/* * Copyright (C) 2018-2022 Intel Corporation * * SPDX-License-Identifier: MIT * */ #include "shared/source/os_interface/windows/wddm/wddm.h" #include "shared/source/command_stream/command_stream_receiver.h" #include "shared/source/command_stream/preemption.h" #include "shared/source/execution_environment/execution_environment.h" #include "shared/source/execution_environment/root_device_environment.h" #include "shared/source/gmm_helper/client_context/gmm_client_context.h" #include "shared/source/gmm_helper/gmm.h" #include "shared/source/gmm_helper/gmm_helper.h" #include "shared/source/gmm_helper/page_table_mngr.h" #include "shared/source/gmm_helper/resource_info.h" #include "shared/source/helpers/api_specific_config.h" #include "shared/source/helpers/heap_assigner.h" #include "shared/source/helpers/mt_helpers.h" #include "shared/source/helpers/string.h" #include "shared/source/helpers/windows/gmm_callbacks.h" #include "shared/source/os_interface/hw_info_config.h" #include "shared/source/os_interface/sys_calls_common.h" #include "shared/source/os_interface/windows/driver_info_windows.h" #include "shared/source/os_interface/windows/dxcore_wrapper.h" #include "shared/source/os_interface/windows/gdi_interface.h" #include "shared/source/os_interface/windows/kmdaf_listener.h" #include "shared/source/os_interface/windows/os_context_win.h" #include "shared/source/os_interface/windows/os_environment_win.h" #include "shared/source/os_interface/windows/sharedata_wrapper.h" #include "shared/source/os_interface/windows/wddm/adapter_factory.h" #include "shared/source/os_interface/windows/wddm/adapter_info.h" #include "shared/source/os_interface/windows/wddm/um_km_data_translator.h" #include "shared/source/os_interface/windows/wddm/wddm_interface.h" #include "shared/source/os_interface/windows/wddm/wddm_residency_logger.h" #include "shared/source/os_interface/windows/wddm_allocation.h" #include "shared/source/os_interface/windows/wddm_engine_mapper.h" #include "shared/source/os_interface/windows/wddm_memory_manager.h" #include "shared/source/os_interface/windows/wddm_residency_allocations_container.h" #include "shared/source/sku_info/operations/windows/sku_info_receiver.h" #include "shared/source/utilities/stackvec.h" #include "gmm_memory.h" namespace NEO { extern Wddm::CreateDXGIFactoryFcn getCreateDxgiFactory(); extern Wddm::DXCoreCreateAdapterFactoryFcn getDXCoreCreateAdapterFactory(); extern Wddm::GetSystemInfoFcn getGetSystemInfo(); Wddm::DXCoreCreateAdapterFactoryFcn Wddm::dXCoreCreateAdapterFactory = getDXCoreCreateAdapterFactory(); Wddm::CreateDXGIFactoryFcn Wddm::createDxgiFactory = getCreateDxgiFactory(); Wddm::GetSystemInfoFcn Wddm::getSystemInfo = getGetSystemInfo(); Wddm::Wddm(std::unique_ptr &&hwDeviceIdIn, RootDeviceEnvironment &rootDeviceEnvironment) : DriverModel(DriverModelType::WDDM), hwDeviceId(std::move(hwDeviceIdIn)), rootDeviceEnvironment(rootDeviceEnvironment) { UNRECOVERABLE_IF(!hwDeviceId); featureTable.reset(new FeatureTable()); workaroundTable.reset(new WorkaroundTable()); gtSystemInfo.reset(new GT_SYSTEM_INFO); gfxPlatform.reset(new PLATFORM); memset(gtSystemInfo.get(), 0, sizeof(*gtSystemInfo)); memset(gfxPlatform.get(), 0, sizeof(*gfxPlatform)); this->enablePreemptionRegValue = NEO::readEnablePreemptionRegKey(); kmDafListener = std::unique_ptr(new KmDafListener); temporaryResources = std::make_unique(this); osMemory = OSMemory::create(); } Wddm::~Wddm() { temporaryResources.reset(); destroyPagingQueue(); destroyDevice(); UNRECOVERABLE_IF(temporaryResources.get()) } bool Wddm::init() { if (!rootDeviceEnvironment.osInterface) { rootDeviceEnvironment.osInterface = std::make_unique(); rootDeviceEnvironment.osInterface->setDriverModel(std::unique_ptr(this)); } if (!queryAdapterInfo()) { return false; } auto productFamily = gfxPlatform->eProductFamily; if (!hardwareInfoTable[productFamily]) { return false; } auto hardwareInfo = rootDeviceEnvironment.getMutableHardwareInfo(); hardwareInfo->platform = *gfxPlatform; hardwareInfo->featureTable = *featureTable; hardwareInfo->workaroundTable = *workaroundTable; hardwareInfo->gtSystemInfo = *gtSystemInfo; hardwareInfo->capabilityTable = hardwareInfoTable[productFamily]->capabilityTable; hardwareInfo->capabilityTable.maxRenderFrequency = maxRenderFrequency; hardwareInfo->capabilityTable.instrumentationEnabled = (hardwareInfo->capabilityTable.instrumentationEnabled && instrumentationEnabled); auto &productHelper = rootDeviceEnvironment.getHelper(); productHelper.adjustPlatformForProductFamily(hardwareInfo); if (productHelper.configureHwInfoWddm(hardwareInfo, hardwareInfo, nullptr)) { return false; } setPlatformSupportEvictIfNecessaryFlag(productHelper); auto preemptionMode = PreemptionHelper::getDefaultPreemptionMode(*hardwareInfo); populateIpVersion(*hardwareInfo); rootDeviceEnvironment.initGmm(); this->rootDeviceEnvironment.getGmmClientContext()->setHandleAllocator(this->hwDeviceId->getUmKmDataTranslator()->createGmmHandleAllocator()); [[maybe_unused]] bool result = rootDeviceEnvironment.initAilConfiguration(); DEBUG_BREAK_IF(!result); if (WddmVersion::WDDM_2_3 == getWddmVersion()) { wddmInterface = std::make_unique(*this); } else { wddmInterface = std::make_unique(*this); } if (!createDevice(preemptionMode)) { return false; } if (!createPagingQueue()) { return false; } if (!gmmMemory) { gmmMemory.reset(GmmMemory::create(rootDeviceEnvironment.getGmmClientContext())); } if (rootDeviceEnvironment.executionEnvironment.isDebuggingEnabled()) { if (!buildTopologyMapping()) { return false; } } return configureDeviceAddressSpace(); } void Wddm::setPlatformSupportEvictIfNecessaryFlag(const HwInfoConfig &hwInfoConfig) { platformSupportsEvictIfNecessary = hwInfoConfig.isEvictionIfNecessaryFlagSupported(); int32_t overridePlatformSupportsEvictIfNecessary = DebugManager.flags.PlaformSupportEvictIfNecessaryFlag.get(); if (overridePlatformSupportsEvictIfNecessary != -1) { platformSupportsEvictIfNecessary = !!overridePlatformSupportsEvictIfNecessary; } forceEvictOnlyIfNecessary = DebugManager.flags.ForceEvictOnlyIfNecessaryFlag.get(); } bool Wddm::buildTopologyMapping() { auto hwInfo = rootDeviceEnvironment.getHardwareInfo(); UNRECOVERABLE_IF(hwInfo->gtSystemInfo.MultiTileArchInfo.TileCount > 1); TopologyMapping mapping; if (!translateTopologyInfo(mapping)) { PRINT_DEBUGGER_ERROR_LOG("translateTopologyInfo Failed\n", ""); return false; } this->topologyMap[0] = mapping; return true; } bool Wddm::translateTopologyInfo(TopologyMapping &mapping) { int sliceCount = 0; int subSliceCount = 0; int euCount = 0; std::vector sliceIndices; auto gtSystemInfo = rootDeviceEnvironment.getHardwareInfo()->gtSystemInfo; sliceIndices.reserve(gtSystemInfo.SliceCount); auto hwInfo = rootDeviceEnvironment.getHardwareInfo(); const uint32_t highestEnabledSlice = NEO::HwHelper::getHighestEnabledSlice(*hwInfo); for (uint32_t x = 0; x < std::max(highestEnabledSlice, hwInfo->gtSystemInfo.MaxSlicesSupported); x++) { if (!gtSystemInfo.SliceInfo[x].Enabled) { continue; } sliceIndices.push_back(x); sliceCount++; std::vector subSliceIndices; subSliceIndices.reserve((gtSystemInfo.SliceInfo[x].DualSubSliceEnabledCount) * GT_MAX_SUBSLICE_PER_DSS); // subSliceIndex is used to track the index number of subslices from all DSS in this slice int subSliceIndex = -1; for (uint32_t dss = 0; dss < GT_MAX_DUALSUBSLICE_PER_SLICE; dss++) { if (!gtSystemInfo.SliceInfo[x].DSSInfo[dss].Enabled) { subSliceIndex += 2; continue; } for (uint32_t y = 0; y < GT_MAX_SUBSLICE_PER_DSS; y++) { subSliceIndex++; if (!gtSystemInfo.SliceInfo[x].DSSInfo[dss].SubSlice[y].Enabled) { continue; } subSliceCount++; subSliceIndices.push_back(subSliceIndex); euCount += gtSystemInfo.SliceInfo[x].DSSInfo[dss].SubSlice[y].EuEnabledCount; } } // single slice available if (sliceCount == 1) { mapping.subsliceIndices = std::move(subSliceIndices); } } if (sliceIndices.size()) { mapping.sliceIndices = std::move(sliceIndices); } if (sliceCount != 1) { mapping.subsliceIndices.clear(); } PRINT_DEBUGGER_INFO_LOG("Topology Mapping: sliceCount=%d subSliceCount=%d euCount=%d\n", sliceCount, subSliceCount, euCount); return (sliceCount && subSliceCount && euCount); } bool Wddm::queryAdapterInfo() { NTSTATUS status = STATUS_UNSUCCESSFUL; ADAPTER_INFO_KMD adapterInfo = {}; D3DKMT_QUERYADAPTERINFO queryAdapterInfo = {}; queryAdapterInfo.hAdapter = getAdapter(); queryAdapterInfo.Type = KMTQAITYPE_UMDRIVERPRIVATE; if (hwDeviceId->getUmKmDataTranslator()->enabled()) { UmKmDataTempStorage internalRepresentation(hwDeviceId->getUmKmDataTranslator()->getSizeForAdapterInfoInternalRepresentation()); queryAdapterInfo.pPrivateDriverData = internalRepresentation.data(); queryAdapterInfo.PrivateDriverDataSize = static_cast(internalRepresentation.size()); status = getGdi()->queryAdapterInfo(&queryAdapterInfo); DEBUG_BREAK_IF(status != STATUS_SUCCESS); if (status == STATUS_SUCCESS) { bool translated = hwDeviceId->getUmKmDataTranslator()->translateAdapterInfoFromInternalRepresentation(adapterInfo, internalRepresentation.data(), internalRepresentation.size()); status = translated ? STATUS_SUCCESS : STATUS_UNSUCCESSFUL; } } else { queryAdapterInfo.pPrivateDriverData = &adapterInfo; queryAdapterInfo.PrivateDriverDataSize = sizeof(ADAPTER_INFO_KMD); status = getGdi()->queryAdapterInfo(&queryAdapterInfo); DEBUG_BREAK_IF(status != STATUS_SUCCESS); } // translate if (status == STATUS_SUCCESS) { memcpy_s(gtSystemInfo.get(), sizeof(GT_SYSTEM_INFO), &adapterInfo.SystemInfo, sizeof(GT_SYSTEM_INFO)); memcpy_s(gfxPlatform.get(), sizeof(PLATFORM), &adapterInfo.GfxPlatform, sizeof(PLATFORM)); SkuInfoReceiver::receiveFtrTableFromAdapterInfo(featureTable.get(), &adapterInfo); SkuInfoReceiver::receiveWaTableFromAdapterInfo(workaroundTable.get(), &adapterInfo); memcpy_s(&gfxPartition, sizeof(gfxPartition), &adapterInfo.GfxPartition, sizeof(GMM_GFX_PARTITIONING)); memcpy_s(&adapterBDF, sizeof(adapterBDF), &adapterInfo.stAdapterBDF, sizeof(ADAPTER_BDF)); deviceRegistryPath = std::string(adapterInfo.DeviceRegistryPath, sizeof(adapterInfo.DeviceRegistryPath)).c_str(); systemSharedMemory = adapterInfo.SystemSharedMemory; dedicatedVideoMemory = adapterInfo.DedicatedVideoMemory; maxRenderFrequency = adapterInfo.MaxRenderFreq; timestampFrequency = adapterInfo.GfxTimeStampFreq; instrumentationEnabled = adapterInfo.Caps.InstrumentationIsEnabled != 0; populateAdditionalAdapterInfoOptions(adapterInfo); } return status == STATUS_SUCCESS; } bool Wddm::createPagingQueue() { D3DKMT_CREATEPAGINGQUEUE createPagingQueue = {}; createPagingQueue.hDevice = device; createPagingQueue.Priority = D3DDDI_PAGINGQUEUE_PRIORITY_NORMAL; NTSTATUS status = getGdi()->createPagingQueue(&createPagingQueue); if (status == STATUS_SUCCESS) { pagingQueue = createPagingQueue.hPagingQueue; pagingQueueSyncObject = createPagingQueue.hSyncObject; pagingFenceAddress = reinterpret_cast(createPagingQueue.FenceValueCPUVirtualAddress); createPagingFenceLogger(); } return status == STATUS_SUCCESS; } bool Wddm::destroyPagingQueue() { D3DDDI_DESTROYPAGINGQUEUE