sizeof(hucHevcS2LPicBssG12->PredictorPaletteEntries)); } if (m_hevcSccPicParams) { hucHevcS2LPicBssG12->UseSliceACTOffset = m_hevcSccPicParams->PicSCCExtensionFlags.fields.pps_slice_act_qp_offsets_present_flag; hucHevcS2LPicBssG12->pps_act_y_qp_offset = m_hevcSccPicParams->pps_act_y_qp_offset_plus5 - 5; hucHevcS2LPicBssG12->pps_act_cb_qp_offset = m_hevcSccPicParams->pps_act_cb_qp_offset_plus5 - 5; hucHevcS2LPicBssG12->pps_act_cr_qp_offset = m_hevcSccPicParams->pps_act_cr_qp_offset_plus3 - 3; hucHevcS2LPicBssG12->MVRControlIdc = m_hevcSccPicParams->PicSCCExtensionFlags.fields.motion_vector_resolution_control_idc; } else { hucHevcS2LPicBssG12->UseSliceACTOffset = 0; hucHevcS2LPicBssG12->pps_act_y_qp_offset = 0; hucHevcS2LPicBssG12->pps_act_cb_qp_offset = 0; hucHevcS2LPicBssG12->pps_act_cr_qp_offset = 0; hucHevcS2LPicBssG12->MVRControlIdc = 0; } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::CalcDownsamplingParams( void *picParams, uint32_t *refSurfWidth, uint32_t *refSurfHeight, MOS_FORMAT *format, uint8_t *frameIdx) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_CHK_NULL_RETURN(picParams); CODECHAL_DECODE_CHK_NULL_RETURN(refSurfWidth); CODECHAL_DECODE_CHK_NULL_RETURN(refSurfHeight); CODECHAL_DECODE_CHK_NULL_RETURN(format); CODECHAL_DECODE_CHK_NULL_RETURN(frameIdx); PCODEC_HEVC_PIC_PARAMS hevcPicParams = (PCODEC_HEVC_PIC_PARAMS)picParams; *refSurfWidth = 0; *refSurfHeight = 0; *format = Format_NV12; *frameIdx = hevcPicParams->CurrPic.FrameIdx; uint32_t widthInPix, heightInPix; widthInPix = (1 << (hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3)) * (hevcPicParams->PicWidthInMinCbsY); heightInPix = (1 << (hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3)) * (hevcPicParams->PicHeightInMinCbsY); *refSurfWidth = MOS_ALIGN_CEIL(widthInPix, 64); *refSurfHeight = MOS_ALIGN_CEIL(heightInPix, 64); if (hevcPicParams->chroma_format_idc == HCP_CHROMA_FORMAT_YUV444) { if (hevcPicParams->bit_depth_luma_minus8 > 2 || hevcPicParams->bit_depth_chroma_minus8 > 2) { *format = Format_Y416; } else if (hevcPicParams->bit_depth_luma_minus8 > 0 || hevcPicParams->bit_depth_chroma_minus8 > 0) { *format = Format_Y410; } else { *format = Format_AYUV; } } else if (hevcPicParams->chroma_format_idc == HCP_CHROMA_FORMAT_YUV422) { if (hevcPicParams->bit_depth_luma_minus8 > 2 || hevcPicParams->bit_depth_chroma_minus8 > 2) { *format = Format_Y216; } else if (hevcPicParams->bit_depth_luma_minus8 > 0 || hevcPicParams->bit_depth_chroma_minus8 > 0) { *format = Format_Y210; } else { *format = Format_YUY2; } } else { if (hevcPicParams->bit_depth_luma_minus8 > 2 || hevcPicParams->bit_depth_chroma_minus8 > 2) { *format = Format_P016; } else if (hevcPicParams->bit_depth_luma_minus8 > 0 || hevcPicParams->bit_depth_chroma_minus8 > 0) { *format = Format_P010; } else { *format = Format_NV12; } } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SetHucDmemParams ( PMOS_RESOURCE dmemBuffer) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(dmemBuffer); CodechalResLock DmemLock(m_osInterface, dmemBuffer); PHUC_HEVC_S2L_BSS_G12 hucHevcS2LBss = (PHUC_HEVC_S2L_BSS_G12)DmemLock.Lock(CodechalResLock::writeOnly); CODECHAL_DECODE_CHK_NULL_RETURN(hucHevcS2LBss); hucHevcS2LBss->PictureBss.reserve.reserve_0 = 0; hucHevcS2LBss->PictureBss.reserve.reserve_1 = 0; hucHevcS2LBss->PictureBss.reserve.reserve_2 = 0; hucHevcS2LBss->PictureBss.reserve.reserve_3 = 0; hucHevcS2LBss->ProductFamily = m_hucInterface->GetHucProductFamily(); hucHevcS2LBss->RevId = m_hwInterface->GetPlatform().usRevId; hucHevcS2LBss->DummyRefIdxState = MEDIA_IS_WA(m_waTable, WaDummyReference) && !m_osInterface->bSimIsActive; hucHevcS2LBss->DummyVDControlState = MEDIA_IS_WA(m_waTable, Wa_14010222001); hucHevcS2LBss->WaTileFlushScalability = MEDIA_IS_WA(m_waTable, Wa_2209620131); CODECHAL_DECODE_CHK_STATUS_RETURN(SetHucDmemS2LPictureBss(&hucHevcS2LBss->PictureBss)); CODECHAL_DECODE_CHK_STATUS_RETURN(SetHucDmemS2LSliceBss(&hucHevcS2LBss->SliceBss[0])); if (m_secureDecoder) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_secureDecoder->SetHevcHucDmemS2LBss(this, &hucHevcS2LBss->PictureBss, &hucHevcS2LBss->SliceBss[0])); } if (m_numSlices < CODECHAL_HEVC_MAX_NUM_SLICES_LVL_6) { m_dmemTransferSize = (uint32_t)((uint8_t *)&(hucHevcS2LBss->SliceBss[m_numSlices]) - (uint8_t *)hucHevcS2LBss); m_dmemTransferSize = MOS_ALIGN_CEIL(m_dmemTransferSize, CODECHAL_CACHELINE_SIZE); } else { m_dmemTransferSize = m_dmemBufferSize; } return eStatus; } MOS_STATUS CodechalDecodeHevcG12 ::InitializeDecodeMode() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (MOS_VE_SUPPORTED(m_osInterface) && static_cast(m_mfxInterface)->IsScalabilitySupported()) { CODECHAL_DECODE_SCALABILITY_INIT_PARAMS_G12 initParams; MOS_ZeroMemory(&initParams, sizeof(initParams)); initParams.u32PicWidthInPixel = m_width; initParams.u32PicHeightInPixel = m_height; initParams.bIsTileEnabled = m_hevcPicParams->tiles_enabled_flag; initParams.bHasSubsetParams = !!m_decodeParams.m_subsetParams; initParams.format = m_decodeParams.m_destSurface->Format; initParams.usingSecureDecode = (m_secureDecoder != nullptr); if (m_decodeHistogram == nullptr) { initParams.usingHistogram = false; #if (_DEBUG || _RELEASE_INTERNAL) if (m_histogramDebug) { initParams.usingHistogram = true; } #endif } else { initParams.usingHistogram = true; } // Only support SCC real tile mode. SCC virtual tile scalability mode is disabled here initParams.bIsSccDecoding = m_hevcSccPicParams != nullptr; initParams.u8NumTileColumns = m_hevcPicParams->num_tile_columns_minus1 + 1; initParams.u8NumTileRows = m_hevcPicParams->num_tile_rows_minus1 + 1; initParams.gpuCtxInUse = GetVideoContext(); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_InitScalableParams_G12( m_scalabilityState, &initParams, &m_decodePassNum)); if (MOS_VE_CTXBASEDSCHEDULING_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeScalability_ChkGpuCtxReCreation( m_scalabilityState, (PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt)); SetVideoContext(m_scalabilityState->VideoContext); } m_isRealTile = CodecHalDecodeScalabilityIsRealTileMode(m_scalabilityState); if (m_isRealTile) { m_isSeparateTileDecoding = false; } m_isVirtualTile = CodecHalDecodeScalabilityIsVirtualTileMode(m_scalabilityState); #if (_DEBUG || _RELEASE_INTERNAL) if (m_isRealTile) { m_rtFrameCount++; } else if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { m_vtFrameCount++; } else if (m_isSeparateTileDecoding) { m_spFrameCount++; } #endif } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SetFrameStates () { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; PERF_UTILITY_AUTO(__FUNCTION__, PERF_DECODE, PERF_LEVEL_HAL); CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(m_decodeParams.m_destSurface); CODECHAL_DECODE_CHK_NULL_RETURN(m_decodeParams.m_dataBuffer); if (m_secureDecoder) { m_secureDecoder->EnableSampleGroupConstantIV(); } m_frameIdx++; // Check HuC_status2 Imem loaded bit, if 0,return error // As driver doesn't know when can get reg value afer storing HuC_Status2 register, // Check the reg value here at the beginning of next frame // Check twice, first entry and second entry if (m_shortFormatInUse && m_frameIdx < 3 && m_statusQueryReportingEnabled && (((m_decodeStatusBuf.m_decodeStatus->m_hucErrorStatus2 >> 32) & m_hucInterface->GetHucStatus2ImemLoadedMask()) == 0)) { if (!m_reportHucStatus) { MOS_USER_FEATURE_VALUE_WRITE_DATA userFeatureWriteData; MOS_ZeroMemory(&userFeatureWriteData, sizeof(userFeatureWriteData)); userFeatureWriteData.Value.i32Data = true; userFeatureWriteData.ValueID = __MEDIA_USER_FEATURE_VALUE_HUC_LOAD_STATUS_ID; MOS_UserFeature_WriteValues_ID(nullptr, &userFeatureWriteData, 1, m_osInterface->pOsContext); m_reportHucStatus = true; } CODECHAL_DECODE_ASSERTMESSAGE("HuC IMEM Loaded fails"); MT_ERR1(MT_DEC_HEVC, MT_DEC_HUC_ERROR_STATUS2, (m_decodeStatusBuf.m_decodeStatus->m_hucErrorStatus2 >> 32)); return MOS_STATUS_UNKNOWN; } m_cencBuf = m_decodeParams.m_cencBuf; if (IsFirstExecuteCall()) // For DRC Multiple Execution Call, no need to update every value in pHevcState except first execute { m_dataSize = m_decodeParams.m_dataSize; m_dataOffset = m_decodeParams.m_dataOffset; m_numSlices = m_decodeParams.m_numSlices; if (m_numSlices > CODECHAL_HEVC_MAX_NUM_SLICES_LVL_6) { CODECHAL_DECODE_ASSERTMESSAGE("Slice number doesn't support!"); return MOS_STATUS_INVALID_PARAMETER; } m_hevcPicParams = (PCODEC_HEVC_PIC_PARAMS)m_decodeParams.m_picParams; m_hevcExtPicParams = (PCODEC_HEVC_EXT_PIC_PARAMS)m_decodeParams.m_extPicParams; m_hevcSccPicParams = (PCODEC_HEVC_SCC_PIC_PARAMS)m_decodeParams.m_advPicParams; CODECHAL_DECODE_CHK_NULL_RETURN(m_decodeParams.m_sliceParams); m_hevcSliceParams = (PCODEC_HEVC_SLICE_PARAMS)m_decodeParams.m_sliceParams; m_hevcExtSliceParams = (PCODEC_HEVC_EXT_SLICE_PARAMS)m_decodeParams.m_extSliceParams; m_hevcSubsetParams = (PCODEC_HEVC_SUBSET_PARAMS)m_decodeParams.m_subsetParams; m_hevcIqMatrixParams = (PCODECHAL_HEVC_IQ_MATRIX_PARAMS)m_decodeParams.m_iqMatrixBuffer; m_destSurface = *(m_decodeParams.m_destSurface); m_resDataBuffer = *(m_decodeParams.m_dataBuffer); CODECHAL_DECODE_CHK_STATUS_RETURN(InitializeBitstreamCat()); } else { m_dataSize = m_decodeParams.m_dataSize; m_dataOffset = 0; m_resDataBuffer = *(m_decodeParams.m_dataBuffer); } m_reportFrameCrc = true; CODECHAL_DECODE_CHK_STATUS_RETURN(CheckAndCopyBitstream()); PCODEC_REF_LIST destEntry = m_hevcRefList[m_hevcPicParams->CurrPic.FrameIdx]; MOS_ZeroMemory(destEntry, sizeof(CODEC_REF_LIST)); if (m_incompletePicture) { return MOS_STATUS_SUCCESS; } CODECHAL_DECODE_CHK_NULL_RETURN(m_hevcPicParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_hevcIqMatrixParams); // sanity check to make sure no same reference exists uint32_t m = 0, n = 0; for (m = 0; m < CODEC_MAX_NUM_REF_FRAME_HEVC; m++) { int32_t poc = m_hevcPicParams->PicOrderCntValList[m]; for (n = m + 1; n < CODEC_MAX_NUM_REF_FRAME_HEVC; n++) { if (poc == m_hevcPicParams->PicOrderCntValList[n]) { m_hevcPicParams->RefFrameList[n].PicFlags = PICTURE_INVALID; } } } // Calculate bCurPicIntra m_curPicIntra = true; if (m_hevcPicParams->IntraPicFlag == 0) { for (uint32_t i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { uint8_t frameIdx = m_hevcPicParams->RefPicSetStCurrBefore[i]; if (frameIdx < 15) { m_curPicIntra = false; break; } frameIdx = m_hevcPicParams->RefPicSetStCurrAfter[i]; if (frameIdx < 15) { m_curPicIntra = false; break; } frameIdx = m_hevcPicParams->RefPicSetLtCurr[i]; if (frameIdx < 15) { m_curPicIntra = false; break; } } } if (!(CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams))) { uint8_t refCurrIndex = -1; uint8_t refBeforeIndex = -1; uint8_t refAfterIndex = -1; for (int i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { uint8_t indexCurr = m_hevcPicParams->RefPicSetLtCurr[i]; uint8_t indexBefore = m_hevcPicParams->RefPicSetStCurrBefore[i]; uint8_t indexAfter = m_hevcPicParams->RefPicSetStCurrAfter[i]; if (indexCurr < CODEC_MAX_NUM_REF_FRAME_HEVC) { refCurrIndex = m_hevcPicParams->RefFrameList[indexCurr].FrameIdx; } if (indexBefore < CODEC_MAX_NUM_REF_FRAME_HEVC) { refBeforeIndex = m_hevcPicParams->RefFrameList[indexBefore].FrameIdx; } if (indexAfter < CODEC_MAX_NUM_REF_FRAME_HEVC) { refAfterIndex = m_hevcPicParams->RefFrameList[indexAfter].FrameIdx; } if ((refCurrIndex == m_hevcPicParams->CurrPic.FrameIdx) || (refBeforeIndex == m_hevcPicParams->CurrPic.FrameIdx) || (refAfterIndex == m_hevcPicParams->CurrPic.FrameIdx)) { return MOS_STATUS_INVALID_PARAMETER; } } } m_twoVersionsOfCurrDecPicFlag = 0; if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { m_curPicIntra = false; m_twoVersionsOfCurrDecPicFlag = !m_hevcPicParams->pps_deblocking_filter_disabled_flag || m_hevcPicParams->sample_adaptive_offset_enabled_flag || m_hevcPicParams->deblocking_filter_override_enabled_flag; #ifdef _MMC_SUPPORTED if (m_mmc->IsMmcEnabled()) { // Due to limitation, IBC reference has to be uncompressed, while recon surface is still compressed. // Always need internal surface for IBC reference for MMC. m_twoVersionsOfCurrDecPicFlag = true; } #endif } CODECHAL_DECODE_CHK_STATUS_RETURN(SetPictureStructs()); uint32_t i; for (i = 0; i < CODEC_MAX_NUM_REF_FRAME_HEVC; i++) { m_frameUsedAsCurRef[i] = false; m_refIdxMapping[i] = -1; } // Calculate RefIdxMapping for (i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { uint8_t frameIdx = m_hevcPicParams->RefPicSetStCurrBefore[i]; if (frameIdx < CODEC_MAX_NUM_REF_FRAME_HEVC) { m_frameUsedAsCurRef[frameIdx] = true; } frameIdx = m_hevcPicParams->RefPicSetStCurrAfter[i]; if (frameIdx < CODEC_MAX_NUM_REF_FRAME_HEVC) { m_frameUsedAsCurRef[frameIdx] = true; } frameIdx = m_hevcPicParams->RefPicSetLtCurr[i]; if (frameIdx < CODEC_MAX_NUM_REF_FRAME_HEVC) { m_frameUsedAsCurRef[frameIdx] = true; } } if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { for (i = 0; i < CODEC_MAX_NUM_REF_FRAME_HEVC; i++) { if (!CodecHal_PictureIsInvalid(m_hevcPicParams->RefFrameList[i]) && m_hevcPicParams->PicOrderCntValList[i] == m_hevcPicParams->CurrPicOrderCntVal) { m_frameUsedAsCurRef[i] = true; break; } } } uint8_t curRefIdx = 0; for (i = 0; i < CODEC_MAX_NUM_REF_FRAME_HEVC; i++) { if (m_frameUsedAsCurRef[i]) { if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { if (m_hevcPicParams->PicOrderCntValList[i] == m_hevcPicParams->CurrPicOrderCntVal) { // pre-dbk reference id for IBC mode m_IBCRefIdx = curRefIdx; } } m_refIdxMapping[i] = curRefIdx++; } } CODECHAL_DECODE_ASSERT(curRefIdx <= 8); m_minCtbSize = 1 << (m_hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3); m_width = m_hevcPicParams->PicWidthInMinCbsY * m_minCtbSize; m_height = m_hevcPicParams->PicHeightInMinCbsY * m_minCtbSize; m_ctbSize = 1 << (m_hevcPicParams->log2_diff_max_min_luma_coding_block_size + m_hevcPicParams->log2_min_luma_coding_block_size_minus3 + 3); CODECHAL_DECODE_CHK_STATUS_RETURN(CheckLCUSize()); if (m_hcpInterface->IsRowStoreCachingSupported()) { MHW_VDBOX_ROWSTORE_PARAMS rowstoreParams; rowstoreParams.Mode = CODECHAL_DECODE_MODE_HEVCVLD; rowstoreParams.dwPicWidth = m_width; rowstoreParams.bMbaff = false; rowstoreParams.ucBitDepthMinus8 = (uint8_t)MOS_MAX(m_hevcPicParams->bit_depth_luma_minus8, m_hevcPicParams->bit_depth_chroma_minus8); rowstoreParams.ucChromaFormat = m_hevcPicParams->chroma_format_idc; rowstoreParams.ucLCUSize = (uint8_t)m_ctbSize; m_hwInterface->SetRowstoreCachingOffsets(&rowstoreParams); } // Calculate Tile info if (m_hevcPicParams->tiles_enabled_flag) { CODECHAL_DECODE_CHK_STATUS_RETURN(GetAllTileInfo()); } if (m_curPicIntra) { m_perfType = I_TYPE; } else { // Not possible to determine whether P or B is used for short format. // For long format iterating through all of the slices to determine P vs // B, so in order to avoid this, declare all other pictures MIXED_TYPE. m_perfType = MIXED_TYPE; } m_crrPic = m_hevcPicParams->CurrPic; m_secondField = CodecHal_PictureIsBottomField(m_hevcPicParams->CurrPic); if (m_pCodechalOcaDumper) { m_pCodechalOcaDumper->SetHevcDecodeParam( m_hevcPicParams, m_hevcExtPicParams, m_hevcSccPicParams, m_hevcSliceParams, m_hevcExtSliceParams, m_numSlices, m_shortFormatInUse); } CODECHAL_DEBUG_TOOL( m_debugInterface->m_currPic = m_crrPic; m_debugInterface->m_secondField = m_secondField; m_debugInterface->m_frameType = m_perfType; CODECHAL_DECODE_CHK_STATUS_RETURN(DumpPicParams( m_hevcPicParams, m_hevcExtPicParams, m_hevcSccPicParams)); if (m_hevcIqMatrixParams) { CODECHAL_DECODE_CHK_STATUS_RETURN(DumpIQParams(m_hevcIqMatrixParams)); } if (m_hevcSliceParams) { CODECHAL_DECODE_CHK_STATUS_RETURN(DumpSliceParams( m_hevcSliceParams, m_hevcExtSliceParams, m_numSlices, m_shortFormatInUse)); } if(m_hevcSubsetParams) { CODECHAL_DECODE_CHK_STATUS_RETURN(DumpSubsetsParams(m_hevcSubsetParams)); }) // Clear DMEM buffer program flag if (m_shortFormatInUse) { m_dmemBufferProgrammed = false; m_dmemBufferIdx++; m_dmemBufferIdx %= CODECHAL_HEVC_NUM_DMEM_BUFFERS; } m_isSeparateTileDecoding = CodecHalDecodeNeedsTileDecoding(m_hevcPicParams, m_hevcSccPicParams); InitializeDecodeMode(); #ifdef _DECODE_PROCESSING_SUPPORTED if (m_decodeParams.m_procParams) { CodechalHevcSfcStateG12 *sfcStateG12 = static_cast(m_sfcState); CODECHAL_DECODE_CHK_NULL_RETURN(sfcStateG12); CODECHAL_DECODE_CHK_STATUS_RETURN(AllocateHistogramSurface()); CODECHAL_DECODE_CHK_STATUS_RETURN(sfcStateG12->CheckAndInitialize( (DecodeProcessingParams *)m_decodeParams.m_procParams, m_hevcPicParams, m_scalabilityState, m_histogramSurface)); } #endif CODECHAL_DEBUG_TOOL( if (!m_incompletePicture && !IsFirstExecuteCall()) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpBuffer( &m_resCopyDataBuffer, CodechalDbgAttr::attrDecodeBitstream, "_DEC", m_estiBytesInBitstream, 0, CODECHAL_NUM_MEDIA_STATES)); }) m_secondLevelBatchBufferIndex++; m_secondLevelBatchBufferIndex %= CODEC_HEVC_NUM_SECOND_BB; CODECHAL_DECODE_CHK_STATUS_RETURN(AllocateResourcesVariableSizes()); if (m_twoVersionsOfCurrDecPicFlag) { m_hevcRefList[m_hevcPicParams->CurrPic.FrameIdx]->resRefPic = m_resRefBeforeLoopFilter.OsResource; } else { m_hevcRefList[m_hevcPicParams->CurrPic.FrameIdx]->resRefPic = m_destSurface.OsResource; } m_hcpDecPhase = CodechalHcpDecodePhaseInitialized; if (!m_shortFormatInUse&&!m_cencBuf) { CodechalResLock bbLock(m_osInterface, &m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].OsResource); uint8_t *bbBase = (uint8_t*)bbLock.Lock(CodechalResLock::writeOnly); CODECHAL_DECODE_CHK_NULL_RETURN(bbBase); HevcDecodeSliceLongG12 hevcLong(this, m_hcpInterface, m_miInterface); CODECHAL_DECODE_CHK_STATUS_RETURN(hevcLong.ProcessSliceLong(bbBase, m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iSize)); } return eStatus; } //! //! \brief Determine Decode Phase //! \details Determine decode phase in hevc decode //! \param N/A //! \return MOS_STATUS //! MOS_STATUS_SUCCESS if success, else fail reason //! MOS_STATUS CodechalDecodeHevcG12::DetermineDecodePhase() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (static_cast(m_mfxInterface)->IsScalabilitySupported()) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_DetermineDecodePhase_G12( m_scalabilityState, &m_hcpDecPhase)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeHevc::DetermineDecodePhase()); } CODECHAL_DECODE_VERBOSEMESSAGE("Current Decode Phase: %d.", m_hcpDecPhase); return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SetAndPopulateVEHintParams( PMOS_COMMAND_BUFFER primCmdBuf) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (static_cast(m_mfxInterface)->IsScalabilitySupported()) { CODECHAL_DECODE_SCALABILITY_SETHINT_PARMS scalSetParms; MOS_ZeroMemory(&scalSetParms, sizeof(CODECHAL_DECODE_SCALABILITY_SETHINT_PARMS)); if (!MOS_VE_CTXBASEDSCHEDULING_SUPPORTED(m_osInterface)) { scalSetParms.bNeedSyncWithPrevious = true; scalSetParms.bSameEngineAsLastSubmission = false; scalSetParms.bSFCInUse = false; } CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_SetHintParams_G12(m_scalabilityState, &scalSetParms)); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_PopulateHintParams(m_scalabilityState, primCmdBuf)); } else { if (!MOS_VE_CTXBASEDSCHEDULING_SUPPORTED(m_osInterface)) { MOS_VIRTUALENGINE_SET_PARAMS vesetParams; MOS_ZeroMemory(&vesetParams, sizeof(vesetParams)); vesetParams.bNeedSyncWithPrevious = true; vesetParams.bSameEngineAsLastSubmission = false; vesetParams.bSFCInUse = false; CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_SetHintParams(m_sinlgePipeVeState, &vesetParams)); } CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_PopulateHintParams(m_sinlgePipeVeState, primCmdBuf, true)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::DetermineSendProlgwithFrmTracking( bool *sendPrologWithFrameTracking) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(sendPrologWithFrameTracking); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { if (CodecHalDecodeScalability1stPhaseofSubmission(m_scalabilityState) || (CodecHalDecodeScalabilityIsFirstRealTilePhase(m_scalabilityState) && (m_scalabilityState->u8RtCurPipe == 0))) { *sendPrologWithFrameTracking = true; } } else { if (m_shortFormatInUse) { *sendPrologWithFrameTracking = m_enableSf2DmaSubmits ? true : false; } else { *sendPrologWithFrameTracking = true; } } return eStatus; } uint32_t CodechalDecodeHevcG12::RequestedSpaceSize(uint32_t requestedSize) { CODECHAL_DECODE_FUNCTION_ENTER; if (m_scalabilityState && m_scalabilityState->bScalableDecodeMode) { //primary cmd buffer only including cmd buffer header . return COMMAND_BUFFER_RESERVED_SPACE * 2; } else { return requestedSize; } } void CodechalDecodeHevcG12::CalcRequestedSpace( uint32_t &requestedSize, uint32_t &additionalSizeNeeded, uint32_t &requestedPatchListSize) { if (m_isRealTile) { if (m_cencBuf) { requestedSize = m_commandBufferSizeNeeded; requestedPatchListSize = m_commandPatchListSizeNeeded; additionalSizeNeeded = 0; } else { //Since G12, HCP primitive level buffers are in separate allocated 2nd level batch buffer. So only have state level size here requestedSize = m_HcpStateCmdBufferSizeNeeded * m_scalabilityState->u8RtPhaseNum + m_HucStateCmdBufferSizeNeeded + m_HucPrimitiveCmdBufferSizeNeeded + m_CpPrimitiveCmdBufferSizeNeeded * m_numSlices; //Patch list is still submit with primitive