/* * Copyright (C) 2018-2023 Intel Corporation * * SPDX-License-Identifier: MIT * */ #include "shared/source/built_ins/built_ins.h" #include "shared/source/debug_settings/debug_settings_manager.h" #include "shared/source/gmm_helper/gmm.h" #include "shared/source/gmm_helper/gmm_helper.h" #include "shared/source/helpers/compiler_product_helper.h" #include "shared/source/helpers/file_io.h" #include "shared/source/helpers/hash.h" #include "shared/source/helpers/path.h" #include "shared/source/helpers/string.h" #include "shared/test/common/helpers/debug_manager_state_restore.h" #include "shared/test/common/helpers/gtest_helpers.h" #include "shared/test/common/helpers/test_files.h" #include "shared/test/common/libult/global_environment.h" #include "shared/test/common/mocks/mock_builtins.h" #include "shared/test/common/mocks/mock_builtinslib.h" #include "shared/test/common/mocks/mock_compiler_interface.h" #include "shared/test/common/mocks/mock_compilers.h" #include "shared/test/common/mocks/mock_memory_manager.h" #include "shared/test/common/mocks/ult_device_factory.h" #include "shared/test/common/test_macros/test.h" #include "shared/test/common/utilities/base_object_utils.h" #include "opencl/source/accelerators/intel_motion_estimation.h" #include "opencl/source/built_ins/aux_translation_builtin.h" #include "opencl/source/built_ins/builtins_dispatch_builder.h" #include "opencl/source/built_ins/vme_builtin.h" #include "opencl/source/built_ins/vme_dispatch_builder.h" #include "opencl/source/helpers/dispatch_info_builder.h" #include "opencl/source/kernel/kernel.h" #include "opencl/test/unit_test/built_ins/built_ins_file_names.h" #include "opencl/test/unit_test/fixtures/built_in_fixture.h" #include "opencl/test/unit_test/fixtures/cl_device_fixture.h" #include "opencl/test/unit_test/fixtures/context_fixture.h" #include "opencl/test/unit_test/fixtures/image_fixture.h" #include "opencl/test/unit_test/fixtures/run_kernel_fixture.h" #include "opencl/test/unit_test/mocks/mock_buffer.h" #include "opencl/test/unit_test/mocks/mock_cl_device.h" #include "opencl/test/unit_test/mocks/mock_cl_execution_environment.h" #include "opencl/test/unit_test/mocks/mock_command_queue.h" #include "opencl/test/unit_test/mocks/mock_kernel.h" #include "opencl/test/unit_test/test_macros/test_checks_ocl.h" #include "gtest/gtest.h" #include "os_inc.h" #include "test_traits_common.h" #include using namespace NEO; class BuiltInTests : public BuiltInFixture, public ClDeviceFixture, public ContextFixture, public ::testing::Test { using BuiltInFixture::setUp; using ContextFixture::setUp; public: BuiltInTests() { // reserving space here to avoid the appearance of a memory management // leak being reported allBuiltIns.reserve(5000); } void SetUp() override { DebugManager.flags.ForceAuxTranslationMode.set(static_cast(AuxTranslationMode::Builtin)); ClDeviceFixture::setUp(); cl_device_id device = pClDevice; ContextFixture::setUp(1, &device); BuiltInFixture::setUp(pDevice); } void TearDown() override { allBuiltIns.clear(); BuiltInFixture::tearDown(); ContextFixture::tearDown(); ClDeviceFixture::tearDown(); } void appendBuiltInStringFromFile(std::string builtInFile, size_t &size) { std::string src; auto pData = loadDataFromFile( builtInFile.c_str(), size); ASSERT_NE(nullptr, pData); src = (const char *)pData.get(); size_t start = src.find("R\"===("); size_t stop = src.find(")===\""); // assert that pattern was found ASSERT_NE(std::string::npos, start); ASSERT_NE(std::string::npos, stop); start += strlen("R\"===("); size = stop - start; allBuiltIns.append(src, start, size); } bool compareBuiltinOpParams(const BuiltinOpParams &left, const BuiltinOpParams &right) { return left.srcPtr == right.srcPtr && left.dstPtr == right.dstPtr && left.size == right.size && left.srcOffset == right.srcOffset && left.dstOffset == right.dstOffset && left.dstMemObj == right.dstMemObj && left.srcMemObj == right.srcMemObj; } DebugManagerStateRestore restore; std::string allBuiltIns; }; struct VmeBuiltInTests : BuiltInTests { void SetUp() override { BuiltInTests::SetUp(); if (!pDevice->getHardwareInfo().capabilityTable.supportsVme) { GTEST_SKIP(); } } }; struct AuxBuiltInTests : BuiltInTests, public ::testing::WithParamInterface { void SetUp() override { BuiltInTests::SetUp(); kernelObjType = GetParam(); } KernelObjForAuxTranslation::Type kernelObjType; }; struct AuxBuiltinsMatcher { template static constexpr bool isMatched() { return TestTraits::get()>::auxBuiltinsSupported; } }; HWTEST2_F(BuiltInTests, GivenBuiltinTypeBinaryWhenGettingAuxTranslationBuiltinThenResourceSizeIsNonZero, MatchAny) { auto mockBuiltinsLib = std::unique_ptr(new MockBuiltinsLib()); EXPECT_EQ(TestTraits::get()>::auxBuiltinsSupported, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::AuxTranslation, BuiltinCode::ECodeType::Binary, *pDevice).size() != 0); } class MockAuxBuilInOp : public BuiltInOp { public: using BuiltinDispatchInfoBuilder::populate; using BaseClass = BuiltInOp; using BaseClass::baseKernel; using BaseClass::convertToAuxKernel; using BaseClass::convertToNonAuxKernel; using BaseClass::resizeKernelInstances; using BaseClass::usedKernels; using BaseClass::BuiltInOp; }; INSTANTIATE_TEST_CASE_P(, AuxBuiltInTests, testing::ValuesIn({KernelObjForAuxTranslation::Type::MEM_OBJ, KernelObjForAuxTranslation::Type::GFX_ALLOC})); HWCMDTEST_P(IGFX_XE_HP_CORE, AuxBuiltInTests, givenXeHpCoreCommandsAndAuxTranslationKernelWhenSettingKernelArgsThenSetValidMocs) { const auto &compilerProductHelper = pDevice->getRootDeviceEnvironment().getHelper(); if (compilerProductHelper.isForceToStatelessRequired()) { GTEST_SKIP(); } using RENDER_SURFACE_STATE = typename FamilyType::RENDER_SURFACE_STATE; MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); BuiltinOpParams builtinOpParamsToAux; builtinOpParamsToAux.auxTranslationDirection = AuxTranslationDirection::NonAuxToAux; BuiltinOpParams builtinOpParamsToNonAux; builtinOpParamsToNonAux.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; std::unique_ptr buffer = nullptr; std::unique_ptr gfxAllocation = nullptr; auto kernelObjsForAuxTranslation = std::make_unique(); if (kernelObjType == MockKernelObjForAuxTranslation::Type::MEM_OBJ) { cl_int retVal = CL_SUCCESS; buffer.reset(Buffer::create(pContext, 0, MemoryConstants::pageSize, nullptr, retVal)); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::MEM_OBJ, buffer.get()}); } else { gfxAllocation.reset(new MockGraphicsAllocation(nullptr, MemoryConstants::pageSize)); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::GFX_ALLOC, gfxAllocation.get()}); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParamsToAux); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParamsToNonAux); { // read args auto argNum = 0; auto expectedMocs = pDevice->getGmmHelper()->getMOCS(GMM_RESOURCE_USAGE_OCL_BUFFER_CACHELINE_MISALIGNED); auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); } { // write args auto argNum = 1; auto expectedMocs = pDevice->getGmmHelper()->getMOCS(GMM_RESOURCE_USAGE_OCL_BUFFER_CONST); auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); } } TEST_F(BuiltInTests, WhenBuildingListOfBuiltinsThenBuiltinsHaveBeenGenerated) { for (auto supportsImages : ::testing::Bool()) { allBuiltIns.clear(); size_t size = 0; for (auto &fileName : getBuiltInFileNames(supportsImages)) { appendBuiltInStringFromFile(sharedBuiltinsDir + "/" + fileName, size); ASSERT_NE(0u, size); } // convert /r/n to /n size_t startPos = 0; while ((startPos = allBuiltIns.find("\r\n", startPos)) != std::string::npos) { allBuiltIns.replace(startPos, 2, "\n"); } // convert /r to /n startPos = 0; while ((startPos = allBuiltIns.find("\r", startPos)) != std::string::npos) { allBuiltIns.replace(startPos, 1, "\n"); } uint64_t hash = Hash::hash(allBuiltIns.c_str(), allBuiltIns.length()); auto hashName = getBuiltInHashFileName(hash, supportsImages); // First fail, if we are inconsistent EXPECT_EQ(true, fileExists(hashName)) << "**********\nBuilt in kernels need to be regenerated for the mock compilers!