/* * Copyright (c) 2011-2020, 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_jpeg_g11.cpp //! \brief Implements the decode interface extension for JPEG. //! \details Implements all functions and constants required by CodecHal for JPEG decoding. //! #include "codechal_decoder.h" #include "codechal_decode_jpeg_g11.h" #include "mhw_vdbox_mfx_g11_X.h" #include "hal_oca_interface.h" CodechalDecodeJpegG11::~CodechalDecodeJpegG11() { CODECHAL_DECODE_FUNCTION_ENTER; if (m_veState != nullptr) { MOS_FreeMemAndSetNull(m_veState); m_veState = nullptr; } } MOS_STATUS CodechalDecodeJpegG11::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); bool sfcInUse = IsSfcInUse(codecHalSetting); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_ConstructParmsForGpuCtxCreation( m_veState, (PMOS_GPUCTX_CREATOPTIONS_ENHANCED)m_gpuCtxCreatOpt, sfcInUse)); if (sfcInUse) { m_videoContext = MOS_GPU_CONTEXT_VIDEO4; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnCreateGpuContext( m_osInterface, m_videoContext, MOS_GPU_NODE_VIDEO, m_gpuCtxCreatOpt)); m_videoContext = MOS_GPU_CONTEXT_VIDEO; } else { m_videoContext = MOS_GPU_CONTEXT_VIDEO; } } return eStatus; } MOS_STATUS CodechalDecodeJpegG11::SetFrameStates() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeJpeg::SetFrameStates()); if ( MOS_VE_SUPPORTED(m_osInterface)) { if (!MOS_VE_CTXBASEDSCHEDULING_SUPPORTED(m_osInterface)) { MOS_VIRTUALENGINE_SET_PARAMS vesetParams; MOS_ZeroMemory(&vesetParams, sizeof(vesetParams)); #ifdef _DECODE_PROCESSING_SUPPORTED vesetParams.bSFCInUse = m_sfcState->m_sfcPipeOut; #else vesetParams.bSFCInUse = false; #endif vesetParams.bNeedSyncWithPrevious = true; vesetParams.bSameEngineAsLastSubmission = false; CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_SetHintParams( m_veState, &vesetParams)); } } return eStatus; } MOS_STATUS CodechalDecodeJpegG11::DecodeStateLevel() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; MHW_VDBOX_JPEG_DECODE_PIC_STATE jpegPicState; jpegPicState.dwOutputFormat = m_decodeParams.m_destSurface->Format; #ifdef _DECODE_PROCESSING_SUPPORTED if (m_sfcState->m_sfcPipeOut) { jpegPicState.dwOutputFormat = m_sfcState->m_sfcInSurface.Format; } #endif //Three new formats from HSW C0,HSW ULT can only be supported in specific conditions. if (jpegPicState.dwOutputFormat == Format_NV12 || jpegPicState.dwOutputFormat == Format_YUY2 || jpegPicState.dwOutputFormat == Format_UYVY) { //Only interleaved single scan are supported. if (m_jpegPicParams->m_totalScans != 1 || m_jpegPicParams->m_interleavedData == 0) { return MOS_STATUS_UNKNOWN; } switch (m_jpegPicParams->m_chromaType) { case jpegYUV420: case jpegYUV422H2Y: case jpegYUV422H4Y: break; case jpegYUV422V2Y: case jpegYUV422V4Y: if (GFX_IS_GEN_8_OR_LATER(m_hwInterface->GetPlatform()) && jpegPicState.dwOutputFormat == Format_NV12) { break; } default: return MOS_STATUS_UNKNOWN; } } if (m_decodeParams.m_destSurface->Format == Format_A8R8G8B8) { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSetGpuContext( m_osInterface, MOS_GPU_CONTEXT_VIDEO4)); m_videoContext = MOS_GPU_CONTEXT_VIDEO4; } else { CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSetGpuContext( m_osInterface, MOS_GPU_CONTEXT_VIDEO)); m_videoContext = MOS_GPU_CONTEXT_VIDEO; } MOS_COMMAND_BUFFER cmdBuffer; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnGetCommandBuffer( m_osInterface, &cmdBuffer, 0)); auto mmioRegisters = m_hwInterface->GetMfxInterface()->GetMmioRegisters(m_vdboxIndex); HalOcaInterface::On1stLevelBBStart(cmdBuffer, *m_osInterface->pOsContext, m_osInterface->CurrentGpuContextHandle, *m_miInterface, *mmioRegisters); CODECHAL_DECODE_CHK_STATUS_RETURN(SendPrologWithFrameTracking( &cmdBuffer, true)); // Set PIPE_MODE_SELECT MHW_VDBOX_PIPE_MODE_SELECT_PARAMS pipeModeSelectParams; pipeModeSelectParams.Mode = CODECHAL_DECODE_MODE_JPEG; pipeModeSelectParams.bStreamOutEnabled = m_streamOutEnabled; pipeModeSelectParams.bDeblockerStreamOutEnable = false; pipeModeSelectParams.bPostDeblockOutEnable = false; pipeModeSelectParams.bPreDeblockOutEnable = true; // Set CMD_MFX_SURFACE_STATE MHW_VDBOX_SURFACE_PARAMS surfaceParams; MOS_ZeroMemory(&surfaceParams, sizeof(surfaceParams)); surfaceParams.Mode = CODECHAL_DECODE_MODE_JPEG; surfaceParams.psSurface = &m_destSurface; surfaceParams.ChromaType = m_jpegPicParams->m_chromaType; #ifdef _DECODE_PROCESSING_SUPPORTED if (m_sfcState->m_sfcPipeOut) { surfaceParams.psSurface = &m_sfcState->m_sfcInSurface; } #endif // Set MFX_PIPE_BUF_ADDR_STATE_CMD MHW_VDBOX_PIPE_BUF_ADDR_PARAMS pipeBufAddrParams; pipeBufAddrParams.Mode = CODECHAL_DECODE_MODE_JPEG; // Predeblock surface is the same as destination surface here because there is no deblocking for JPEG pipeBufAddrParams.psPreDeblockSurface = &m_destSurface; pipeBufAddrParams.pDecodedReconParam = &surfaceParams; pipeBufAddrParams.psRawSurface = nullptr; #ifdef _MMC_SUPPORTED CODECHAL_DECODE_CHK_STATUS_RETURN(m_mmc->SetPipeBufAddr(&pipeBufAddrParams, &cmdBuffer)); #endif pipeBufAddrParams.pDecodedReconParam = nullptr; // Set MFX_IND_OBJ_BASE_ADDR_STATE_CMD MHW_VDBOX_IND_OBJ_BASE_ADDR_PARAMS indObjBaseAddrParams; MOS_ZeroMemory(&indObjBaseAddrParams, sizeof(indObjBaseAddrParams)); indObjBaseAddrParams.Mode = CODECHAL_DECODE_MODE_JPEG; indObjBaseAddrParams.dwDataSize = m_copiedDataBufferInUse ? m_nextCopiedDataOffset : m_dataSize; indObjBaseAddrParams.presDataBuffer = &m_resDataBuffer; // Set MFX_JPEG_PIC_STATE_CMD jpegPicState.pJpegPicParams = m_jpegPicParams; if ((m_jpegPicParams->m_rotation == jpegRotation90) || (m_jpegPicParams->m_rotation == jpegRotation270)) { jpegPicState.dwWidthInBlocks = (m_destSurface.dwHeight / CODECHAL_DECODE_JPEG_BLOCK_SIZE) - 1; jpegPicState.dwHeightInBlocks = (m_destSurface.dwWidth / CODECHAL_DECODE_JPEG_BLOCK_SIZE) - 1; } else { jpegPicState.dwWidthInBlocks = (m_destSurface.dwWidth / CODECHAL_DECODE_JPEG_BLOCK_SIZE) - 1; jpegPicState.dwHeightInBlocks = (m_destSurface.dwHeight / CODECHAL_DECODE_JPEG_BLOCK_SIZE) - 1; } // Add commands to command buffer // MI_FLUSH_DW command -> must be before to MFX_PIPE_MODE_SELECT MHW_MI_FLUSH_DW_PARAMS flushDwParams; MOS_ZeroMemory(&flushDwParams, sizeof(flushDwParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiFlushDwCmd( &cmdBuffer, &flushDwParams)); if (m_statusQueryReportingEnabled) { CODECHAL_DECODE_CHK_STATUS_RETURN(StartStatusReport( &cmdBuffer)); } // MFX_PIPE_MODE_SELECT_CMD CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxPipeModeSelectCmd( &cmdBuffer, &pipeModeSelectParams)); #ifdef _DECODE_PROCESSING_SUPPORTED // Output decode result through SFC CODECHAL_DECODE_CHK_STATUS_RETURN(m_sfcState->AddSfcCommands(&cmdBuffer)); #endif // CMD_MFX_SURFACE_STATE CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxSurfaceCmd( &cmdBuffer, &surfaceParams)); // MFX_PIPE_BUF_ADDR_STATE_CMD CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxPipeBufAddrCmd( &cmdBuffer, &pipeBufAddrParams)); // MFX_IND_OBJ_BASE_ADDR_STATE_CMD CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxIndObjBaseAddrCmd( &cmdBuffer, &indObjBaseAddrParams)); // MFX_JPEG_PIC_STATE_CMD CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxJpegPicCmd( &cmdBuffer, &jpegPicState)); m_osInterface->pfnReturnCommandBuffer(m_osInterface, &cmdBuffer, 0); return eStatus; } MOS_STATUS CodechalDecodeJpegG11::DecodePrimitiveLevel() { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; // if the bitstream is not complete, don't do any decoding work. if (m_incompletePicture) { return MOS_STATUS_SUCCESS; } CODECHAL_DECODE_CHK_NULL_RETURN(m_osInterface); MOS_COMMAND_BUFFER cmdBuffer; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnGetCommandBuffer( m_osInterface, &cmdBuffer, 0)); // MFX_QM_STATE_CMD MHW_VDBOX_QM_PARAMS qmParams; MOS_ZeroMemory(&qmParams, sizeof(qmParams)); qmParams.Standard = CODECHAL_JPEG; qmParams.pJpegQuantMatrix = m_jpegQMatrix; // Swapping QM(x,y) to QM(y,x) for 90/270 degree rotation if ((m_jpegPicParams->m_rotation == jpegRotation90) || (m_jpegPicParams->m_rotation == jpegRotation270)) { qmParams.bJpegQMRotation = true; } else { qmParams.bJpegQMRotation = false; } for (uint16_t scanCount = 0; scanCount < m_jpegPicParams->m_numCompInFrame; scanCount++) { // Using scanCount here because the same command is used for JPEG decode and encode uint32_t quantTableSelector = m_jpegPicParams->m_quantTableSelector[scanCount]; qmParams.pJpegQuantMatrix->m_jpegQMTableType[quantTableSelector] = scanCount; qmParams.JpegQMTableSelector = quantTableSelector; CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxQmCmd( &cmdBuffer, &qmParams)); } uint32_t dcCurHuffTblIndex[2] = { 0xff, 0xff }; uint32_t acCurHuffTblIndex[2] = { 0xff, 0xff }; for (uint16_t scanCount = 0; scanCount < m_jpegScanParams->NumScans; scanCount++) { // MFX_JPEG_HUFF_TABLE uint16_t numComponents = m_jpegScanParams->ScanHeader[scanCount].NumComponents; for (uint16_t scanComponent = 0; scanComponent < numComponents; scanComponent++) { // Determine which huffman table we will be writing to // For gray image, componentIdentifier[jpegComponentU] and componentIdentifier[jpegComponentV] are initialized to 0, // and when componentSelector[scanComponent] is equal 0, variable huffTableID is set to 1, and wrong Huffman table is used, // so it is more reasonable to use componentIdentifier[jpegComponentY] to determine which huffman table we will be writing to. uint8_t componentSelector = m_jpegScanParams->ScanHeader[scanCount].ComponentSelector[scanComponent]; uint16_t huffTableID = 0; if (componentSelector == m_jpegPicParams->m_componentIdentifier[jpegComponentY]) { huffTableID = 0; } else { huffTableID = 1; } int32_t acTableSelector = m_jpegScanParams->ScanHeader[scanCount].AcHuffTblSelector[scanComponent]; int32_t dcTableSelector = m_jpegScanParams->ScanHeader[scanCount].DcHuffTblSelector[scanComponent]; // Send the huffman table state command only if the table changed if ((dcTableSelector != dcCurHuffTblIndex[huffTableID]) || (acTableSelector != acCurHuffTblIndex[huffTableID])) { MHW_VDBOX_HUFF_TABLE_PARAMS huffmanTableParams; MOS_ZeroMemory(&huffmanTableParams, sizeof(huffmanTableParams)); huffmanTableParams.HuffTableID = huffTableID; huffmanTableParams.pACBits = &m_jpegHuffmanTable->HuffTable[acTableSelector].AC_BITS[0]; huffmanTableParams.pDCBits = &m_jpegHuffmanTable->HuffTable[dcTableSelector].DC_BITS[0]; huffmanTableParams.pACValues = &m_jpegHuffmanTable->HuffTable[acTableSelector].AC_HUFFVAL[0]; huffmanTableParams.pDCValues = &m_jpegHuffmanTable->HuffTable[dcTableSelector].DC_HUFFVAL[0]; CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxJpegHuffTableCmd( &cmdBuffer, &huffmanTableParams)); // Set the current huffman table indices for the next scan dcCurHuffTblIndex[huffTableID] = dcTableSelector; acCurHuffTblIndex[huffTableID] = acTableSelector; } } MHW_VDBOX_JPEG_BSD_PARAMS jpegBsdObject; MOS_ZeroMemory(&jpegBsdObject, sizeof(jpegBsdObject)); // MFX_JPEG_BSD_OBJECT jpegBsdObject.dwIndirectDataLength = m_jpegScanParams->ScanHeader[scanCount].DataLength; jpegBsdObject.dwDataStartAddress = m_jpegScanParams->ScanHeader[scanCount].DataOffset; jpegBsdObject.dwScanHorizontalPosition = m_jpegScanParams->ScanHeader[scanCount].ScanHoriPosition; jpegBsdObject.dwScanVerticalPosition = m_jpegScanParams->ScanHeader[scanCount].ScanVertPosition; jpegBsdObject.bInterleaved = (numComponents > 1) ? 1 : 0; jpegBsdObject.dwMCUCount = m_jpegScanParams->ScanHeader[scanCount].MCUCount; jpegBsdObject.dwRestartInterval = m_jpegScanParams->ScanHeader[scanCount].RestartInterval; uint16_t scanComponentIndex = 0; for (uint16_t scanComponent = 0; scanComponent < numComponents; scanComponent++) { uint8_t componentSelector = m_jpegScanParams->ScanHeader[scanCount].ComponentSelector[scanComponent]; if (componentSelector == m_jpegPicParams->m_componentIdentifier[jpegComponentY]) { scanComponentIndex = 0; } else if (componentSelector == m_jpegPicParams->m_componentIdentifier[jpegComponentU]) { scanComponentIndex = 1; } else if (componentSelector == m_jpegPicParams->m_componentIdentifier[jpegComponentV]) { scanComponentIndex = 2; } // Add logic for component identifier JPEG_A jpegBsdObject.sScanComponent |= (1 << scanComponentIndex); } CODECHAL_DECODE_CHK_STATUS_RETURN(m_mfxInterface->AddMfxJpegBsdObjCmd( &cmdBuffer, &jpegBsdObject)); } // Check if destination surface needs to be synchronized 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; 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); MHW_MI_FLUSH_DW_PARAMS flushDwParams; MOS_ZeroMemory(&flushDwParams, sizeof(flushDwParams)); CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiFlushDwCmd( &cmdBuffer, &flushDwParams)); // 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( &cmdBuffer, &syncParams)); } if (m_statusQueryReportingEnabled) { CodechalDecodeStatusReport