level buffers, so requestedPatchListSize still need to contain the primitive level size. requestedPatchListSize = m_HcpPatchListSizeNeeded * m_scalabilityState->u8RtPhaseNum + m_HucPatchListSizeNeeded + m_HucPrimitivePatchListSizeNeeded + m_CpPrimitivePatchListSizeNeeded * m_numSlices + (m_standardDecodePatchListSizeNeeded * (m_decodeParams.m_numSlices + 1 + m_hevcPicParams->num_tile_rows_minus1)); additionalSizeNeeded = COMMAND_BUFFER_RESERVED_SPACE; } } else { if (m_cencBuf) { requestedSize = m_commandBufferSizeNeeded; requestedPatchListSize = m_commandPatchListSizeNeeded; additionalSizeNeeded = 0; } else { //Since G12, HCP primitive level buffers are in separate allocated 2nd level batch buffer. So only have state level size here. requestedSize = m_HcpStateCmdBufferSizeNeeded + m_HucStateCmdBufferSizeNeeded + m_HucPrimitiveCmdBufferSizeNeeded + m_CpPrimitiveCmdBufferSizeNeeded * m_numSlices; //Patch list is still submit with primitive level buffers, so requestedPatchListSize still need to contain the primitive level size. requestedPatchListSize = m_HcpPatchListSizeNeeded + m_HucPatchListSizeNeeded + m_HucPrimitivePatchListSizeNeeded + m_CpPrimitivePatchListSizeNeeded * m_numSlices + (m_standardDecodePatchListSizeNeeded * (m_decodeParams.m_numSlices + 1)); additionalSizeNeeded = COMMAND_BUFFER_RESERVED_SPACE; } } } MOS_STATUS CodechalDecodeHevcG12::VerifyExtraSpace( uint32_t requestedSize, uint32_t additionalSizeNeeded) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (m_scalabilityState && m_scalabilityState->bScalableDecodeMode) { eStatus = MOS_STATUS_NO_SPACE; // Try a maximum of 3 attempts to request the required sizes from OS // OS could reset the sizes if necessary, therefore, requires to re-verify for (auto i = 0; (i < 3) && (eStatus != MOS_STATUS_SUCCESS); i++) { // Verify secondary cmd buffer eStatus = (MOS_STATUS)m_osInterface->pfnVerifyCommandBufferSize( m_osInterface, requestedSize, MOS_VE_HAVE_SECONDARY_CMDBUFFER); // Resize command buffer if not enough if (eStatus != MOS_STATUS_SUCCESS) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnResizeCommandBufferAndPatchList( m_osInterface, requestedSize + additionalSizeNeeded, 0, MOS_VE_HAVE_SECONDARY_CMDBUFFER)); // Set status to NO_SPACE to enter the commaned buffer size verification on next loop. eStatus = MOS_STATUS_NO_SPACE; } } } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::DecodeStateLevel() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; PERF_UTILITY_AUTO(__FUNCTION__, PERF_DECODE, PERF_LEVEL_HAL); CODECHAL_DECODE_FUNCTION_ENTER; if (m_secureDecoder && m_hcpDecPhase == CodechalHcpDecodePhaseInitialized) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_secureDecoder->Execute(this)); } //HCP Decode Phase State Machine CODECHAL_DECODE_CHK_STATUS_RETURN(DetermineDecodePhase()); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { //Switch GPU context when necessary CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_SwitchGpuContext(m_scalabilityState)); } // Set HEVC Decode Phase, and execute it. if (m_shortFormatInUse && m_hcpDecPhase == CodechalHcpDecodePhaseLegacyS2L) { CODECHAL_DECODE_CHK_STATUS_RETURN(SendPictureS2L()); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(SendPictureLongFormat()); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SendPictureS2L() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (m_enableSf2DmaSubmits) { m_osInterface->pfnSetPerfTag( m_osInterface, (uint16_t)(((CODECHAL_DECODE_MODE_HUC << 4) & 0xF0) | (m_perfType & 0xF))); } MOS_COMMAND_BUFFER primCmdBuffer; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnGetCommandBuffer(m_osInterface, &primCmdBuffer, 0)); MHW_MI_FORCE_WAKEUP_PARAMS forceWakeupParams; MOS_ZeroMemory(&forceWakeupParams, sizeof(MHW_MI_FORCE_WAKEUP_PARAMS)); forceWakeupParams.bMFXPowerWellControl = false; forceWakeupParams.bMFXPowerWellControlMask = true; forceWakeupParams.bHEVCPowerWellControl = true; forceWakeupParams.bHEVCPowerWellControlMask = true; CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiForceWakeupCmd( &primCmdBuffer, &forceWakeupParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(SendPrologWithFrameTracking( &primCmdBuffer, true)); PMOS_COMMAND_BUFFER cmdBufferInUse = &primCmdBuffer; MOS_COMMAND_BUFFER scdryCmdBuffer; if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_GetCmdBufferToUse_G12( m_scalabilityState, &scdryCmdBuffer, &cmdBufferInUse)); if (cmdBufferInUse == &scdryCmdBuffer) { MHW_MI_FORCE_WAKEUP_PARAMS forceWakeupParams; MOS_ZeroMemory(&forceWakeupParams, sizeof(MHW_MI_FORCE_WAKEUP_PARAMS)); forceWakeupParams.bMFXPowerWellControl = false; forceWakeupParams.bMFXPowerWellControlMask = true; forceWakeupParams.bHEVCPowerWellControl = true; forceWakeupParams.bHEVCPowerWellControlMask = true; CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiForceWakeupCmd( cmdBufferInUse, &forceWakeupParams)); //send prolog at the start of a secondary cmd buffer CODECHAL_DECODE_CHK_STATUS_RETURN(SendPrologWithFrameTracking(cmdBufferInUse, false)); } } if (CodecHalDecodeScalabilityIsVirtualTileMode(m_scalabilityState) && CodecHalDecodeScalability1stDecPhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_InitSemaMemResources(m_scalabilityState, cmdBufferInUse)); } CODECHAL_DECODE_CHK_STATUS_RETURN(AddPictureS2LCmds(cmdBufferInUse)); m_osInterface->pfnReturnCommandBuffer(m_osInterface, &primCmdBuffer, 0); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_ReturnSdryCmdBuffer_G12(m_scalabilityState, &scdryCmdBuffer)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::InitPicLongFormatMhwParams() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; // Reset all pic Mhw Params auto pipeModeSelectParams = static_cast(m_picMhwParams.PipeModeSelectParams); *pipeModeSelectParams = {}; auto pipeBufAddrParams = static_cast(m_picMhwParams.PipeBufAddrParams); *pipeBufAddrParams = {}; auto hevcPicStateParams = static_cast(m_picMhwParams.HevcPicState); *hevcPicStateParams = {}; CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeHevc::InitPicLongFormatMhwParams()); pipeModeSelectParams->bHEVCSeparateTileProgramming = m_isSeparateTileDecoding; if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { CodecHalDecodeScalablity_DecPhaseToHwWorkMode_G12( pipeModeSelectParams->MultiEngineMode, pipeModeSelectParams->PipeWorkMode); if (m_isRealTile) { CodecHalDecodeScalablity_SetPhaseIndicator( pipeModeSelectParams->ucPhaseIndicator); } pipeBufAddrParams->presSliceStateStreamOutBuffer = &m_scalabilityState->resSliceStateStreamOutBuffer; pipeBufAddrParams->presMvUpRightColStoreBuffer = &m_scalabilityState->resMvUpRightColStoreBuffer; pipeBufAddrParams->presIntraPredUpRightColStoreBuffer = &m_scalabilityState->resIntraPredUpRightColStoreBuffer; pipeBufAddrParams->presIntraPredLeftReconColStoreBuffer = &m_scalabilityState->resIntraPredLeftReconColStoreBuffer; pipeBufAddrParams->presCABACSyntaxStreamOutBuffer = m_scalabilityState->presCABACStreamOutBuffer; } hevcPicStateParams->pHevcExtPicParams = m_hevcExtPicParams; hevcPicStateParams->pHevcSccPicParams = m_hevcSccPicParams; hevcPicStateParams->ucRecNotFilteredID = CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams) ? m_IBCRefIdx : 0; return eStatus; } MOS_STATUS CodechalDecodeHevcG12::AddPictureLongFormatCmds( PMOS_COMMAND_BUFFER cmdBufferInUse, PIC_LONG_FORMAT_MHW_PARAMS *picMhwParams) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; MHW_MI_VD_CONTROL_STATE_PARAMS vdCtrlParam; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(cmdBufferInUse); CODECHAL_DECODE_CHK_NULL_RETURN(picMhwParams); // Send VD_CONTROL_STATE Pipe Initialization MOS_ZeroMemory(&vdCtrlParam, sizeof(MHW_MI_VD_CONTROL_STATE_PARAMS)); vdCtrlParam.initialization = true; CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_miInterface)->AddMiVdControlStateCmd(cmdBufferInUse, &vdCtrlParam)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpPipeModeSelectCmd( cmdBufferInUse, picMhwParams->PipeModeSelectParams)); if (CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState) || m_isRealTile) { // Send VD_CONTROL_STATE HcpPipeLock MOS_ZeroMemory(&vdCtrlParam, sizeof(MHW_MI_VD_CONTROL_STATE_PARAMS)); vdCtrlParam.scalableModePipeLock = true; CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_miInterface)->AddMiVdControlStateCmd(cmdBufferInUse, &vdCtrlParam)); } #ifdef _DECODE_PROCESSING_SUPPORTED if (!CodecHalDecodeScalabilityIsFEPhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_sfcState->AddSfcCommands(cmdBufferInUse)); } #endif #ifdef _MMC_SUPPORTED CODECHAL_DECODE_CHK_STATUS_RETURN(m_mmc->SetSurfaceState(picMhwParams->SurfaceParams)); #endif CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpSurfaceCmd( cmdBufferInUse, picMhwParams->SurfaceParams)); // Let ref always use the same state (including MMC) as decode picMhwParams->SurfaceParams->ucSurfaceStateId = CODECHAL_HCP_REF_SURFACE_ID; #ifdef _MMC_SUPPORTED if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { uint8_t skipMask = 0; for (uint8_t i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { if (picMhwParams->PipeBufAddrParams->presReferences[i] == m_presReferences[m_IBCRefIdx]) { skipMask |= (1 << i); } } picMhwParams->SurfaceParams->mmcSkipMask = skipMask; CODECHAL_DECODE_NORMALMESSAGE("IBC ref index %d, MMC skip mask %d,", m_IBCRefIdx, skipMask); } if (MEDIA_IS_WA(m_waTable, WaDummyReference)) { uint8_t skipMask = 0; for (uint8_t i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { if (m_dummyReferenceSlot[i]) { skipMask |= (1 << i); } } picMhwParams->SurfaceParams->mmcSkipMask |= skipMask; } #endif CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpSurfaceCmd( cmdBufferInUse, picMhwParams->SurfaceParams)); if (CodecHalDecodeIsSCCIBCMode(m_hevcSccPicParams)) { uint8_t refIdxMask = 0; for (uint8_t i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { if (picMhwParams->PipeBufAddrParams->presReferences[i] == m_presReferences[m_IBCRefIdx]) { refIdxMask |= (1 << i); } } picMhwParams->PipeBufAddrParams->IBCRefIdxMask = refIdxMask; } CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpPipeBufAddrCmd( cmdBufferInUse, picMhwParams->PipeBufAddrParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpIndObjBaseAddrCmd( cmdBufferInUse, picMhwParams->IndObjBaseAddrParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpQmStateCmd( cmdBufferInUse, picMhwParams->QmParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpPicStateCmd( cmdBufferInUse, picMhwParams->HevcPicState)); if (m_hevcPicParams->tiles_enabled_flag) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_hcpInterface->AddHcpTileStateCmd( cmdBufferInUse, picMhwParams->HevcTileState)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SendPictureLongFormat() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; if (m_enableSf2DmaSubmits) { m_osInterface->pfnSetPerfTag( m_osInterface, (uint16_t)(((CODECHAL_DECODE_MODE_HEVCVLD << 4) & 0xF0) | (m_perfType & 0xF))); } MOS_COMMAND_BUFFER primCmdBuffer; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnGetCommandBuffer(m_osInterface, &primCmdBuffer, 0)); bool sendPrologWithFrameTracking = false; CODECHAL_DECODE_CHK_STATUS_RETURN(DetermineSendProlgwithFrmTracking(&sendPrologWithFrameTracking)); if (sendPrologWithFrameTracking) { MHW_MI_FORCE_WAKEUP_PARAMS forceWakeupParams; MOS_ZeroMemory(&forceWakeupParams, sizeof(MHW_MI_FORCE_WAKEUP_PARAMS)); forceWakeupParams.bMFXPowerWellControl = false; forceWakeupParams.bMFXPowerWellControlMask = true; forceWakeupParams.bHEVCPowerWellControl = true; forceWakeupParams.bHEVCPowerWellControlMask = true; CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiForceWakeupCmd( &primCmdBuffer, &forceWakeupParams)); //Frame tracking functionality is called at the start of a command buffer. CODECHAL_DECODE_CHK_STATUS_RETURN(SendPrologWithFrameTracking( &primCmdBuffer, true)); } PMOS_COMMAND_BUFFER cmdBufferInUse = &primCmdBuffer; MOS_COMMAND_BUFFER scdryCmdBuffer; auto mmioRegisters = m_hwInterface->GetMfxInterface()->GetMmioRegisters(m_vdboxIndex); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_GetCmdBufferToUse_G12( m_scalabilityState, &scdryCmdBuffer, &cmdBufferInUse)); if ((!m_shortFormatInUse && !CodecHalDecodeScalabilityIsFESeparateSubmission(m_scalabilityState) && !m_isRealTile) || CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState) || CodecHalDecodeScalabilityIsFirstRealTilePhase(m_scalabilityState) || (m_secureDecoder != nullptr && m_osInterface->phasedSubmission)) { MHW_MI_FORCE_WAKEUP_PARAMS forceWakeupParams; MOS_ZeroMemory(&forceWakeupParams, sizeof(MHW_MI_FORCE_WAKEUP_PARAMS)); forceWakeupParams.bMFXPowerWellControl = false; forceWakeupParams.bMFXPowerWellControlMask = true; forceWakeupParams.bHEVCPowerWellControl = true; forceWakeupParams.bHEVCPowerWellControlMask = true; CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiForceWakeupCmd( cmdBufferInUse, &forceWakeupParams)); //send prolog at the start of a secondary cmd buffer CODECHAL_DECODE_CHK_STATUS_RETURN(SendPrologWithFrameTracking(cmdBufferInUse, false)); } HalOcaInterface::On1stLevelBBStart(scdryCmdBuffer, *m_osInterface->pOsContext, m_osInterface->CurrentGpuContextHandle, *m_miInterface, *mmioRegisters); } else { HalOcaInterface::On1stLevelBBStart(primCmdBuffer, *m_osInterface->pOsContext, m_osInterface->CurrentGpuContextHandle, *m_miInterface, *mmioRegisters); } CODECHAL_DECODE_CHK_STATUS_RETURN(InitPicLongFormatMhwParams()); CODECHAL_DEBUG_TOOL( uint32_t activeReferenceNumber = 0; for (uint32_t i = 0; i < CODECHAL_MAX_CUR_NUM_REF_FRAME_HEVC; i++) { if (m_frameUsedAsCurRef[i]) { activeReferenceNumber++; } } for (uint32_t n = 0; n < activeReferenceNumber; n++) { if (m_picMhwParams.PipeBufAddrParams->presReferences[n]) { MOS_SURFACE dstSurface; MOS_ZeroMemory(&dstSurface, sizeof(MOS_SURFACE)); dstSurface.OsResource = *(m_picMhwParams.PipeBufAddrParams->presReferences[n]); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalGetResourceInfo( m_osInterface, &dstSurface)); std::string refSurfDumpName = "RefSurf[" + std::to_string(n) + "]"; CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpYUVSurface( &dstSurface, CodechalDbgAttr::attrDecodeReferenceSurfaces, refSurfDumpName.c_str())); } if (m_picMhwParams.PipeBufAddrParams->presColMvTempBuffer[n]) { m_debugInterface->m_refIndex = (uint16_t)n; // dump mvdata std::string mvBufDumpName = "_DEC_" + std::to_string(n); CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpBuffer( m_picMhwParams.PipeBufAddrParams->presColMvTempBuffer[n], CodechalDbgAttr::attrMvData, mvBufDumpName.c_str(), m_mvBufferSize)); } } ); if (CodecHalDecodeScalabilityIsVirtualTileMode(m_scalabilityState) && CodecHalDecodeScalability1stDecPhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_InitSemaMemResources(m_scalabilityState, cmdBufferInUse)); } //Send status report Start if (m_statusQueryReportingEnabled) { bool sendStatusReportStart = true; if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { sendStatusReportStart = CodecHalDecodeScalabilityIsFEPhase(m_scalabilityState) || m_scalabilityState->bIsRtMode; } if (sendStatusReportStart) { CODECHAL_DECODE_CHK_STATUS_RETURN(StartStatusReport(cmdBufferInUse)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(NullHW::StartPredicate(m_osInterface, m_miInterface, cmdBufferInUse)); } } else { CODECHAL_DECODE_CHK_STATUS_RETURN(NullHW::StartPredicate(m_osInterface, m_miInterface, cmdBufferInUse)); } if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_FEBESync_G12( m_scalabilityState, cmdBufferInUse, m_osInterface->phasedSubmission)); if (m_perfFEBETimingEnabled && CodecHalDecodeScalabilityIsLastCompletePhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_perfProfiler->AddPerfCollectStartCmd((void *)this, m_osInterface, m_miInterface, &scdryCmdBuffer)); } } if (m_shortFormatInUse && m_statusQueryReportingEnabled && (!CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) || CodecHalDecodeScalabilityIsFEPhase(m_scalabilityState) || CodecHalDecodeScalabilityIsRealTileMode(m_scalabilityState))) { uint32_t statusBufferOffset = (m_decodeStatusBuf.m_currIndex * sizeof(CodechalDecodeStatus)) + m_decodeStatusBuf.m_storeDataOffset + sizeof(uint32_t) * 2; // Check HuC_STATUS bit15, HW continue if bit15 > 0, otherwise send COND BB END cmd. CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_hwInterface)->SendCondBbEndCmd(&m_decodeStatusBuf.m_statusBuffer, statusBufferOffset + m_decodeStatusBuf.m_hucErrorStatusMaskOffset, 0, false, false, mhw_mi_g12_X::MI_CONDITIONAL_BATCH_BUFFER_END_CMD::COMPARE_OPERATION_MADGREATERTHANIDD, cmdBufferInUse)); } if (CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState) || CodecHalDecodeScalabilityIsFirstRealTilePhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddWatchdogTimerStartCmd(cmdBufferInUse)); } CODECHAL_DECODE_CHK_STATUS_RETURN(AddPictureLongFormatCmds(cmdBufferInUse, &m_picMhwParams)); m_osInterface->pfnReturnCommandBuffer(m_osInterface, &primCmdBuffer, 0); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_ReturnSdryCmdBuffer_G12(m_scalabilityState, &scdryCmdBuffer)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::AddPipeEpilog( PMOS_COMMAND_BUFFER cmdBufferInUse, MOS_COMMAND_BUFFER &scdryCmdBuffer) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; MHW_MI_FLUSH_DW_PARAMS flushDwParams; MOS_ZeroMemory(&flushDwParams, sizeof(flushDwParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiFlushDwCmd( cmdBufferInUse, &flushDwParams)); if (CodecHalDecodeScalabilityIsFEPhase(m_scalabilityState)) { if (m_scalabilityState->bIsEnableEndCurrentBatchBuffLevel) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalablity_GetFEReportedCabacStreamoutBufferSize( m_scalabilityState, cmdBufferInUse)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalablity_SetFECabacStreamoutOverflowStatus( m_scalabilityState, cmdBufferInUse)); } CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_SignalFE2BESemaphore( m_scalabilityState, cmdBufferInUse)); if (m_perfFEBETimingEnabled) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_perfProfiler->AddPerfCollectEndCmd((void *)this, m_osInterface, m_miInterface, &scdryCmdBuffer)); } } //Sync for decode completion in scalable mode if (CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_BEsCompletionSync( m_scalabilityState, cmdBufferInUse)); } bool syncDestSurface = true; //if scalable decode, BE0 finish means whole frame complete. // Check if destination surface needs to be synchronized if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { syncDestSurface = CodecHalDecodeScalabilityIsLastCompletePhase(m_scalabilityState) || CodecHalDecodeScalabilityIsLastRealTilePass(m_scalabilityState); } if (syncDestSurface) { MOS_SYNC_PARAMS syncParams = g_cInitSyncParams; syncParams.GpuContext = m_videoContext; syncParams.presSyncResource = &m_destSurface.OsResource; syncParams.bReadOnly = false; syncParams.bDisableDecodeSyncLock = m_disableDecodeSyncLock; syncParams.bDisableLockForTranscode = m_disableLockForTranscode; if (!CodecHal_PictureIsField(m_hevcPicParams->CurrPic)) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnPerformOverlaySync(m_osInterface, &syncParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnResourceWait(m_osInterface, &syncParams)); // Update the resource tag (s/w tag) for On-Demand Sync m_osInterface->pfnSetResourceSyncTag(m_osInterface, &syncParams); } // Update the tag in GPU Sync eStatus buffer (H/W Tag) to match the current S/W tag if (m_osInterface->bTagResourceSync) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->WriteSyncTagToResource( cmdBufferInUse, &syncParams)); } if (m_statusQueryReportingEnabled) { CodechalDecodeStatusReport decodeStatusReport; MOS_ZeroMemory(&decodeStatusReport, sizeof(decodeStatusReport)); decodeStatusReport.m_statusReportNumber = m_statusReportFeedbackNumber; decodeStatusReport.m_currDecodedPic = m_hevcPicParams->CurrPic; decodeStatusReport.m_currDeblockedPic = m_hevcPicParams->CurrPic; decodeStatusReport.m_codecStatus = CODECHAL_STATUS_UNAVAILABLE; decodeStatusReport.m_currDecodedPicRes = m_hevcRefList[m_hevcPicParams->CurrPic.FrameIdx]->resRefPic; #ifdef _DECODE_PROCESSING_SUPPORTED CODECHAL_DEBUG_TOOL( if (m_sfcState && m_sfcState->m_sfcOutputSurface) { if(m_downsampledSurfaces) { m_downsampledSurfaces[m_hevcPicParams->CurrPic.FrameIdx].OsResource = m_sfcState->m_sfcOutputSurface->OsResource; decodeStatusReport.m_currSfcOutputPicRes = &m_downsampledSurfaces[m_hevcPicParams->CurrPic.FrameIdx].OsResource; } else { decodeStatusReport.m_currSfcOutputPicRes = &(m_sfcState->m_sfcOutputSurface->OsResource); } }) #endif CODECHAL_DEBUG_TOOL( decodeStatusReport.m_secondField = CodecHal_PictureIsBottomField(m_hevcPicParams->CurrPic); decodeStatusReport.m_frameType = m_perfType;); CODECHAL_DECODE_CHK_STATUS_RETURN(EndStatusReport( decodeStatusReport, cmdBufferInUse)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(NullHW::StopPredicate(m_osInterface, m_miInterface, cmdBufferInUse)); } } else { CODECHAL_DECODE_CHK_STATUS_RETURN(NullHW::StopPredicate(m_osInterface, m_miInterface, cmdBufferInUse)); } MOS_ZeroMemory(&flushDwParams, sizeof(flushDwParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiFlushDwCmd( cmdBufferInUse, &flushDwParams)); if (!m_osInterface->pfnIsMismatchOrderProgrammingSupported()) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiBatchBufferEnd( cmdBufferInUse, nullptr)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::SendShortSlices(PMOS_COMMAND_BUFFER cmdBuffer) { CODECHAL_DECODE_CHK_NULL_RETURN(cmdBuffer); MHW_VDBOX_HEVC_SLICE_STATE_G12 hevcSliceState; hevcSliceState.presDataBuffer = m_copyDataBufferInUse ? &m_resCopyDataBuffer : &m_resDataBuffer; auto slc = m_hevcSliceParams; for (uint16_t i = 0; i < m_numSlices; i++, slc++) { hevcSliceState.pHevcSliceParams = slc; hevcSliceState.dwLength = slc->slice_data_size; hevcSliceState.dwSliceIndex = i; hevcSliceState.bLastSlice = (i == (m_numSlices - 1)); CODECHAL_DECODE_CHK_STATUS_RETURN(SendSliceS2L(cmdBuffer, &hevcSliceState)); } return MOS_STATUS_SUCCESS; } MOS_STATUS CodechalDecodeHevcG12::SendHucFlush(PMOS_COMMAND_BUFFER cmdBuffer, MOS_COMMAND_BUFFER &primCmdBuffer, MOS_COMMAND_BUFFER &scdryCmdBuffer, uint32_t renderingFlags) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_CHK_NULL_RETURN(cmdBuffer); CODECHAL_DECODE_CHK_COND_RETURN( (m_vdboxIndex > m_mfxInterface->GetMaxVdboxIndex()), "ERROR - vdbox index exceed the maximum"); auto mmioRegisters = m_hucInterface->GetMmioRegisters(m_vdboxIndex); uint32_t statusBufferOffset = (m_decodeStatusBuf.m_currIndex * sizeof(CodechalDecodeStatus)) + m_decodeStatusBuf.m_storeDataOffset + sizeof(uint32_t) * 2; // Send VD Pipe Flush command for SKL+ MHW_VDBOX_VD_PIPE_FLUSH_PARAMS vdpipeFlushParams; MOS_ZeroMemory(&vdpipeFlushParams, sizeof(vdpipeFlushParams)); vdpipeFlushParams.Flags.bWaitDoneHEVC = 1; vdpipeFlushParams.Flags.bFlushHEVC = 1; vdpipeFlushParams.Flags.bWaitDoneVDCmdMsgParser = 1; CODECHAL_DECODE_CHK_STATUS_RETURN(m_vdencInterface->AddVdPipelineFlushCmd( cmdBuffer, &vdpipeFlushParams)); MHW_MI_FLUSH_DW_PARAMS flushDwParams; MOS_ZeroMemory(&flushDwParams, sizeof(flushDwParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiFlushDwCmd( cmdBuffer, &flushDwParams)); if (m_statusQueryReportingEnabled) { // Check HuC_STATUS2 bit6, if bit6 > 0 HW continue execution following cmd, otherwise it send a COND BB END cmd. eStatus = static_cast(m_hwInterface)->SendCondBbEndCmd( &m_decodeStatusBuf.m_statusBuffer, statusBufferOffset + m_decodeStatusBuf.m_hucErrorStatus2MaskOffset, 0, false, false, mhw_mi_g12_X::MI_CONDITIONAL_BATCH_BUFFER_END_CMD::COMPARE_OPERATION_MADGREATERTHANIDD, cmdBuffer); CODECHAL_DECODE_CHK_STATUS_RETURN(eStatus); // Write HUC_STATUS mask MHW_MI_STORE_DATA_PARAMS storeDataParams; MOS_ZeroMemory(&storeDataParams, sizeof(storeDataParams)); storeDataParams.pOsResource = &m_decodeStatusBuf.m_statusBuffer; storeDataParams.dwResourceOffset = statusBufferOffset + m_decodeStatusBuf.m_hucErrorStatusMaskOffset; storeDataParams.dwValue = m_hucInterface->GetHucStatusHevcS2lFailureMask(); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiStoreDataImmCmd( cmdBuffer, &storeDataParams)); // store HUC_STATUS register MHW_MI_STORE_REGISTER_MEM_PARAMS storeRegParams; MOS_ZeroMemory(&storeRegParams, sizeof(storeRegParams)); storeRegParams.presStoreBuffer = &m_decodeStatusBuf.m_statusBuffer; storeRegParams.dwOffset = statusBufferOffset + m_decodeStatusBuf.m_hucErrorStatusRegOffset; storeRegParams.dwRegister = mmioRegisters->hucStatusRegOffset; CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiStoreRegisterMemCmd( cmdBuffer, &storeRegParams)); } if (m_enableSf2DmaSubmits) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiBatchBufferEnd( cmdBuffer, nullptr)); } CODECHAL_DECODE_CHK_NULL_RETURN(m_osInterface); m_osInterface->pfnReturnCommandBuffer(m_osInterface, &primCmdBuffer, 0); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_ReturnSdryCmdBuffer_G12(m_scalabilityState, &scdryCmdBuffer)); } if (m_enableSf2DmaSubmits) { CODECHAL_DEBUG_TOOL( CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpCmdBuffer( cmdBuffer, CODECHAL_NUM_MEDIA_STATES, "_DEC")); ); CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSubmitCommandBuffer( m_osInterface, cmdBuffer, renderingFlags)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::DecodePrimitiveLevel() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; MHW_MI_VD_CONTROL_STATE_PARAMS vdCtrlParam; CODECHAL_DECODE_FUNCTION_ENTER; // Bitstream is incomplete, don't do any decoding work. if (m_incompletePicture) { return MOS_STATUS_SUCCESS; } uint32_t renderingFlags = m_videoContextUsesNullHw; MOS_COMMAND_BUFFER primCmdBuffer; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnGetCommandBuffer(m_osInterface, &primCmdBuffer, 0)); PMOS_COMMAND_BUFFER cmdBufferInUse = &primCmdBuffer; MOS_COMMAND_BUFFER scdryCmdBuffer; if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_GetCmdBufferToUse_G12( m_scalabilityState, &scdryCmdBuffer, &cmdBufferInUse)); CodecHalDecodeScalability_DecPhaseToSubmissionType_G12(m_scalabilityState,cmdBufferInUse); } if (m_shortFormatInUse && m_hcpDecPhase == CodechalHcpDecodePhaseLegacyS2L) { CODECHAL_DECODE_CHK_STATUS_RETURN(SendShortSlices(cmdBufferInUse)); return SendHucFlush(cmdBufferInUse, primCmdBuffer, scdryCmdBuffer, renderingFlags); } else if (CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState)) { MHW_VDBOX_HCP_TILE_CODING_PARAMS_G12 hcpTileCodingParam; CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_CalculateHcpTileCodingParams( m_scalabilityState, m_hevcPicParams, &hcpTileCodingParam)); //insert 2 dummy VD_CONTROL_STATE packets with data=0 before every HCP_TILE_CODING if (MEDIA_IS_WA(m_waTable, Wa_14010222001)) { MHW_MI_VD_CONTROL_STATE_PARAMS vdCtrlParam; MOS_ZeroMemory(&vdCtrlParam, sizeof(MHW_MI_VD_CONTROL_STATE_PARAMS)); for (int i = 0; i < 2; i++) { CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_miInterface)->AddMiVdControlStateCmd(cmdBufferInUse, &vdCtrlParam)); } } CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_hcpInterface)->AddHcpTileCodingCmd( cmdBufferInUse, &hcpTileCodingParam)); } else if (m_cencBuf) { CODECHAL_DECODE_CHK_STATUS_RETURN(SetCencBatchBuffer(cmdBufferInUse)); } else { if (m_isRealTile) { uint8_t col = 0; CodecHalDecodeScalability_GetCurrentRealTileColumnId(m_scalabilityState, col); CODECHAL_DECODE_ASSERT(col < m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].count); m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].dwOffset = col * m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iSize; } else { m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].dwOffset = 0; } CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiBatchBufferStartCmd( cmdBufferInUse, &m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex])); } // Send VD_CONTROL_STATE Memory Implict Flush MOS_ZeroMemory(&vdCtrlParam, sizeof(MHW_MI_VD_CONTROL_STATE_PARAMS)); vdCtrlParam.memoryImplicitFlush = true; CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_miInterface)->AddMiVdControlStateCmd(cmdBufferInUse, &vdCtrlParam)); if (CodecHalDecodeScalabilityIsBEPhaseG12(m_scalabilityState) || m_isRealTile) { // Send VD_CONTROL_STATE HCP Pipe Unlock MOS_ZeroMemory(&vdCtrlParam, sizeof(MHW_MI_VD_CONTROL_STATE_PARAMS)); vdCtrlParam.scalableModePipeUnlock = true; CODECHAL_DECODE_CHK_STATUS_RETURN(static_cast(m_miInterface)->AddMiVdControlStateCmd(cmdBufferInUse, &vdCtrlParam)); } if (m_isRealTile) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMfxWaitCmd(cmdBufferInUse, nullptr, true)); } // store CS ENGINE ID register if (static_cast(m_mfxInterface)->IsScalabilitySupported()) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_ReadCSEngineIDReg_G12( m_scalabilityState, &m_decodeStatusBuf, cmdBufferInUse)); } // Send VD Pipe Flush command for SKL+ MHW_VDBOX_VD_PIPE_FLUSH_PARAMS vdpipeFlushParams; MOS_ZeroMemory(&vdpipeFlushParams, sizeof(vdpipeFlushParams)); vdpipeFlushParams.Flags.bWaitDoneHEVC = 1; vdpipeFlushParams.Flags.bFlushHEVC = 1; vdpipeFlushParams.Flags.bWaitDoneVDCmdMsgParser = 1; CODECHAL_DECODE_CHK_STATUS_RETURN(m_vdencInterface->AddVdPipelineFlushCmd( cmdBufferInUse, &vdpipeFlushParams)); // Needs to be re-set for Linux buffer re-use scenarios if (CodecHalDecodeScalabilityIsLastRealTilePass(m_scalabilityState) || !CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { m_hevcRefList[m_hevcPicParams->CurrPic.FrameIdx]->resRefPic = m_destSurface.OsResource; } if (!m_isRealTile || CodecHalDecodeScalabilityIsLastRealTilePhase(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(AddPipeEpilog(cmdBufferInUse, scdryCmdBuffer)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(NullHW::StopPredicate(m_osInterface, m_miInterface, cmdBufferInUse)); } m_osInterface->pfnReturnCommandBuffer(m_osInterface, &primCmdBuffer, 0); if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState) && MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_ReturnSdryCmdBuffer_G12(m_scalabilityState, &scdryCmdBuffer)); } bool syncCompleteFrame = m_copyDataBufferInUse; if (MOS_VE_SUPPORTED(m_osInterface) && CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { syncCompleteFrame = syncCompleteFrame && CodecHalDecodeScalabilityIsFEPhase(m_scalabilityState); } if (syncCompleteFrame) { //Sync up complete frame MOS_SYNC_PARAMS copyDataSyncParams = g_cInitSyncParams; copyDataSyncParams.GpuContext = m_videoContextForWa; copyDataSyncParams.presSyncResource = &m_resSyncObjectWaContextInUse; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnEngineSignal(m_osInterface, ©DataSyncParams)); copyDataSyncParams = g_cInitSyncParams; copyDataSyncParams.GpuContext = m_videoContext; copyDataSyncParams.presSyncResource = &m_resSyncObjectWaContextInUse; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnEngineWait(m_osInterface, ©DataSyncParams)); } CODECHAL_DEBUG_TOOL( { if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_DbgDumpCmdBuffer_G12( this, m_scalabilityState, m_debugInterface, &primCmdBuffer)); } else { std::string packetName = ""; if (m_shortFormatInUse) { packetName = "_S2L_DECODE_PASS0__0"; } else { packetName = "_DEC"; } CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpCmdBuffer( &primCmdBuffer, CODECHAL_NUM_MEDIA_STATES, packetName.c_str())); } }); bool submitCommand = true; //submit command buffer if (MOS_VE_SUPPORTED(m_osInterface) && CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { submitCommand = CodecHalDecodeScalabilityIsToSubmitCmdBuffer_G12(m_scalabilityState); HalOcaInterface::DumpCodechalParam(scdryCmdBuffer, (MOS_CONTEXT_HANDLE)m_osInterface->pOsContext, m_pCodechalOcaDumper, CODECHAL_HEVC); HalOcaInterface::On1stLevelBBEnd(scdryCmdBuffer, *m_osInterface); } else { HalOcaInterface::DumpCodechalParam(primCmdBuffer, (MOS_CONTEXT_HANDLE)m_osInterface->pOsContext, m_pCodechalOcaDumper, CODECHAL_HEVC); HalOcaInterface::On1stLevelBBEnd(primCmdBuffer, *m_osInterface); } if (submitCommand) { //command buffer to submit is the primary cmd buffer. if ( MOS_VE_SUPPORTED(m_osInterface)) { CODECHAL_DECODE_CHK_STATUS_RETURN(SetAndPopulateVEHintParams(&primCmdBuffer)); } if(m_osInterface->phasedSubmission && MOS_VE_SUPPORTED(m_osInterface) && CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSubmitCommandBuffer(m_osInterface, cmdBufferInUse, renderingFlags)); } else { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSubmitCommandBuffer(m_osInterface, &primCmdBuffer, renderingFlags)); } } // If S2L and 2nd pass, jump to 2nd level batch buffer if ((!Mos_ResourceIsNull(&m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].OsResource)) && m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].dwOffset == 0) { #if (_DEBUG || _RELEASE_INTERNAL) m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iLastCurrent = m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].iSize * m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex].count; #endif CODECHAL_DEBUG_TOOL( CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->Dump2ndLvlBatch( &m_secondLevelBatchBuffer[m_secondLevelBatchBufferIndex], CODECHAL_NUM_MEDIA_STATES, "_DEC"));) } CODECHAL_DEBUG_TOOL( m_mmc->UpdateUserFeatureKey(&m_destSurface); if (m_histogramDebug && m_histogramSurface) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpBuffer( &m_histogramSurface->OsResource, CodechalDbgAttr::attrSfcHistogram, "_DEC", 256 * 4)); }) // Reset status report if (m_statusQueryReportingEnabled) { bool resetStatusReport = true; //if scalable decode, reset status report at final BE phase. if (CodecHalDecodeScalabilityIsScalableMode(m_scalabilityState)) { resetStatusReport = CodecHalDecodeScalabilityIsFinalBEPhaseG12(m_scalabilityState); } if (resetStatusReport) { CODECHAL_DECODE_CHK_STATUS_RETURN(ResetStatusReport( m_videoContextUsesNullHw)); } } // Send the signal to indicate decode completion, in case On-Demand Sync is not present if (!CodecHal_PictureIsField(m_hevcPicParams->CurrPic)) { MOS_SYNC_PARAMS syncParams = g_cInitSyncParams; syncParams.GpuContext = m_videoContext; syncParams.presSyncResource = &m_destSurface.OsResource; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnResourceSignal(m_osInterface, &syncParams)); } // Scalability real tile, move to next tile column if (m_isRealTile) { CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_AdvanceRealTilePass(m_scalabilityState)); } return eStatus; } MOS_STATUS CodechalDecodeHevcG12::InitMmcState() { #ifdef _MMC_SUPPORTED m_mmc = MOS_New(CodechalMmcDecodeHevcG12, m_hwInterface, this); CODECHAL_DECODE_CHK_NULL_RETURN(m_mmc); #endif if (m_osInterface->pfnIsMismatchOrderProgrammingSupported()) { m_mmc->SetMmcDisabled(); } return MOS_STATUS_SUCCESS; } MOS_STATUS CodechalDecodeHevcG12::AllocateStandard ( CodechalSetting * settings) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(settings); CODECHAL_DECODE_CHK_STATUS_RETURN(InitMmcState()); m_width = settings->width; m_height = settings->height; m_is10BitHevc = (settings->lumaChromaDepth & CODECHAL_LUMA_CHROMA_DEPTH_10_BITS) ? true : false; m_is12BitHevc = (settings->lumaChromaDepth & CODECHAL_LUMA_CHROMA_DEPTH_12_BITS) ? true : false; m_chromaFormatinProfile = settings->chromaFormat; m_shortFormatInUse = settings->shortFormatInUse; #ifdef _DECODE_PROCESSING_SUPPORTED m_sfcState = MOS_New(CodechalHevcSfcStateG12); CODECHAL_DECODE_CHK_NULL_RETURN(m_sfcState); CODECHAL_DECODE_CHK_STATUS_RETURN(m_sfcState->InitializeSfcState( this, m_hwInterface, m_osInterface)); #endif MOS_ZeroMemory(&m_currPic, sizeof(m_currPic)); m_frameIdx = 0; if (m_shortFormatInUse) { // Legacy SF has 2 passes, 1st pass is S2L, 2nd pass is HEVC Long decode // The pass number will be changed again if is scalable decode mode. m_decodePassNum = 2; MOS_USER_FEATURE_VALUE_DATA userFeatureData; MOS_ZeroMemory(&userFeatureData, sizeof(userFeatureData)); MOS_UserFeature_ReadValue_ID( nullptr, __MEDIA_USER_FEATURE_VALUE_HEVC_SF_2_DMA_SUBMITS_ENABLE_ID, &userFeatureData, m_osInterface->pOsContext); m_enableSf2DmaSubmits = userFeatureData.u32Data ? true : false; } MHW_VDBOX_STATE_CMDSIZE_PARAMS_G12 stateCmdSizeParams; stateCmdSizeParams.bShortFormat = m_shortFormatInUse; stateCmdSizeParams.bHucDummyStream = (m_secureDecoder ? m_secureDecoder->IsDummyStreamEnabled() : false); stateCmdSizeParams.bScalableMode = static_cast(m_mfxInterface)->IsScalabilitySupported(); stateCmdSizeParams.bSfcInUse = true; // Picture Level Commands CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->GetHxxStateCommandSize( m_mode, &m_commandBufferSizeNeeded, &m_commandPatchListSizeNeeded, &stateCmdSizeParams)); // Primitive Level Commands CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->GetHxxPrimitiveCommandSize( m_mode, &m_standardDecodeSizeNeeded, &m_standardDecodePatchListSizeNeeded, m_shortFormatInUse)); //HCP Commands CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->GetHcpStateCommandSize( m_mode, &m_HcpStateCmdBufferSizeNeeded, &m_HcpPatchListSizeNeeded, &stateCmdSizeParams)); //Huc State Commands CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->GetHucStateCommandSize( m_mode, &m_HucStateCmdBufferSizeNeeded, &m_HucPatchListSizeNeeded, &stateCmdSizeParams)); //Huc Primitive Commands CODECHAL_DECODE_CHK_STATUS_RETURN(m_hwInterface->GetHucPrimitiveCommandSize( m_mode, &m_HucPrimitiveCmdBufferSizeNeeded, &m_HucPrimitivePatchListSizeNeeded)); //CP Primitive Commands m_cpInterface->GetCpSliceLevelCmdSize( m_CpPrimitiveCmdBufferSizeNeeded, m_CpPrimitivePatchListSizeNeeded); if ( MOS_VE_SUPPORTED(m_osInterface)) { if (static_cast(m_mfxInterface)->IsScalabilitySupported()) { m_scalabilityState = (PCODECHAL_DECODE_SCALABILITY_STATE_G12)MOS_AllocAndZeroMemory(sizeof(CODECHAL_DECODE_SCALABILITY_STATE_G12)); CODECHAL_DECODE_CHK_NULL_RETURN(m_scalabilityState); //scalability initialize CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeScalability_InitializeState_G12( this, m_scalabilityState, m_hwInterface, m_shortFormatInUse, settings)); } else { //single pipe VE initialize m_sinlgePipeVeState = (PCODECHAL_DECODE_SINGLEPIPE_VIRTUALENGINE_STATE)MOS_AllocAndZeroMemory(sizeof(CODECHAL_DECODE_SINGLEPIPE_VIRTUALENGINE_STATE)); CODECHAL_DECODE_CHK_NULL_RETURN(m_sinlgePipeVeState); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_InitInterface(m_osInterface, m_sinlgePipeVeState)); } } CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeHevc::AllocateResourcesFixedSizes()); // Prepare Pic Params m_picMhwParams.PipeModeSelectParams = MOS_New(MHW_VDBOX_PIPE_MODE_SELECT_PARAMS_G12); m_picMhwParams.SurfaceParams = MOS_New(MHW_VDBOX_SURFACE_PARAMS); m_picMhwParams.PipeBufAddrParams = MOS_New(MHW_VDBOX_PIPE_BUF_ADDR_PARAMS_G12); m_picMhwParams.IndObjBaseAddrParams = MOS_New(MHW_VDBOX_IND_OBJ_BASE_ADDR_PARAMS); m_picMhwParams.QmParams = MOS_New(MHW_VDBOX_QM_PARAMS); m_picMhwParams.HevcPicState = MOS_New(MHW_VDBOX_HEVC_PIC_STATE_G12); m_picMhwParams.HevcTileState = MOS_New(MHW_VDBOX_HEVC_TILE_STATE); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.PipeModeSelectParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.SurfaceParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.PipeBufAddrParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.IndObjBaseAddrParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.QmParams); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.HevcPicState); CODECHAL_DECODE_CHK_NULL_RETURN(m_picMhwParams.HevcTileState); MOS_ZeroMemory(m_picMhwParams.SurfaceParams, sizeof(MHW_VDBOX_SURFACE_PARAMS)); MOS_ZeroMemory(m_picMhwParams.IndObjBaseAddrParams, sizeof(MHW_VDBOX_IND_OBJ_BASE_ADDR_PARAMS)); MOS_ZeroMemory(m_picMhwParams.QmParams, sizeof(MHW_VDBOX_QM_PARAMS)); MOS_ZeroMemory(m_picMhwParams.HevcTileState, sizeof(MHW_VDBOX_HEVC_TILE_STATE)); return eStatus; } CodechalDecodeHevcG12::CodechalDecodeHevcG12( CodechalHwInterface * hwInterface, CodechalDebugInterface *debugInterface, PCODECHAL_STANDARD_INFO standardInfo) : CodechalDecodeHevc(hwInterface, debugInterface, standardInfo), m_hevcExtPicParams(nullptr), m_hevcExtSliceParams(nullptr), m_hevcSccPicParams(nullptr), m_hevcSubsetParams(nullptr), m_ctbSize(0), m_frameSizeMaxAlloced(0), m_twoVersionsOfCurrDecPicFlag(false), m_IBCRefIdx(0), #if (_DEBUG || _RELEASE_INTERNAL) m_rtFrameCount(0), m_vtFrameCount(0), m_spFrameCount(0), #endif m_sinlgePipeVeState(nullptr), m_scalabilityState(nullptr) { CODECHAL_DECODE_FUNCTION_ENTER; MOS_ZeroMemory(&m_resRefBeforeLoopFilter, sizeof(m_resRefBeforeLoopFilter)); CODECHAL_DECODE_CHK_NULL_NO_STATUS_RETURN(m_osInterface); m_osInterface->pfnVirtualEngineSupported(m_osInterface, true, true); #if (_DEBUG || _RELEASE_INTERNAL) MOS_USER_FEATURE_VALUE_DATA userFeatureData; MOS_ZeroMemory(&userFeatureData, sizeof(userFeatureData)); MOS_UserFeature_ReadValue_ID( nullptr, __MEDIA_USER_FEATURE_VALUE_DECODE_HISTOGRAM_DEBUG_ID, &userFeatureData, m_osInterface->pOsContext); m_histogramDebug = userFeatureData.u32Data ? true : false; #endif } #if USE_CODECHAL_DEBUG_TOOL MOS_STATUS CodechalDecodeHevcG12::DumpPicParams( PCODEC_HEVC_PIC_PARAMS picParams, PCODEC_HEVC_EXT_PIC_PARAMS extPicParams, PCODEC_HEVC_SCC_PIC_PARAMS sccPicParams) { CODECHAL_DEBUG_FUNCTION_ENTER; if (!m_debugInterface->DumpIsEnabled(CodechalDbgAttr::attrPicParams)) { return MOS_STATUS_SUCCESS; } CODECHAL_DEBUG_CHK_NULL(picParams); std::ostringstream oss; oss.setf(std::ios::showbase | std::ios::uppercase); oss.setf(std::ios::hex, std::ios::basefield); oss << "PicWidthInMinCbsY: " << +picParams->PicWidthInMinCbsY << std::endl; oss << "PicHeightInMinCbsY: " << +picParams->PicHeightInMinCbsY << std::endl; //wFormatAndSequenceInfoFlags oss << "chroma_format_idc: " << +picParams->chroma_format_idc << std::endl; oss << "separate_colour_plane_flag: " << +picParams->separate_colour_plane_flag << std::endl; oss << "bit_depth_luma_minus8: " << +picParams->bit_depth_luma_minus8 << std::endl; oss << "bit_depth_chroma_minus8: " << +picParams->bit_depth_chroma_minus8 << std::endl; oss << "log2_max_pic_order_cnt_lsb_minus4: " << +picParams->log2_max_pic_order_cnt_lsb_minus4 << std::endl; oss << "NoPicReorderingFlag: " << +picParams->NoPicReorderingFlag << std::endl; oss << "ReservedBits1: " << +picParams->ReservedBits1 << std::endl; oss << "wFormatAndSequenceInfoFlags: " << +picParams->wFormatAndSequenceInfoFlags << std::endl; oss << "CurrPic FrameIdx: " << +picParams->CurrPic.FrameIdx << std::endl; oss << "CurrPic PicFlags: " << +picParams->CurrPic.PicFlags << std::endl; oss << "sps_max_dec_pic_buffering_minus1: " << +picParams->sps_max_dec_pic_buffering_minus1 << std::endl; oss << "log2_min_luma_coding_block_size_minus3: " << +picParams->log2_min_luma_coding_block_size_minus3 << std::endl; oss << "log2_diff_max_min_luma_coding_block_size: " << +picParams->log2_diff_max_min_luma_coding_block_size << std::endl; oss << "log2_min_transform_block_size_minus2: " << +picParams->log2_min_transform_block_size_minus2 << std::endl; oss << "log2_diff_max_min_transform_block_size: " << +picParams->log2_diff_max_min_transform_block_size << std::endl; oss << "max_transform_hierarchy_depth_intra: " << +picParams->max_transform_hierarchy_depth_intra << std::endl; oss << "max_transform_hierarchy_depth_inter: " << +picParams->max_transform_hierarchy_depth_inter << std::endl; oss << "num_short_term_ref_pic_sets: " << +picParams->num_short_term_ref_pic_sets << std::endl; oss << "num_long_term_ref_pic_sps: " << +picParams->num_long_term_ref_pic_sps << std::endl; oss << "num_ref_idx_l0_default_active_minus1: " << +picParams->num_ref_idx_l0_default_active_minus1 << std::endl; oss << "num_ref_idx_l1_default_active_minus1: " << +picParams->num_ref_idx_l1_default_active_minus1 << std::endl; oss << "init_qp_minus26: " << +picParams->init_qp_minus26 << std::endl; oss << "ucNumDeltaPocsOfRefRpsIdx: " << +picParams->ucNumDeltaPocsOfRefRpsIdx << std::endl; oss << "wNumBitsForShortTermRPSInSlice: " << +picParams->wNumBitsForShortTermRPSInSlice << std::endl; oss << "ReservedBits2: " << +picParams->ReservedBits2 << std::endl; //dwCodingParamToolFlags oss << "scaling_list_enabled_flag: " << +picParams->scaling_list_enabled_flag << std::endl; oss << "amp_enabled_flag: " << +picParams->amp_enabled_flag << std::endl; oss << "sample_adaptive_offset_enabled_flag: " << +picParams->sample_adaptive_offset_enabled_flag << std::endl; oss << "pcm_enabled_flag: " << +picParams->pcm_enabled_flag << std::endl; oss << "pcm_sample_bit_depth_luma_minus1: " << +picParams->pcm_sample_bit_depth_luma_minus1 << std::endl; oss << "pcm_sample_bit_depth_chroma_minus1: " << +picParams->pcm_sample_bit_depth_chroma_minus1 << std::endl; oss << "log2_min_pcm_luma_coding_block_size_minus3: " << +picParams->log2_min_pcm_luma_coding_block_size_minus3 << std::endl; oss << "log2_diff_max_min_pcm_luma_coding_block_size: " << +picParams->log2_diff_max_min_pcm_luma_coding_block_size << std::endl; oss << "pcm_loop_filter_disabled_flag: " << +picParams->pcm_loop_filter_disabled_flag << std::endl; oss << "long_term_ref_pics_present_flag: " << +picParams->long_term_ref_pics_present_flag << std::endl; oss << "sps_temporal_mvp_enabled_flag: " << +picParams->sps_temporal_mvp_enabled_flag << std::endl; oss << "strong_intra_smoothing_enabled_flag: " << +picParams->strong_intra_smoothing_enabled_flag << std::endl; oss << "dependent_slice_segments_enabled_flag: " << +picParams->dependent_slice_segments_enabled_flag << std::endl; oss << "output_flag_present_flag: " << +picParams->output_flag_present_flag << std::endl; oss << "num_extra_slice_header_bits: " << +picParams->num_extra_slice_header_bits << std::endl; oss << "sign_data_hiding_enabled_flag: " << +picParams->sign_data_hiding_enabled_flag << std::endl; oss << "cabac_init_present_flag: " << +picParams->cabac_init_present_flag << std::endl; oss << "ReservedBits3: " << +picParams->ReservedBits3 << std::endl; oss << "dwCodingParamToolFlags: " << +picParams->dwCodingParamToolFlags << std::endl; //dwCodingSettingPicturePropertyFlags oss << "constrained_intra_pred_flag: " << +picParams->constrained_intra_pred_flag << std::endl; oss << "transform_skip_enabled_flag: " << +picParams->transform_skip_enabled_flag << std::endl; oss << "cu_qp_delta_enabled_flag: " << +picParams->cu_qp_delta_enabled_flag << std::endl; oss << "diff_cu_qp_delta_depth: " << +picParams->diff_cu_qp_delta_depth << std::endl; oss << "pps_slice_chroma_qp_offsets_present_flag: " << +picParams->pps_slice_chroma_qp_offsets_present_flag << std::endl; oss << "weighted_pred_flag: " << +picParams->weighted_pred_flag << std::endl; oss << "weighted_bipred_flag: " << +picParams->weighted_bipred_flag << std::endl; oss << "transquant_bypass_enabled_flag: " << +picParams->transquant_bypass_enabled_flag << std::endl; oss << "tiles_enabled_flag: " << +picParams->tiles_enabled_flag << std::endl; oss << "entropy_coding_sync_enabled_flag: " << +picParams->entropy_coding_sync_enabled_flag << std::endl; oss << "uniform_spacing_flag: " << +picParams->uniform_spacing_flag << std::endl; oss << "loop_filter_across_tiles_enabled_flag: " << +picParams->loop_filter_across_tiles_enabled_flag << std::endl; oss << "pps_loop_filter_across_slices_enabled_flag: " << +picParams->pps_loop_filter_across_slices_enabled_flag << std::endl; oss << "deblocking_filter_override_enabled_flag: " << +picParams->deblocking_filter_override_enabled_flag << std::endl; oss << "pps_deblocking_filter_disabled_flag: " << +picParams->pps_deblocking_filter_disabled_flag << std::endl; oss << "lists_modification_present_flag: " << +picParams->lists_modification_present_flag << std::endl; oss << "slice_segment_header_extension_present_flag: " << +picParams->slice_segment_header_extension_present_flag << std::endl; oss << "IrapPicFlag: " << +picParams->IrapPicFlag << std::endl; oss << "IdrPicFlag: " << +picParams->IdrPicFlag << std::endl; oss << "IntraPicFlag: " << +picParams->IntraPicFlag << std::endl; oss << "ReservedBits4: " << +picParams->ReservedBits4 << std::endl; oss << "dwCodingSettingPicturePropertyFlags: " << +picParams->dwCodingSettingPicturePropertyFlags << std::endl; oss << "pps_cb_qp_offset: " << +picParams->pps_cb_qp_offset << std::endl; oss << "pps_cr_qp_offset: " << +picParams->pps_cr_qp_offset << std::endl; oss << "num_tile_columns_minus1: " << +picParams->num_tile_columns_minus1 << std::endl; oss << "num_tile_rows_minus1: " << +picParams->num_tile_rows_minus1 << std::endl; //Dump column width oss << "column_width_minus1[19]:"; for (uint8_t i = 0; i < 19; i++) oss << picParams->column_width_minus1[i] << " "; oss << std::endl; //Dump row height oss << "row_height_minus1[21]:"; for (uint8_t i = 0; i < 21; i++) oss << picParams->row_height_minus1[i] << " "; oss << std::endl; oss << "pps_beta_offset_div2: " << +picParams->pps_beta_offset_div2 << std::endl; oss << "pps_tc_offset_div2: " << +picParams->pps_tc_offset_div2 << std::endl; oss << "log2_parallel_merge_level_minus2: " << +picParams->log2_parallel_merge_level_minus2 << std::endl; oss << "CurrPicOrderCntVal: " << +picParams->CurrPicOrderCntVal << std::endl; oss.setf(std::ios::dec, std::ios::basefield); //Dump RefFrameList[15] for (uint8_t i = 0; i < 15; ++i) { oss << "RefFrameList[" << +i << "].FrameIdx:" << +picParams->RefFrameList[i].FrameIdx << std::endl; oss << "RefFrameList[" << +i << "].PicFlags:" << +picParams->RefFrameList[i].PicFlags << std::endl; } //Dump POC List oss << "PicOrderCntValList[15]:"; for (uint8_t i = 0; i < 15; i++) oss << std::hex << picParams->PicOrderCntValList[i] << " "; oss << std::endl; //Dump Ref RefPicSetStCurrBefore List oss << "RefPicSetStCurrBefore[8]:"; for (uint8_t i = 0; i < 8; i++) oss << +picParams->RefPicSetStCurrBefore[i] << " "; oss << std::endl; //Dump Ref RefPicSetStCurrAfter List oss << "RefPicSetStCurrAfter[16]:"; for (uint8_t i = 0; i < 8; i++) oss << +picParams->RefPicSetStCurrAfter[i] << " "; oss << std::endl; //Dump Ref PicSetStCurr List oss << "RefPicSetLtCurr[16]:"; for (uint8_t i = 0; i < 8; i++) oss << +picParams->RefPicSetLtCurr[i] << " "; oss << std::endl; //Dump Ref RefPicSetStCurrBefore List with POC oss << "POC of RefPicSetStCurrBefore[8]: "; for (uint8_t i = 0; i < 8; i++) oss << +picParams->PicOrderCntValList[picParams->RefPicSetStCurrBefore[i]%15] << " "; oss << std::endl; //Dump Ref RefPicSetStCurrAfter List with POC oss << "POC of RefPicSetStCurrAfter[16]:"; for (uint8_t i = 0; i < 8; i++) oss << +picParams->PicOrderCntValList[picParams->RefPicSetStCurrAfter[i]%15] << " "; oss << std::endl; //Dump Ref PicSetStCurr List with POC oss << "POC of RefPicSetLtCurr[16]: "; for (uint8_t i = 0; i < 8; i++) oss << +picParams->PicOrderCntValList[picParams->RefPicSetLtCurr[i]%15] << " "; oss << std::endl; oss << "RefFieldPicFlag: " << +picParams->RefFieldPicFlag << std::endl; oss << "RefBottomFieldFlag: " << +picParams->RefBottomFieldFlag << std::endl; oss << "StatusReportFeedbackNumber: " << +picParams->StatusReportFeedbackNumber << std::endl; if (extPicParams) { //PicRangeExtensionFlags oss << "transform_skip_rotation_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.transform_skip_rotation_enabled_flag << std::endl; oss << "transform_skip_context_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.transform_skip_context_enabled_flag << std::endl; oss << "implicit_rdpcm_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.implicit_rdpcm_enabled_flag << std::endl; oss << "explicit_rdpcm_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.explicit_rdpcm_enabled_flag << std::endl; oss << "extended_precision_processing_flag: " << +extPicParams->PicRangeExtensionFlags.fields.extended_precision_processing_flag << std::endl; oss << "intra_smoothing_disabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.intra_smoothing_disabled_flag << std::endl; oss << "high_precision_offsets_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.high_precision_offsets_enabled_flag << std::endl; oss << "persistent_rice_adaptation_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.persistent_rice_adaptation_enabled_flag << std::endl; oss << "cabac_bypass_alignment_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.cabac_bypass_alignment_enabled_flag << std::endl; oss << "cross_component_prediction_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.cross_component_prediction_enabled_flag << std::endl; oss << "chroma_qp_offset_list_enabled_flag: " << +extPicParams->PicRangeExtensionFlags.fields.chroma_qp_offset_list_enabled_flag << std::endl; oss << "BitDepthLuma16: " << +extPicParams->PicRangeExtensionFlags.fields.BitDepthLuma16 << std::endl; oss << "BitDepthChroma16: " << +extPicParams->PicRangeExtensionFlags.fields.BitDepthChroma16 << std::endl; oss << "diff_cu_chroma_qp_offset_depth: " << +extPicParams->diff_cu_chroma_qp_offset_depth << std::endl; oss << "chroma_qp_offset_list_len_minus1: " << +extPicParams->chroma_qp_offset_list_len_minus1 << std::endl; oss << "log2_sao_offset_scale_luma: " << +extPicParams->log2_sao_offset_scale_luma << std::endl; oss << "log2_sao_offset_scale_chroma: " << +extPicParams->log2_sao_offset_scale_chroma << std::endl; oss << "log2_max_transform_skip_block_size_minus2: " << +extPicParams->log2_max_transform_skip_block_size_minus2 << std::endl; //Dump cb_qp_offset_list[6] oss << "cb_qp_offset_list[6]: "; for (uint8_t i = 0; i < 6; i++) oss << +extPicParams->cb_qp_offset_list[i] << " "; oss << std::endl; //Dump cr_qp_offset_list[6] oss << "cr_qp_offset_list[6]: "; for (uint8_t i = 0; i < 6; i++) oss << +extPicParams->cr_qp_offset_list[i] << " "; oss << std::endl; //Dump scc pic parameters if(sccPicParams) { oss << "pps_curr_pic_ref_enabled_flag: " << +sccPicParams->PicSCCExtensionFlags.fields.pps_curr_pic_ref_enabled_flag<< std::endl; oss << "palette_mode_enabled_flag: " << +sccPicParams->PicSCCExtensionFlags.fields.palette_mode_enabled_flag << std::endl; oss << "motion_vector_resolution_control_idc: " << +sccPicParams->PicSCCExtensionFlags.fields.motion_vector_resolution_control_idc << std::endl; oss << "intra_boundary_filtering_disabled_flag: " << +sccPicParams->PicSCCExtensionFlags.fields.intra_boundary_filtering_disabled_flag << std::endl; oss << "residual_adaptive_colour_transform_enabled_flag: " << +sccPicParams->PicSCCExtensionFlags.fields.residual_adaptive_colour_transform_enabled_flag << std::endl; oss << "pps_slice_act_qp_offsets_present_flag: " << +sccPicParams->PicSCCExtensionFlags.fields.pps_slice_act_qp_offsets_present_flag << std::endl; oss << "palette_max_size: " << +sccPicParams->palette_max_size << std::endl; oss << "delta_palette_max_predictor_size: " << +sccPicParams->delta_palette_max_predictor_size << std::endl; oss << "PredictorPaletteSize: " << +sccPicParams->PredictorPaletteSize << std::endl; for(uint8_t i = 0; i < 128; i++) { oss << "PredictorPaletteEntries[0][" << +i << "]: " << +sccPicParams->PredictorPaletteEntries[0][i] << std::endl; oss << "PredictorPaletteEntries[1][" << +i << "]: " << +sccPicParams->PredictorPaletteEntries[1][i] << std::endl; oss << "PredictorPaletteEntries[2][" << +i << "]: " << +sccPicParams->PredictorPaletteEntries[2][i] << std::endl; } oss << "pps_act_y_qp_offset_plus5: " << +sccPicParams->pps_act_y_qp_offset_plus5 << std::endl; oss << "pps_act_cb_qp_offset_plus5: " << +sccPicParams->pps_act_y_qp_offset_plus5 << std::endl; oss << "pps_act_cr_qp_offset_plus3: " << +sccPicParams->pps_act_y_qp_offset_plus5 << std::endl; } } const char *fileName = m_debugInterface->CreateFileName( "_DEC", CodechalDbgBufferType::bufPicParams, CodechalDbgExtType::txt); std::ofstream ofs(fileName, std::ios::out); ofs << oss.str(); ofs.close(); return MOS_STATUS_SUCCESS; } MOS_STATUS CodechalDecodeHevcG12::DumpSliceParams( PCODEC_HEVC_SLICE_PARAMS sliceParams, PCODEC_HEVC_EXT_SLICE_PARAMS extSliceParams, uint32_t numSlices, bool shortFormatInUse) { CODECHAL_DEBUG_FUNCTION_ENTER; if (!m_debugInterface->DumpIsEnabled(CodechalDbgAttr::attrSlcParams)) { return MOS_STATUS_SUCCESS; } CODECHAL_DEBUG_CHK_NULL(sliceParams); PCODEC_HEVC_SLICE_PARAMS hevcSliceControl = nullptr; PCODEC_HEVC_EXT_SLICE_PARAMS hevcExtSliceControl = nullptr; std::ostringstream oss; oss.setf(std::ios::showbase | std::ios::uppercase); for (uint16_t j = 0; j < numSlices; j++) { hevcSliceControl = &sliceParams[j]; if (extSliceParams) { hevcExtSliceControl = &extSliceParams[j]; } oss << "====================================================================================================" << std::endl; oss << "Data for Slice number = " << +j << std::endl; oss << "slice_data_size: " << +hevcSliceControl->slice_data_size << std::endl; oss << "slice_data_offset: " << +hevcSliceControl->slice_data_offset << std::endl; if (!shortFormatInUse) { //Dump Long format specific oss << "ByteOffsetToSliceData: " << +hevcSliceControl->ByteOffsetToSliceData << std::endl; oss << "slice_segment_address: " << +hevcSliceControl->slice_segment_address << std::endl; //Dump RefPicList[2][15] for (uint8_t i = 0; i < 15; ++i) { oss << "RefPicList[0][" << +i << "]"; oss << ".FrameIdx: " << +hevcSliceControl->RefPicList[0][i].FrameIdx << std::endl; oss << "RefPicList[0][" << +i << "]"; oss << ".PicFlags: " << +hevcSliceControl->RefPicList[0][i].PicFlags << std::endl; } for (uint8_t i = 0; i < 15; ++i) { oss << "RefPicList[1][" << +i << "]"; oss << ".FrameIdx: " << +hevcSliceControl->RefPicList[1][i].FrameIdx << std::endl; oss << "RefPicList[1][" << +i << "]"; oss << ".PicFlags: " << +hevcSliceControl->RefPicList[1][i].PicFlags << std::endl; } oss << "last_slice_of_pic: " << +hevcSliceControl->LongSliceFlags.fields.LastSliceOfPic << std::endl; oss << "dependent_slice_segment_flag: " << +hevcSliceControl->LongSliceFlags.fields.dependent_slice_segment_flag << std::endl; oss << "slice_type: " << +hevcSliceControl->LongSliceFlags.fields.slice_type << std::endl; oss << "color_plane_id: " << +hevcSliceControl->LongSliceFlags.fields.color_plane_id << std::endl; oss << "slice_sao_luma_flag: " << +hevcSliceControl->LongSliceFlags.fields.slice_sao_luma_flag << std::endl; oss << "slice_sao_chroma_flag: " << +hevcSliceControl->LongSliceFlags.fields.slice_sao_chroma_flag << std::endl; oss << "mvd_l1_zero_flag: " << +hevcSliceControl->LongSliceFlags.fields.mvd_l1_zero_flag << std::endl; oss << "cabac_init_flag: " << +hevcSliceControl->LongSliceFlags.fields.cabac_init_flag << std::endl; oss << "slice_temporal_mvp_enabled_flag: " << +hevcSliceControl->LongSliceFlags.fields.slice_temporal_mvp_enabled_flag << std::endl; oss << "slice_deblocking_filter_disabled_flag: " << +hevcSliceControl->LongSliceFlags.fields.slice_deblocking_filter_disabled_flag << std::endl; oss << "collocated_from_l0_flag: " << +hevcSliceControl->LongSliceFlags.fields.collocated_from_l0_flag << std::endl; oss << "slice_loop_filter_across_slices_enabled_flag: " << +hevcSliceControl->LongSliceFlags.fields.slice_loop_filter_across_slices_enabled_flag << std::endl; oss << "reserved: " << +hevcSliceControl->LongSliceFlags.fields.reserved << std::endl; oss << "collocated_ref_idx: " << +hevcSliceControl->collocated_ref_idx << std::endl; oss << "num_ref_idx_l0_active_minus1: " << +hevcSliceControl->num_ref_idx_l0_active_minus1 << std::endl; oss << "num_ref_idx_l1_active_minus1: " << +hevcSliceControl->num_ref_idx_l1_active_minus1 << std::endl; oss << "slice_qp_delta: " << +hevcSliceControl->slice_qp_delta << std::endl; oss << "slice_cb_qp_offset: " << +hevcSliceControl->slice_cb_qp_offset << std::endl; oss << "slice_cr_qp_offset: " << +hevcSliceControl->slice_cr_qp_offset << std::endl; oss << "slice_beta_offset_div2: " << +hevcSliceControl->slice_beta_offset_div2 << std::endl; oss << "slice_tc_offset_div2: " << +hevcSliceControl->slice_tc_offset_div2 << std::endl; oss << "luma_log2_weight_denom: " << +hevcSliceControl->luma_log2_weight_denom << std::endl; oss << "delta_chroma_log2_weight_denom: " << +hevcSliceControl->delta_chroma_log2_weight_denom << std::endl; //Dump luma_offset[2][15] for (uint8_t i = 0; i < 15; i++) { oss << "luma_offset_l0[" << +i << "]: " << (extSliceParams ? +hevcExtSliceControl->luma_offset_l0[i] : +hevcSliceControl->luma_offset_l0[i]) << std::endl; oss << "luma_offset_l1[" << +i << "]: " << (extSliceParams ? +hevcExtSliceControl->luma_offset_l1[i] : +hevcSliceControl->luma_offset_l1[i]) << std::endl; } //Dump delta_luma_weight[2][15] for (uint8_t i = 0; i < 15; i++) { oss << "delta_luma_weight_l0[" << +i << "]: " << +hevcSliceControl->delta_luma_weight_l0[i] << std::endl; oss << "delta_luma_weight_l1[" << +i << "]: " << +hevcSliceControl->delta_luma_weight_l1[i] << std::endl; } //Dump chroma_offset[2][15][2] for (uint8_t i = 0; i < 15; i++) { oss << "ChromaOffsetL0[" << +i << "][0]: " << (extSliceParams ? +hevcExtSliceControl->ChromaOffsetL0[i][0] : +hevcSliceControl->ChromaOffsetL0[i][0]) << std::endl; oss << "ChromaOffsetL0[" << +i << "][1]: " << (extSliceParams ? +hevcExtSliceControl->ChromaOffsetL0[i][1] : +hevcSliceControl->ChromaOffsetL0[i][1]) << std::endl; oss << "ChromaOffsetL1[" << +i << "][0]: " << (extSliceParams ? +hevcExtSliceControl->ChromaOffsetL1[i][0] : +hevcSliceControl->ChromaOffsetL1[i][0]) << std::endl; oss << "ChromaOffsetL1[" << +i << "][1]: " << (extSliceParams ? +hevcExtSliceControl->ChromaOffsetL1[i][1] : +hevcSliceControl->ChromaOffsetL1[i][1]) << std::endl; } //Dump delta_chroma_weight[2][15][2] for (uint8_t i = 0; i < 15; i++) { oss << "delta_chroma_weight_l0[" << +i << "][0]: " << +hevcSliceControl->delta_chroma_weight_l0[i][0] << std::endl; oss << "delta_chroma_weight_l0[" << +i << "][1]: " << +hevcSliceControl->delta_chroma_weight_l0[i][1] << std::endl; oss << "delta_chroma_weight_l1[" << +i << "][0]: " << +hevcSliceControl->delta_chroma_weight_l1[i][0] << std::endl; oss << "delta_chroma_weight_l1[" << +i << "][1]: " << +hevcSliceControl->delta_chroma_weight_l1[i][1] << std::endl; } oss << "five_minus_max_num_merge_cand: " << +hevcSliceControl->five_minus_max_num_merge_cand << std::endl; oss << "num_entry_point_offsets: " << +hevcSliceControl->num_entry_point_offsets << std::endl; oss << "EntryOffsetToSubsetArray: " << +hevcSliceControl->EntryOffsetToSubsetArray << std::endl; if (extSliceParams) { oss << "cu_chroma_qp_offset_enabled_flag: " << +hevcExtSliceControl->cu_chroma_qp_offset_enabled_flag << std::endl; //Dump scc slice parameters oss << "slice_act_y_qp_offset: " << +hevcExtSliceControl->slice_act_y_qp_offset<< std::endl; oss << "slice_act_cb_qp_offset: " << +hevcExtSliceControl->slice_act_cb_qp_offset << std::endl; oss << "slice_act_cr_qp_offset: " << +hevcExtSliceControl->slice_act_cr_qp_offset << std::endl; oss << "use_integer_mv_flag: " << +hevcExtSliceControl->use_integer_mv_flag << std::endl; } } } const char *fileName = m_debugInterface->CreateFileName( "_DEC", CodechalDbgBufferType::bufSlcParams, CodechalDbgExtType::txt); CODECHAL_DEBUG_CHK_NULL(fileName); std::ofstream ofs; ofs.open(fileName, std::ios::out); ofs << oss.str(); ofs.close(); return MOS_STATUS_SUCCESS; } MOS_STATUS CodechalDecodeHevcG12::DumpSubsetsParams( PCODEC_HEVC_SUBSET_PARAMS subsetsParams) { CODECHAL_DEBUG_FUNCTION_ENTER; if (!m_debugInterface->DumpIsEnabled(CodechalDbgAttr::attrSubsetsParams)) { return MOS_STATUS_SUCCESS; } if(subsetsParams) { std::ostringstream oss; oss.setf(std::ios::showbase | std::ios::uppercase); for(uint16_t i = 0; i < 440; i++) { oss << "entry_point_offset_minus1[" << +i << "]: " << +subsetsParams->entry_point_offset_minus1[i]<< std::endl; } //create the file const char *fileName = m_debugInterface->CreateFileName( "_DEC", CodechalDbgBufferType::bufSubsetsParams, CodechalDbgExtType::txt); std::ofstream ofs(fileName, std::ios::out); ofs << oss.str(); ofs.close(); } return MOS_STATUS_SUCCESS; } #endif