destroyPagingQueue = {}; if (pagingQueue) { destroyPagingQueue.hPagingQueue = pagingQueue; [[maybe_unused]] NTSTATUS status = getGdi()->destroyPagingQueue(&destroyPagingQueue); DEBUG_BREAK_IF(status != STATUS_SUCCESS); pagingQueue = 0; } return true; } bool Wddm::createDevice(PreemptionMode preemptionMode) { NTSTATUS status = STATUS_UNSUCCESSFUL; D3DKMT_CREATEDEVICE createDevice = {}; if (hwDeviceId) { createDevice.hAdapter = getAdapter(); createDevice.Flags.LegacyMode = FALSE; if (preemptionMode >= PreemptionMode::MidBatch) { createDevice.Flags.DisableGpuTimeout = getEnablePreemptionRegValue(); } status = getGdi()->createDevice(&createDevice); if (status == STATUS_SUCCESS) { device = createDevice.hDevice; } } return status == STATUS_SUCCESS; } bool Wddm::destroyDevice() { D3DKMT_DESTROYDEVICE destroyDevice = {}; if (device) { destroyDevice.hDevice = device; [[maybe_unused]] NTSTATUS status = getGdi()->destroyDevice(&destroyDevice); DEBUG_BREAK_IF(status != STATUS_SUCCESS); device = 0; } return true; } bool validDriverStorePath(OsEnvironmentWin &osEnvironment, D3DKMT_HANDLE adapter) { D3DKMT_QUERYADAPTERINFO queryAdapterInfo = {}; ADAPTER_INFO_KMD adapterInfo = {}; queryAdapterInfo.hAdapter = adapter; queryAdapterInfo.Type = KMTQAITYPE_UMDRIVERPRIVATE; queryAdapterInfo.pPrivateDriverData = &adapterInfo; queryAdapterInfo.PrivateDriverDataSize = sizeof(ADAPTER_INFO_KMD); auto status = osEnvironment.gdi->queryAdapterInfo(&queryAdapterInfo); if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF("queryAdapterInfo failed"); return false; } std::string deviceRegistryPath = adapterInfo.DeviceRegistryPath; return isCompatibleDriverStore(std::move(deviceRegistryPath)); } std::unique_ptr createHwDeviceIdFromAdapterLuid(OsEnvironmentWin &osEnvironment, LUID adapterLuid) { D3DKMT_OPENADAPTERFROMLUID openAdapterData = {}; openAdapterData.AdapterLuid = adapterLuid; auto status = osEnvironment.gdi->openAdapterFromLuid(&openAdapterData); if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF("openAdapterFromLuid failed"); return nullptr; } std::unique_ptr umKmDataTranslator = createUmKmDataTranslator(*osEnvironment.gdi, openAdapterData.hAdapter); if (false == umKmDataTranslator->enabled()) { if (false == validDriverStorePath(osEnvironment, openAdapterData.hAdapter)) { return nullptr; } } D3DKMT_QUERYADAPTERINFO queryAdapterInfo = {}; D3DKMT_ADAPTERTYPE queryAdapterType = {}; queryAdapterInfo.hAdapter = openAdapterData.hAdapter; queryAdapterInfo.Type = KMTQAITYPE_ADAPTERTYPE; queryAdapterInfo.pPrivateDriverData = &queryAdapterType; queryAdapterInfo.PrivateDriverDataSize = sizeof(queryAdapterType); status = osEnvironment.gdi->queryAdapterInfo(&queryAdapterInfo); if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF("queryAdapterInfo failed"); return nullptr; } if (0 == queryAdapterType.RenderSupported) { return nullptr; } return std::make_unique(openAdapterData.hAdapter, adapterLuid, &osEnvironment, std::move(umKmDataTranslator)); } std::vector> Wddm::discoverDevices(ExecutionEnvironment &executionEnvironment) { auto osEnvironment = new OsEnvironmentWin(); auto gdi = osEnvironment->gdi.get(); executionEnvironment.osEnvironment.reset(osEnvironment); if (!gdi->isInitialized()) { return {}; } auto adapterFactory = AdapterFactory::create(Wddm::dXCoreCreateAdapterFactory, Wddm::createDxgiFactory); if (false == adapterFactory->isSupported()) { return {}; } size_t numRootDevices = 0u; if (DebugManager.flags.CreateMultipleRootDevices.get()) { numRootDevices = DebugManager.flags.CreateMultipleRootDevices.get(); } std::vector> hwDeviceIds; do { if (false == adapterFactory->createSnapshotOfAvailableAdapters()) { return hwDeviceIds; } auto adapterCount = adapterFactory->getNumAdaptersInSnapshot(); for (uint32_t i = 0; i < adapterCount; ++i) { AdapterFactory::AdapterDesc adapterDesc; if (false == adapterFactory->getAdapterDesc(i, adapterDesc)) { DEBUG_BREAK_IF(true); continue; } if (adapterDesc.type == AdapterFactory::AdapterDesc::Type::NotHardware) { continue; } if (false == canUseAdapterBasedOnDriverDesc(adapterDesc.driverDescription.c_str())) { continue; } if (false == isAllowedDeviceId(adapterDesc.deviceId)) { continue; } auto hwDeviceId = createHwDeviceIdFromAdapterLuid(*osEnvironment, adapterDesc.luid); if (hwDeviceId) { hwDeviceIds.push_back(std::unique_ptr(hwDeviceId.release())); } if (!hwDeviceIds.empty() && hwDeviceIds.size() == numRootDevices) { break; } } if (hwDeviceIds.empty()) { break; } } while (hwDeviceIds.size() < numRootDevices); return hwDeviceIds; } bool Wddm::evict(const D3DKMT_HANDLE *handleList, uint32_t numOfHandles, uint64_t &sizeToTrim, bool evictNeeded) { NTSTATUS status = STATUS_SUCCESS; D3DKMT_EVICT evict = {}; evict.AllocationList = handleList; evict.hDevice = device; evict.NumAllocations = numOfHandles; evict.NumBytesToTrim = 0; evict.Flags.EvictOnlyIfNecessary = adjustEvictNeededParameter(evictNeeded) ? 0 : 1; status = getGdi()->evict(&evict); sizeToTrim = evict.NumBytesToTrim; kmDafListener->notifyEvict(featureTable->flags.ftrKmdDaf, getAdapter(), device, handleList, numOfHandles, getGdi()->escape); return status == STATUS_SUCCESS; } bool Wddm::makeResident(const D3DKMT_HANDLE *handles, uint32_t count, bool cantTrimFurther, uint64_t *numberOfBytesToTrim, size_t totalSize) { NTSTATUS status = STATUS_SUCCESS; D3DDDI_MAKERESIDENT makeResident = {}; UINT priority = 0; bool success = false; perfLogResidencyReportAllocations(residencyLogger.get(), count, totalSize); makeResident.AllocationList = handles; makeResident.hPagingQueue = pagingQueue; makeResident.NumAllocations = count; makeResident.PriorityList = &priority; makeResident.Flags.CantTrimFurther = cantTrimFurther ? 