\n**********"; // then write to file if needed #define GENERATE_NEW_HASH_FOR_BUILT_INS 0 #if GENERATE_NEW_HASH_FOR_BUILT_INS std::cout << "writing builtins to file: " << hashName << std::endl; const char *pData = allBuiltIns.c_str(); writeDataToFile(hashName.c_str(), pData, allBuiltIns.length()); #endif } } TEST_F(BuiltInTests, GivenCopyBufferToSystemMemoryBufferWhenDispatchInfoIsCreatedThenParamsAreCorrect) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); MockBuffer *srcPtr = new MockBuffer(); MockBuffer *dstPtr = new MockBuffer(); MockBuffer &src = *srcPtr; MockBuffer &dst = *dstPtr; srcPtr->mockGfxAllocation.setAllocationType(AllocationType::BUFFER); dstPtr->mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &src; builtinOpsParams.dstMemObj = &dst; builtinOpsParams.srcPtr = src.getCpuAddress(); builtinOpsParams.dstPtr = dst.getCpuAddress(); builtinOpsParams.size = {dst.getSize(), 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); size_t leftSize = reinterpret_cast(dst.getCpuAddress()) % MemoryConstants::cacheLineSize; if (leftSize > 0) { leftSize = MemoryConstants::cacheLineSize - leftSize; } size_t rightSize = (reinterpret_cast(dst.getCpuAddress()) + dst.getSize()) % MemoryConstants::cacheLineSize; size_t middleSize = (dst.getSize() - leftSize - rightSize) / (sizeof(uint32_t) * 4); int i = 0; int leftKernel = 0; int middleKernel = 0; int rightKernel = 0; if (leftSize > 0) { middleKernel++; rightKernel++; } else { leftKernel = -1; } if (middleSize > 0) { rightKernel++; } else { middleKernel = -1; } if (rightSize == 0) { rightKernel = -1; } for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_EQ(1u, dispatchInfo.getDim()); if (i == leftKernel) { EXPECT_EQ(Vec3(leftSize, 1, 1), dispatchInfo.getGWS()); } else if (i == middleKernel) { EXPECT_EQ(Vec3(middleSize, 1, 1), dispatchInfo.getGWS()); } else if (i == rightKernel) { EXPECT_EQ(Vec3(rightSize, 1, 1), dispatchInfo.getGWS()); } i++; EXPECT_TRUE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); delete srcPtr; delete dstPtr; } TEST_F(BuiltInTests, GivenCopyBufferToLocalMemoryBufferWhenDispatchInfoIsCreatedThenParamsAreCorrect) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); MockBuffer *srcPtr = new MockBuffer(); MockBuffer *dstPtr = new MockBuffer(); MockBuffer &src = *srcPtr; MockBuffer &dst = *dstPtr; srcPtr->mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); dstPtr->mockGfxAllocation.setAllocationType(AllocationType::BUFFER); BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &src; builtinOpsParams.dstMemObj = &dst; builtinOpsParams.srcPtr = src.getCpuAddress(); builtinOpsParams.dstPtr = dst.getCpuAddress(); builtinOpsParams.size = {dst.getSize(), 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_FALSE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } delete srcPtr; delete dstPtr; } HWTEST2_P(AuxBuiltInTests, givenInputBufferWhenBuildingNonAuxDispatchInfoForAuxTranslationThenPickAndSetupCorrectKernels, AuxBuiltinsMatcher) { BuiltinDispatchInfoBuilder &baseBuilder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::AuxTranslation, *pClDevice); auto &builder = static_cast &>(baseBuilder); std::vector builtinKernels; std::vector mockKernelObjForAuxTranslation; mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x1000)); mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x20000)); mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x30000)); BuiltinOpParams builtinOpsParams; builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; auto kernelObjsForAuxTranslation = std::make_unique(); for (auto &kernelObj : mockKernelObjForAuxTranslation) { kernelObjsForAuxTranslation->insert(kernelObj); } auto kernelObjsForAuxTranslationPtr = kernelObjsForAuxTranslation.get(); MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); EXPECT_TRUE(builder.