decodeStatusReport; decodeStatusReport.m_statusReportNumber = m_statusReportFeedbackNumber; decodeStatusReport.m_codecStatus = CODECHAL_STATUS_UNAVAILABLE; decodeStatusReport.m_currDecodedPicRes = m_destSurface.OsResource; CODECHAL_DECODE_CHK_STATUS_RETURN(EndStatusReport( decodeStatusReport, &cmdBuffer)); } CODECHAL_DECODE_CHK_STATUS_RETURN(m_miInterface->AddMiBatchBufferEnd( &cmdBuffer, nullptr)); m_osInterface->pfnReturnCommandBuffer(m_osInterface, &cmdBuffer, 0); CODECHAL_DEBUG_TOOL( CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpCmdBuffer( &cmdBuffer, CODECHAL_NUM_MEDIA_STATES, "_DEC")); ) if (m_copiedDataBufferInUse) { //Sync up complete frame syncParams = g_cInitSyncParams; syncParams.GpuContext = m_videoContextForWa; syncParams.presSyncResource = &m_resSyncObjectWaContextInUse; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnEngineSignal( m_osInterface, &syncParams)); syncParams = g_cInitSyncParams; syncParams.GpuContext = m_videoContext; syncParams.presSyncResource = &m_resSyncObjectWaContextInUse; CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnEngineWait( m_osInterface, &syncParams)); } if ( MOS_VE_SUPPORTED(m_osInterface)) { CodecHalDecodeSinglePipeVE_PopulateHintParams(m_veState, &cmdBuffer, true); } HalOcaInterface::On1stLevelBBEnd(cmdBuffer, *m_osInterface); CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnSubmitCommandBuffer( m_osInterface, &cmdBuffer, m_videoContextUsesNullHw)); CODECHAL_DEBUG_TOOL( m_mmc->UpdateUserFeatureKey(&m_destSurface);) if (m_statusQueryReportingEnabled) { CODECHAL_DECODE_CHK_STATUS_RETURN(ResetStatusReport( m_videoContextUsesNullHw)); } // Set output surface layout SetOutputSurfaceLayout(&m_decodeParams.m_outputSurfLayout); // Send the signal to indicate decode completion, in case On-Demand Sync is not present CODECHAL_DECODE_CHK_STATUS_RETURN(m_osInterface->pfnResourceSignal( m_osInterface, &syncParams)); CODECHAL_DEBUG_TOOL( CODECHAL_DECODE_CHK_STATUS_RETURN(m_debugInterface->DumpYUVSurface( &m_destSurface, CodechalDbgAttr::attrDecodeOutputSurface, "DstSurf"));) return eStatus; } MOS_STATUS CodechalDecodeJpegG11::AllocateStandard( CodechalSetting * settings) { MOS_STATUS eStatus = MOS_STATUS_SUCCESS; CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_RETURN(settings); CODECHAL_DECODE_CHK_STATUS_RETURN(CodechalDecodeJpeg::AllocateStandard(settings)); if ( MOS_VE_SUPPORTED(m_osInterface)) { static_cast(m_mfxInterface)->DisableScalabilitySupport(); //single pipe VE initialize m_veState = (PCODECHAL_DECODE_SINGLEPIPE_VIRTUALENGINE_STATE)MOS_AllocAndZeroMemory(sizeof(CODECHAL_DECODE_SINGLEPIPE_VIRTUALENGINE_STATE)); CODECHAL_DECODE_CHK_NULL_RETURN(m_veState); CODECHAL_DECODE_CHK_STATUS_RETURN(CodecHalDecodeSinglePipeVE_InitInterface(m_osInterface, m_veState)); } return eStatus; } CodechalDecodeJpegG11::CodechalDecodeJpegG11( CodechalHwInterface *hwInterface, CodechalDebugInterface* debugInterface, PCODECHAL_STANDARD_INFO standardInfo) : CodechalDecodeJpeg(hwInterface, debugInterface, standardInfo) { CODECHAL_DECODE_FUNCTION_ENTER; CODECHAL_DECODE_CHK_NULL_NO_STATUS_RETURN(m_osInterface); m_osInterface->pfnVirtualEngineSupported(m_osInterface, true, true); }