1 : 0; makeResident.Flags.MustSucceed = 0; status = getGdi()->makeResident(&makeResident); if (status == STATUS_PENDING) { perfLogResidencyMakeResident(residencyLogger.get(), true, makeResident.PagingFenceValue); updatePagingFenceValue(makeResident.PagingFenceValue); success = true; } else if (status == STATUS_SUCCESS) { perfLogResidencyMakeResident(residencyLogger.get(), false, makeResident.PagingFenceValue); success = true; } else { DEBUG_BREAK_IF(true); perfLogResidencyTrimRequired(residencyLogger.get(), makeResident.NumBytesToTrim); if (numberOfBytesToTrim != nullptr) { *numberOfBytesToTrim = makeResident.NumBytesToTrim; } return false; } kmDafListener->notifyMakeResident(featureTable->flags.ftrKmdDaf, getAdapter(), device, handles, count, getGdi()->escape); return success; } bool Wddm::mapGpuVirtualAddress(AllocationStorageData *allocationStorageData) { auto osHandle = static_cast(allocationStorageData->osHandleStorage); return mapGpuVirtualAddress(osHandle->gmm, osHandle->handle, 0u, MemoryConstants::maxSvmAddress, castToUint64(allocationStorageData->cpuPtr), osHandle->gpuPtr); } bool Wddm::mapGpuVirtualAddress(Gmm *gmm, D3DKMT_HANDLE handle, D3DGPU_VIRTUAL_ADDRESS minimumAddress, D3DGPU_VIRTUAL_ADDRESS maximumAddress, D3DGPU_VIRTUAL_ADDRESS preferredAddress, D3DGPU_VIRTUAL_ADDRESS &gpuPtr) { D3DDDI_MAPGPUVIRTUALADDRESS mapGPUVA = {}; D3DDDIGPUVIRTUALADDRESS_PROTECTION_TYPE protectionType = {}; protectionType.Write = TRUE; uint64_t size = gmm->gmmResourceInfo->getSizeAllocation(); mapGPUVA.hPagingQueue = pagingQueue; mapGPUVA.hAllocation = handle; mapGPUVA.Protection = protectionType; mapGPUVA.SizeInPages = size / MemoryConstants::pageSize; mapGPUVA.OffsetInPages = 0; mapGPUVA.BaseAddress = preferredAddress; mapGPUVA.MinimumAddress = minimumAddress; mapGPUVA.MaximumAddress = maximumAddress; applyAdditionalMapGPUVAFields(mapGPUVA, gmm); NTSTATUS status = getGdi()->mapGpuVirtualAddress(&mapGPUVA); auto gmmHelper = gmm->getGmmHelper(); gpuPtr = gmmHelper->canonize(mapGPUVA.VirtualAddress); if (status == STATUS_PENDING) { updatePagingFenceValue(mapGPUVA.PagingFenceValue); status = STATUS_SUCCESS; } if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF(true); return false; } kmDafListener->notifyMapGpuVA(featureTable->flags.ftrKmdDaf, getAdapter(), device, handle, mapGPUVA.VirtualAddress, getGdi()->escape); bool ret = true; if (gmm->isCompressionEnabled && HwInfoConfig::get(gfxPlatform->eProductFamily)->isPageTableManagerSupported(*rootDeviceEnvironment.getHardwareInfo())) { for (auto engine : rootDeviceEnvironment.executionEnvironment.memoryManager->getRegisteredEngines()) { if (engine.commandStreamReceiver->pageTableManager.get()) { ret &= engine.commandStreamReceiver->pageTableManager->updateAuxTable(gpuPtr, gmm, true); } } } return ret; } D3DGPU_VIRTUAL_ADDRESS Wddm::reserveGpuVirtualAddress(D3DGPU_VIRTUAL_ADDRESS minimumAddress, D3DGPU_VIRTUAL_ADDRESS maximumAddress, D3DGPU_SIZE_T size) { UNRECOVERABLE_IF(size % MemoryConstants::pageSize64k); D3DDDI_RESERVEGPUVIRTUALADDRESS reserveGpuVirtualAddress = {}; reserveGpuVirtualAddress.MinimumAddress = minimumAddress; reserveGpuVirtualAddress.MaximumAddress = maximumAddress; reserveGpuVirtualAddress.hPagingQueue = this->pagingQueue; reserveGpuVirtualAddress.Size = size; NTSTATUS status = getGdi()->reserveGpuVirtualAddress(&reserveGpuVirtualAddress); UNRECOVERABLE_IF(status != STATUS_SUCCESS); return reserveGpuVirtualAddress.VirtualAddress; } bool Wddm::freeGpuVirtualAddress(D3DGPU_VIRTUAL_ADDRESS &gpuPtr, uint64_t size) { NTSTATUS status = STATUS_SUCCESS; D3DKMT_FREEGPUVIRTUALADDRESS freeGpuva = {}; freeGpuva.hAdapter = getAdapter(); freeGpuva.BaseAddress = rootDeviceEnvironment.getGmmHelper()->decanonize(gpuPtr); freeGpuva.Size = size; status = getGdi()->freeGpuVirtualAddress(&freeGpuva); gpuPtr = static_cast(0); kmDafListener->notifyUnmapGpuVA(featureTable->flags.ftrKmdDaf, getAdapter(), device, freeGpuva.BaseAddress, getGdi()->escape); return status == STATUS_SUCCESS; } NTSTATUS Wddm::createAllocation(const void *alignedCpuPtr, const Gmm *gmm, D3DKMT_HANDLE &outHandle, D3DKMT_HANDLE &outResourceHandle, uint64_t *outSharedHandle) { NTSTATUS status = STATUS_UNSUCCESSFUL; D3DDDI_ALLOCATIONINFO2 allocationInfo = {}; D3DKMT_CREATEALLOCATION createAllocation = {}; if (gmm == nullptr) return false; allocationInfo.pSystemMem = alignedCpuPtr; allocationInfo.pPrivateDriverData = gmm->gmmResourceInfo->peekHandle(); allocationInfo.PrivateDriverDataSize = static_cast(gmm->gmmResourceInfo->peekHandleSize()); createAllocation.NumAllocations = 1; createAllocation.Flags.CreateShared = outSharedHandle ? TRUE : FALSE; createAllocation.Flags.NtSecuritySharing = outSharedHandle ? TRUE : FALSE; createAllocation.Flags.CreateResource = outSharedHandle ? TRUE : FALSE; createAllocation.pAllocationInfo2 = &allocationInfo; createAllocation.hDevice = device; status = getGdi()->createAllocation2(&createAllocation); if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF(true); return status; } gmm->gmmResourceInfo->refreshHandle(); outHandle = allocationInfo.hAllocation; outResourceHandle = createAllocation.hResource; if (outSharedHandle) { HANDLE ntSharedHandle = NULL; status = this->createNTHandle(&outResourceHandle, &ntSharedHandle); if (status != STATUS_SUCCESS) { DEBUG_BREAK_IF(true); [[maybe_unused]] auto