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams)); EXPECT_EQ(3u, multiDispatchInfo.size()); for (auto &dispatchInfo : multiDispatchInfo) { auto kernel = dispatchInfo.getKernel(); builtinKernels.push_back(kernel); if (kernelObjType == KernelObjForAuxTranslation::Type::MEM_OBJ) { auto buffer = castToObject(kernel->getKernelArguments().at(0).object); auto kernelObj = *kernelObjsForAuxTranslationPtr->find({KernelObjForAuxTranslation::Type::MEM_OBJ, buffer}); EXPECT_NE(nullptr, kernelObj.object); EXPECT_EQ(KernelObjForAuxTranslation::Type::MEM_OBJ, kernelObj.type); kernelObjsForAuxTranslationPtr->erase(kernelObj); cl_mem clMem = buffer; EXPECT_EQ(clMem, kernel->getKernelArguments().at(0).object); EXPECT_EQ(clMem, kernel->getKernelArguments().at(1).object); EXPECT_EQ(1u, dispatchInfo.getDim()); size_t xGws = alignUp(buffer->getSize(), 512) / 16; Vec3 gws = {xGws, 1, 1}; EXPECT_EQ(gws, dispatchInfo.getGWS()); } else { auto gfxAllocation = static_cast(kernel->getKernelArguments().at(0).object); auto kernelObj = *kernelObjsForAuxTranslationPtr->find({KernelObjForAuxTranslation::Type::GFX_ALLOC, gfxAllocation}); EXPECT_NE(nullptr, kernelObj.object); EXPECT_EQ(KernelObjForAuxTranslation::Type::GFX_ALLOC, kernelObj.type); kernelObjsForAuxTranslationPtr->erase(kernelObj); EXPECT_EQ(gfxAllocation, kernel->getKernelArguments().at(0).object); EXPECT_EQ(gfxAllocation, kernel->getKernelArguments().at(1).object); EXPECT_EQ(1u, dispatchInfo.getDim()); size_t xGws = alignUp(gfxAllocation->getUnderlyingBufferSize(), 512) / 16; Vec3 gws = {xGws, 1, 1}; EXPECT_EQ(gws, dispatchInfo.getGWS()); } } EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); // always pick different kernel EXPECT_EQ(3u, builtinKernels.size()); EXPECT_NE(builtinKernels[0], builtinKernels[1]); EXPECT_NE(builtinKernels[0], builtinKernels[2]); EXPECT_NE(builtinKernels[1], builtinKernels[2]); } HWTEST2_P(AuxBuiltInTests, givenInputBufferWhenBuildingAuxDispatchInfoForAuxTranslationThenPickAndSetupCorrectKernels, AuxBuiltinsMatcher) { BuiltinDispatchInfoBuilder &baseBuilder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::AuxTranslation, *pClDevice); auto &builder = static_cast &>(baseBuilder); std::vector builtinKernels; std::vector mockKernelObjForAuxTranslation; mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x1000)); mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x20000)); mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType, 0x30000)); BuiltinOpParams builtinOpsParams; builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::NonAuxToAux; auto kernelObjsForAuxTranslation = std::make_unique(); auto kernelObjsForAuxTranslationPtr = kernelObjsForAuxTranslation.get(); for (auto &kernelObj : mockKernelObjForAuxTranslation) { kernelObjsForAuxTranslation->insert(kernelObj); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); EXPECT_TRUE(builder.