destroyStatus = this->destroyAllocations(&outHandle, 1, outResourceHandle); outHandle = NULL_HANDLE; outResourceHandle = NULL_HANDLE; DEBUG_BREAK_IF(destroyStatus != STATUS_SUCCESS); return status; } *outSharedHandle = castToUint64(ntSharedHandle); } kmDafListener->notifyWriteTarget(featureTable->flags.ftrKmdDaf, getAdapter(), device, outHandle, getGdi()->escape); return status; } bool Wddm::createAllocation(const Gmm *gmm, D3DKMT_HANDLE &outHandle) { D3DKMT_HANDLE outResourceHandle = NULL_HANDLE; uint64_t *outSharedHandle = nullptr; auto result = this->createAllocation(nullptr, gmm, outHandle, outResourceHandle, outSharedHandle); return STATUS_SUCCESS == result; } bool Wddm::setAllocationPriority(const D3DKMT_HANDLE *handles, uint32_t allocationCount, uint32_t priority) { D3DKMT_SETALLOCATIONPRIORITY setAllocationPriority = {}; StackVec priorities{}; priorities.resize(allocationCount); for (auto i = 0u; i < allocationCount; i++) { priorities[i] = priority; } setAllocationPriority.hDevice = device; setAllocationPriority.AllocationCount = allocationCount; setAllocationPriority.hResource = NULL_HANDLE; setAllocationPriority.phAllocationList = handles; setAllocationPriority.pPriorities = priorities.data(); auto status = getGdi()->setAllocationPriority(&setAllocationPriority); DEBUG_BREAK_IF(STATUS_SUCCESS != status); return STATUS_SUCCESS == status; } NTSTATUS Wddm::createAllocationsAndMapGpuVa(OsHandleStorage &osHandles) { NTSTATUS status = STATUS_UNSUCCESSFUL; D3DDDI_ALLOCATIONINFO2 allocationInfo[maxFragmentsCount] = {}; D3DKMT_CREATEALLOCATION createAllocation = {}; auto allocationCount = 0; for (unsigned int i = 0; i < maxFragmentsCount; i++) { if (!osHandles.fragmentStorageData[i].osHandleStorage) { break; } auto osHandle = static_cast(osHandles.fragmentStorageData[i].osHandleStorage); if ((osHandle->handle == (D3DKMT_HANDLE)0) && (osHandles.fragmentStorageData[i].fragmentSize)) { allocationInfo[allocationCount].pPrivateDriverData = osHandle->gmm->gmmResourceInfo->peekHandle(); [[maybe_unused]] auto pSysMem = osHandles.fragmentStorageData[i].cpuPtr; [[maybe_unused]] auto pSysMemFromGmm = osHandle->gmm->gmmResourceInfo->getSystemMemPointer(); DEBUG_BREAK_IF(pSysMemFromGmm != pSysMem); allocationInfo[allocationCount].pSystemMem = osHandles.fragmentStorageData[i].cpuPtr; allocationInfo[allocationCount].PrivateDriverDataSize = static_cast(osHandle->gmm->gmmResourceInfo->peekHandleSize()); allocationCount++; } } if (allocationCount == 0) { return STATUS_SUCCESS; } createAllocation.hGlobalShare = 0; createAllocation.PrivateRuntimeDataSize = 0; createAllocation.PrivateDriverDataSize = 0; createAllocation.Flags.Reserved = 0; createAllocation.NumAllocations = allocationCount; createAllocation.pPrivateRuntimeData = nullptr; createAllocation.pPrivateDriverData = nullptr; createAllocation.Flags.NonSecure = FALSE; createAllocation.Flags.CreateShared = FALSE; createAllocation.Flags.RestrictSharedAccess = FALSE; createAllocation.Flags.CreateResource = FALSE; createAllocation.pAllocationInfo2 = allocationInfo; createAllocation.hDevice = device; while (status == STATUS_UNSUCCESSFUL) { status = getGdi()->createAllocation2(&createAllocation); if (status != STATUS_SUCCESS) { PRINT_DEBUG_STRING(DebugManager.flags.PrintDebugMessages.get(), stderr, "%s status: %d", __FUNCTION__, status); DEBUG_BREAK_IF(status != STATUS_GRAPHICS_NO_VIDEO_MEMORY); break; } auto allocationIndex = 0; for (int i = 0; i < allocationCount; i++) { while (static_cast(osHandles.fragmentStorageData[allocationIndex].osHandleStorage)->handle) { allocationIndex++; } static_cast(osHandles.fragmentStorageData[allocationIndex].osHandleStorage)->handle = allocationInfo[i].hAllocation; bool success = mapGpuVirtualAddress(&osHandles.fragmentStorageData[allocationIndex]); if (!success) { osHandles.fragmentStorageData[allocationIndex].freeTheFragment = true; PRINT_DEBUG_STRING(DebugManager.flags.PrintDebugMessages.get(), stderr, "%s mapGpuVirtualAddress: %d", __FUNCTION__, success); DEBUG_BREAK_IF(true); return STATUS_GRAPHICS_NO_VIDEO_MEMORY; } allocationIndex++; kmDafListener->notifyWriteTarget(featureTable->flags.ftrKmdDaf, getAdapter(), device, allocationInfo[i].hAllocation, getGdi()->escape); } status = STATUS_SUCCESS; } return status; } bool Wddm::destroyAllocations(const D3DKMT_HANDLE *handles, uint32_t allocationCount, D3DKMT_HANDLE resourceHandle) { if ((0U == allocationCount) && (0U == resourceHandle)) { return true; } NTSTATUS status = STATUS_SUCCESS; D3DKMT_DESTROYALLOCATION2 destroyAllocation = {}; DEBUG_BREAK_IF(!(allocationCount <= 1 || resourceHandle == 0)); destroyAllocation.hDevice = device; destroyAllocation.hResource = resourceHandle; destroyAllocation.phAllocationList = handles; destroyAllocation.AllocationCount = allocationCount; destroyAllocation.Flags.AssumeNotInUse = 1; status = getGdi()->destroyAllocation2(&destroyAllocation); return status == STATUS_SUCCESS; } bool Wddm::verifySharedHandle(D3DKMT_HANDLE osHandle) { D3DKMT_QUERYRESOURCEINFO queryResourceInfo = {}; queryResourceInfo.hDevice = device; queryResourceInfo.hGlobalShare = osHandle; auto status = getGdi()->queryResourceInfo(&queryResourceInfo); return status == STATUS_SUCCESS; } bool Wddm::openSharedHandle(D3DKMT_HANDLE handle, WddmAllocation *alloc) { D3DKMT_QUERYRESOURCEINFO queryResourceInfo = {}; queryResourceInfo.hDevice = device; queryResourceInfo.hGlobalShare = handle; [[maybe_unused]] auto status = getGdi()->queryResourceInfo(&queryResourceInfo); DEBUG_BREAK_IF(status != STATUS_SUCCESS); if (queryResourceInfo.NumAllocations == 0) { return false; } std::unique_ptr allocPrivateData(new char[queryResourceInfo.TotalPrivateDriverDataSize]); std::unique_ptr resPrivateData(new char[queryResourceInfo.ResourcePrivateDriverDataSize]); std::unique_ptr resPrivateRuntimeData(new char[queryResourceInfo.PrivateRuntimeDataSize]); std::unique_ptr allocationInfo(new D3DDDI_OPENALLOCATIONINFO2[queryResourceInfo.NumAllocations]); D3DKMT_OPENRESOURCE openResource = {}; openResource.hDevice = device; openResource.hGlobalShare = handle; openResource.NumAllocations = queryResourceInfo.NumAllocations; openResource.pOpenAllocationInfo2 = allocationInfo.get(); openResource.pTotalPrivateDriverDataBuffer = allocPrivateData.get(); openResource.TotalPrivateDriverDataBufferSize = queryResourceInfo.TotalPrivateDriverDataSize; openResource.pResourcePrivateDriverData = resPrivateData.get(); openResource.ResourcePrivateDriverDataSize = queryResourceInfo.ResourcePrivateDriverDataSize; openResource.pPrivateRuntimeData = resPrivateRuntimeData.get(); openResource.PrivateRuntimeDataSize = queryResourceInfo.PrivateRuntimeDataSize; status = getGdi()->openResource(&openResource); DEBUG_BREAK_IF(status != STATUS_SUCCESS); alloc->setDefaultHandle(allocationInfo[0].hAllocation); alloc->resourceHandle = openResource.hResource; auto resourceInfo = const_cast(allocationInfo[0].pPrivateDriverData); alloc->setDefaultGmm(new Gmm(rootDeviceEnvironment.getGmmHelper(), static_cast(resourceInfo))); return true; } bool Wddm::verifyNTHandle(HANDLE handle) { D3DKMT_QUERYRESOURCEINFOFROMNTHANDLE queryResourceInfoFromNtHandle = {}; queryResourceInfoFromNtHandle.hDevice = device; queryResourceInfoFromNtHandle.hNtHandle = handle; auto status = getGdi()->queryResourceInfoFromNtHandle(&queryResourceInfoFromNtHandle); return status == STATUS_SUCCESS; } bool Wddm::openNTHandle(HANDLE handle, WddmAllocation *alloc) { D3DKMT_QUERYRESOURCEINFOFROMNTHANDLE queryResourceInfoFromNtHandle = {}; queryResourceInfoFromNtHandle.hDevice = device; queryResourceInfoFromNtHandle.hNtHandle = handle; [[maybe_unused]] auto status = getGdi()->queryResourceInfoFromNtHandle(&queryResourceInfoFromNtHandle); DEBUG_BREAK_IF(status != STATUS_SUCCESS); std::unique_ptr allocPrivateData(new char[queryResourceInfoFromNtHandle.TotalPrivateDriverDataSize]); std::unique_ptr resPrivateData(new char[queryResourceInfoFromNtHandle.ResourcePrivateDriverDataSize]); std::unique_ptr resPrivateRuntimeData(new char[queryResourceInfoFromNtHandle.PrivateRuntimeDataSize]); std::unique_ptr allocationInfo2(new D3DDDI_OPENALLOCATIONINFO2[queryResourceInfoFromNtHandle.NumAllocations]); D3DKMT_OPENRESOURCEFROMNTHANDLE openResourceFromNtHandle = {}; openResourceFromNtHandle.hDevice = device; openResourceFromNtHandle.hNtHandle = handle; openResourceFromNtHandle.NumAllocations = queryResourceInfoFromNtHandle.NumAllocations; openResourceFromNtHandle.pOpenAllocationInfo2 = allocationInfo2.get(); openResourceFromNtHandle.pTotalPrivateDriverDataBuffer = allocPrivateData.get(); openResourceFromNtHandle.TotalPrivateDriverDataBufferSize = queryResourceInfoFromNtHandle.TotalPrivateDriverDataSize; openResourceFromNtHandle.pResourcePrivateDriverData = resPrivateData.get(); openResourceFromNtHandle.ResourcePrivateDriverDataSize = queryResourceInfoFromNtHandle.ResourcePrivateDriverDataSize; openResourceFromNtHandle.pPrivateRuntimeData = resPrivateRuntimeData.get(); openResourceFromNtHandle.PrivateRuntimeDataSize = queryResourceInfoFromNtHandle.PrivateRuntimeDataSize; status = getGdi()->openResourceFromNtHandle(&openResourceFromNtHandle); DEBUG_BREAK_IF(status != STATUS_SUCCESS); auto resourceInfo = const_cast(allocationInfo2[0].pPrivateDriverData); alloc->setDefaultGmm(new Gmm(rootDeviceEnvironment.getGmmHelper(), static_cast(resourceInfo), hwDeviceId->getUmKmDataTranslator()->enabled())); alloc->setDefaultHandle(allocationInfo2[0].hAllocation); alloc->resourceHandle = openResourceFromNtHandle.hResource; return true; } void *Wddm::lockResource(const D3DKMT_HANDLE &handle, bool applyMakeResidentPriorToLock, size_t size) { if (applyMakeResidentPriorToLock) { temporaryResources->makeResidentResource(handle, size); } D3DKMT_LOCK2 lock2 = {}; lock2.hAllocation = handle; lock2.hDevice = this->device; [[maybe_unused]] NTSTATUS status = getGdi()->lock2(&lock2); DEBUG_BREAK_IF(status != STATUS_SUCCESS); kmDafLock(handle); return lock2.pData; } void Wddm::unlockResource(const D3DKMT_HANDLE &handle) { D3DKMT_UNLOCK2 unlock2 = {}; unlock2.hAllocation = handle; unlock2.hDevice = this->device; [[maybe_unused]] NTSTATUS status = getGdi()->unlock2(&unlock2); DEBUG_BREAK_IF(status != STATUS_SUCCESS); kmDafListener->notifyUnlock(featureTable->flags.ftrKmdDaf, getAdapter(), device, &handle, 1, getGdi()->escape); } void Wddm::kmDafLock(D3DKMT_HANDLE handle) { kmDafListener->notifyLock(featureTable->flags.ftrKmdDaf, getAdapter(), device, handle, 0, getGdi()->escape); } bool Wddm::setLowPriorityContextParam(D3DKMT_HANDLE contextHandle) { D3DKMT_SETCONTEXTSCHEDULINGPRIORITY contextPriority = {}; contextPriority.hContext = contextHandle; contextPriority.Priority = 1; if (DebugManager.flags.ForceWddmLowPriorityContextValue.get() != -1) { contextPriority.Priority = static_cast(DebugManager.flags.ForceWddmLowPriorityContextValue.get()); } auto status = getGdi()->setSchedulingPriority(&contextPriority); PRINT_DEBUG_STRING(DebugManager.flags.PrintDebugMessages.get(), stdout, "\nSet scheduling priority for Wddm context. Status: :%lu, context handle: %u, priority: %d \n", status, contextHandle, contextPriority.Priority); return (status == STATUS_SUCCESS); } bool Wddm::createContext(OsContextWin &osContext) { NTSTATUS status = STATUS_UNSUCCESSFUL; D3DKMT_CREATECONTEXTVIRTUAL createContext = {}; CREATECONTEXT_PVTDATA privateData = initPrivateData(osContext); privateData.ProcessID = NEO::getPid(); privateData.pHwContextId = &hwContextId; privateData.NoRingFlushes = DebugManager.flags.UseNoRingFlushesKmdMode.get(); auto &rootDeviceEnvironment = this->getRootDeviceEnvironment(); applyAdditionalContextFlags(privateData, osContext, *rootDeviceEnvironment.getHardwareInfo()); createContext.EngineAffinity = 0; createContext.Flags.NullRendering = static_cast(DebugManager.flags.EnableNullHardware.get()); createContext.Flags.HwQueueSupported = wddmInterface->hwQueuesSupported(); if (osContext.getPreemptionMode() >= PreemptionMode::MidBatch) { createContext.Flags.DisableGpuTimeout = getEnablePreemptionRegValue(); } UmKmDataTempStorage internalRepresentation; if (hwDeviceId->getUmKmDataTranslator()->enabled()) { internalRepresentation.resize(hwDeviceId->getUmKmDataTranslator()->getSizeForCreateContextDataInternalRepresentation()); hwDeviceId->getUmKmDataTranslator()->translateCreateContextDataToInternalRepresentation(internalRepresentation.data(), internalRepresentation.size(), privateData); createContext.pPrivateDriverData = internalRepresentation.data(); createContext.PrivateDriverDataSize = static_cast(internalRepresentation.size()); } else { createContext.PrivateDriverDataSize = sizeof(privateData); createContext.pPrivateDriverData = &privateData; } createContext.NodeOrdinal = WddmEngineMapper::engineNodeMap(osContext.getEngineType()); if (ApiSpecificConfig::getApiType() == ApiSpecificConfig::L0) { createContext.ClientHint = D3DKMT_CLIENTHINT_ONEAPI_LEVEL0; } else { createContext.ClientHint = D3DKMT_CLIENTHINT_OPENCL; } createContext.hDevice = device; status = getGdi()->createContext(&createContext); osContext.setWddmContextHandle(createContext.hContext); PRINT_DEBUG_STRING(DebugManager.flags.PrintDebugMessages.get(), stdout, "\nCreated Wddm context. Status: :%lu, engine: %u, contextId: %u, deviceBitfield: %lu \n", status, osContext.getEngineType(), osContext.getContextId(), osContext.getDeviceBitfield().to_ulong()); if (status != STATUS_SUCCESS) { return false; } if (osContext.isLowPriority()) { return setLowPriorityContextParam(osContext.getWddmContextHandle()); } return true; } bool Wddm::destroyContext(D3DKMT_HANDLE context) { D3DKMT_DESTROYCONTEXT destroyContext = {}; NTSTATUS status = STATUS_UNSUCCESSFUL; if (context != static_cast(0)) { destroyContext.hContext = context; status = getGdi()->destroyContext(&destroyContext); } return status == STATUS_SUCCESS; } bool Wddm::submit(uint64_t commandBuffer, size_t size, void *commandHeader, WddmSubmitArguments &submitArguments) { bool status = false; if (currentPagingFenceValue > *pagingFenceAddress && !waitOnGPU(submitArguments.contextHandle)) { return false; } DBG_LOG(ResidencyDebugEnable, "Residency:", __FUNCTION__, "currentFenceValue =", submitArguments.monitorFence->currentFenceValue); if (DebugManager.flags.PrintDeviceAndEngineIdOnSubmission.get()) { printf("%u: Wddm Submission with context handle %u and HwQueue handle %u\n", SysCalls::getProcessId(), submitArguments.contextHandle, submitArguments.hwQueueHandle); } status = wddmInterface->submit(commandBuffer, size, commandHeader, submitArguments); if (status) { submitArguments.monitorFence->lastSubmittedFence = submitArguments.monitorFence->currentFenceValue; submitArguments.monitorFence->currentFenceValue++; } getDeviceState(); return status; } void Wddm::getDeviceState() { #ifdef _DEBUG D3DKMT_GETDEVICESTATE GetDevState = {}; NTSTATUS status = STATUS_SUCCESS; GetDevState.hDevice = device; GetDevState.StateType = D3DKMT_DEVICESTATE_EXECUTION; status = getGdi()->getDeviceState(&GetDevState); DEBUG_BREAK_IF(status != STATUS_SUCCESS); if (status == STATUS_SUCCESS) { DEBUG_BREAK_IF(GetDevState.ExecutionState != D3DKMT_DEVICEEXECUTION_ACTIVE); } #endif } unsigned int Wddm::getEnablePreemptionRegValue() { return enablePreemptionRegValue; } bool Wddm::waitOnGPU(D3DKMT_HANDLE context) { D3DKMT_WAITFORSYNCHRONIZATIONOBJECTFROMGPU waitOnGpu = {}; waitOnGpu.hContext = context; waitOnGpu.ObjectCount = 1; waitOnGpu.ObjectHandleArray = &pagingQueueSyncObject; uint64_t localPagingFenceValue = currentPagingFenceValue; waitOnGpu.MonitoredFenceValueArray = &localPagingFenceValue; NTSTATUS status = getGdi()->waitForSynchronizationObjectFromGpu(&waitOnGpu); return status == STATUS_SUCCESS; } bool Wddm::waitFromCpu(uint64_t lastFenceValue, const MonitoredFence &monitoredFence) { NTSTATUS status = STATUS_SUCCESS; if (!skipResourceCleanup() && lastFenceValue > *monitoredFence.cpuAddress) { D3DKMT_WAITFORSYNCHRONIZATIONOBJECTFROMCPU waitFromCpu = {}; waitFromCpu.ObjectCount = 1; waitFromCpu.ObjectHandleArray = &monitoredFence.fenceHandle; waitFromCpu.FenceValueArray = &lastFenceValue; waitFromCpu.hDevice = device; waitFromCpu.hAsyncEvent = NULL_HANDLE; status = getGdi()->waitForSynchronizationObjectFromCpu(&waitFromCpu); DEBUG_BREAK_IF(status != STATUS_SUCCESS); } return status == STATUS_SUCCESS; } bool Wddm::isGpuHangDetected(OsContext &osContext) { const auto osContextWin = static_cast(&osContext); const auto &monitoredFence = osContextWin->getResidencyController().getMonitoredFence(); bool hangDetected = monitoredFence.cpuAddress && *monitoredFence.cpuAddress == gpuHangIndication; PRINT_DEBUG_STRING(hangDetected && DebugManager.flags.PrintDebugMessages.get(), stderr, "%s", "ERROR: GPU HANG detected!\n"); return hangDetected; } void Wddm::initGfxPartition(GfxPartition &outGfxPartition, uint32_t rootDeviceIndex, size_t numRootDevices, bool useExternalFrontWindowPool) const { if (gfxPartition.SVM.Limit != 0) { outGfxPartition.heapInit(HeapIndex::HEAP_SVM, gfxPartition.SVM.Base, gfxPartition.SVM.Limit - gfxPartition.SVM.Base + 1); } else if (is32bit) { outGfxPartition.heapInit(HeapIndex::HEAP_SVM, 0x0ull, 4 * MemoryConstants::gigaByte); } outGfxPartition.heapInit(HeapIndex::HEAP_STANDARD, gfxPartition.Standard.Base, gfxPartition.Standard.Limit - gfxPartition.Standard.Base + 1); // Split HEAP_STANDARD64K among root devices auto gfxStandard64KBSize = alignDown((gfxPartition.Standard64KB.Limit - gfxPartition.Standard64KB.Base + 1) / numRootDevices, GfxPartition::heapGranularity); outGfxPartition.heapInit(HeapIndex::HEAP_STANDARD64KB, gfxPartition.Standard64KB.Base + rootDeviceIndex * gfxStandard64KBSize, gfxStandard64KBSize); for (auto heap : GfxPartition::heap32Names) { if (useExternalFrontWindowPool && HeapAssigner::heapTypeExternalWithFrontWindowPool(heap)) { outGfxPartition.heapInitExternalWithFrontWindow(heap, gfxPartition.Heap32[static_cast(heap)].Base, gfxPartition.Heap32[static_cast(heap)].Limit - gfxPartition.Heap32[static_cast(heap)].Base + 1); size_t externalFrontWindowSize = GfxPartition::externalFrontWindowPoolSize; outGfxPartition.heapInitExternalWithFrontWindow(HeapAssigner::mapExternalWindowIndex(heap), outGfxPartition.heapAllocate(heap, externalFrontWindowSize), externalFrontWindowSize); } else if (HeapAssigner::isInternalHeap(heap)) { auto baseAddress = gfxPartition.Heap32[static_cast(heap)].Base >= minAddress ? gfxPartition.Heap32[static_cast(heap)].Base : minAddress; outGfxPartition.heapInitWithFrontWindow(heap, baseAddress, gfxPartition.Heap32[static_cast(heap)].Limit - baseAddress + 1, GfxPartition::internalFrontWindowPoolSize); outGfxPartition.heapInitFrontWindow(HeapAssigner::mapInternalWindowIndex(heap), baseAddress, GfxPartition::internalFrontWindowPoolSize); } else { outGfxPartition.heapInit(heap, gfxPartition.Heap32[static_cast(heap)].Base, gfxPartition.Heap32[static_cast(heap)].Limit - gfxPartition.Heap32[static_cast(heap)].Base + 1); } } } uint64_t Wddm::getSystemSharedMemory() const { return systemSharedMemory; } uint64_t Wddm::getDedicatedVideoMemory() const { return dedicatedVideoMemory; } uint64_t Wddm::getMaxApplicationAddress() const { return maximumApplicationAddress; } NTSTATUS Wddm::escape(D3DKMT_ESCAPE &escapeCommand) { escapeCommand.hAdapter = getAdapter(); return getGdi()->escape(&escapeCommand); }; PFND3DKMT_ESCAPE Wddm::getEscapeHandle() const { return getGdi()->escape; } bool Wddm::verifyAdapterLuid(LUID adapterLuid) const { return adapterLuid.HighPart == hwDeviceId->getAdapterLuid().HighPart && adapterLuid.LowPart == hwDeviceId->getAdapterLuid().LowPart; } LUID Wddm::getAdapterLuid() const { return hwDeviceId->getAdapterLuid(); } bool Wddm::isShutdownInProgress() { return NEO::isShutdownInProgress(); } void Wddm::releaseReservedAddress(void *reservedAddress) { if (reservedAddress) { this->virtualFree(reservedAddress, 0); } } bool Wddm::reserveValidAddressRange(size_t size, void *&reservedMem) { reservedMem = this->virtualAlloc(nullptr, size, false); if (reservedMem == nullptr) { return false; } else if (minAddress > reinterpret_cast(reservedMem)) { StackVec invalidAddrVector; invalidAddrVector.push_back(reservedMem); do { reservedMem = this->virtualAlloc(nullptr, size, true); if (minAddress > reinterpret_cast(reservedMem) && reservedMem != nullptr) { invalidAddrVector.push_back(reservedMem); } else { break; } } while (1); for (auto &it : invalidAddrVector) { this->virtualFree(it, 0); } if (reservedMem == nullptr) { return false; } } return true; } void *Wddm::virtualAlloc(void *inPtr, size_t size, bool topDownHint) { return osMemory->osReserveCpuAddressRange(inPtr, size, topDownHint); } void Wddm::virtualFree(void *ptr, size_t size) { osMemory->osReleaseCpuAddressRange(ptr, size); } void Wddm::waitOnPagingFenceFromCpu() { perfLogStartWaitTime(residencyLogger.get(), currentPagingFenceValue); while (currentPagingFenceValue > *getPagingFenceAddress()) perfLogResidencyEnteredWait(residencyLogger.get()); perfLogResidencyWaitPagingeFenceLog(residencyLogger.get(), *getPagingFenceAddress()); } void Wddm::updatePagingFenceValue(uint64_t newPagingFenceValue) { NEO::MultiThreadHelpers::interlockedMax(currentPagingFenceValue, newPagingFenceValue); } WddmVersion Wddm::getWddmVersion() { if (featureTable->flags.ftrWddmHwQueues) { return WddmVersion::WDDM_2_3; } else { return WddmVersion::WDDM_2_0; } } uint32_t Wddm::getRequestedEUCount() const { DEBUG_BREAK_IF(!gtSystemInfo); // Always request even number od EUs return (gtSystemInfo->EUCount / gtSystemInfo->SubSliceCount) & (~1u); }; void Wddm::createPagingFenceLogger() { if (DebugManager.flags.WddmResidencyLogger.get()) { residencyLogger = std::make_unique(device, pagingFenceAddress); } } PhysicalDevicePciBusInfo Wddm::getPciBusInfo() const { if (adapterBDF.Data == std::numeric_limits::max()) { return PhysicalDevicePciBusInfo(PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue); } return PhysicalDevicePciBusInfo(0, adapterBDF.Bus, adapterBDF.Device, adapterBDF.Function); } PhysicalDevicePciSpeedInfo Wddm::getPciSpeedInfo() const { PhysicalDevicePciSpeedInfo speedInfo{}; return speedInfo; } } // namespace NEO