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams)); EXPECT_EQ(3u, multiDispatchInfo.size()); for (auto &dispatchInfo : multiDispatchInfo) { auto kernel = dispatchInfo.getKernel(); builtinKernels.push_back(kernel); if (kernelObjType == KernelObjForAuxTranslation::Type::MEM_OBJ) { auto buffer = castToObject(kernel->getKernelArguments().at(0).object); auto kernelObj = *kernelObjsForAuxTranslationPtr->find({KernelObjForAuxTranslation::Type::MEM_OBJ, buffer}); EXPECT_NE(nullptr, kernelObj.object); EXPECT_EQ(KernelObjForAuxTranslation::Type::MEM_OBJ, kernelObj.type); kernelObjsForAuxTranslationPtr->erase(kernelObj); cl_mem clMem = buffer; EXPECT_EQ(clMem, kernel->getKernelArguments().at(0).object); EXPECT_EQ(clMem, kernel->getKernelArguments().at(1).object); EXPECT_EQ(1u, dispatchInfo.getDim()); size_t xGws = alignUp(buffer->getSize(), 4) / 4; Vec3 gws = {xGws, 1, 1}; EXPECT_EQ(gws, dispatchInfo.getGWS()); } else { auto gfxAllocation = static_cast(kernel->getKernelArguments().at(0).object); auto kernelObj = *kernelObjsForAuxTranslationPtr->find({KernelObjForAuxTranslation::Type::GFX_ALLOC, gfxAllocation}); EXPECT_NE(nullptr, kernelObj.object); EXPECT_EQ(KernelObjForAuxTranslation::Type::GFX_ALLOC, kernelObj.type); kernelObjsForAuxTranslationPtr->erase(kernelObj); EXPECT_EQ(gfxAllocation, kernel->getKernelArguments().at(0).object); EXPECT_EQ(gfxAllocation, kernel->getKernelArguments().at(1).object); EXPECT_EQ(1u, dispatchInfo.getDim()); size_t xGws = alignUp(gfxAllocation->getUnderlyingBufferSize(), 512) / 16; Vec3 gws = {xGws, 1, 1}; EXPECT_EQ(gws, dispatchInfo.getGWS()); } } EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); // always pick different kernel EXPECT_EQ(3u, builtinKernels.size()); EXPECT_NE(builtinKernels[0], builtinKernels[1]); EXPECT_NE(builtinKernels[0], builtinKernels[2]); EXPECT_NE(builtinKernels[1], builtinKernels[2]); } HWTEST2_P(AuxBuiltInTests, givenInputBufferWhenBuildingAuxTranslationDispatchThenPickDifferentKernelsDependingOnRequest, AuxBuiltinsMatcher) { BuiltinDispatchInfoBuilder &baseBuilder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::AuxTranslation, *pClDevice); auto &builder = static_cast &>(baseBuilder); std::vector mockKernelObjForAuxTranslation; for (int i = 0; i < 3; i++) { mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType)); } std::vector builtinKernels; BuiltinOpParams builtinOpsParams; auto kernelObjsForAuxTranslation = std::make_unique(); for (auto &kernelObj : mockKernelObjForAuxTranslation) { kernelObjsForAuxTranslation->insert(kernelObj); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; EXPECT_TRUE(builder.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams)); builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::NonAuxToAux; EXPECT_TRUE(builder.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams)); EXPECT_EQ(6u, multiDispatchInfo.size()); for (auto &dispatchInfo : multiDispatchInfo) { builtinKernels.push_back(dispatchInfo.getKernel()); } EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); // nonAux vs Aux instance EXPECT_EQ(6u, builtinKernels.size()); EXPECT_NE(builtinKernels[0], builtinKernels[3]); EXPECT_NE(builtinKernels[1], builtinKernels[4]); EXPECT_NE(builtinKernels[2], builtinKernels[5]); } HWTEST2_P(AuxBuiltInTests, givenInvalidAuxTranslationDirectionWhenBuildingDispatchInfosThenAbort, AuxBuiltinsMatcher) { BuiltinDispatchInfoBuilder &baseBuilder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::AuxTranslation, *pClDevice); auto &builder = static_cast &>(baseBuilder); auto kernelObjsForAuxTranslation = std::make_unique(); auto kernelObjsForAuxTranslationPtr = kernelObjsForAuxTranslation.get(); MockKernelObjForAuxTranslation mockKernelObjForAuxTranslation(kernelObjType); MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); BuiltinOpParams builtinOpsParams; kernelObjsForAuxTranslationPtr->insert(mockKernelObjForAuxTranslation); builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::None; EXPECT_THROW(builder.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams), std::exception); } TEST_F(BuiltInTests, whenAuxBuiltInIsConstructedThenResizeKernelInstancedTo5) { MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); EXPECT_EQ(5u, mockAuxBuiltInOp.convertToAuxKernel.size()); EXPECT_EQ(5u, mockAuxBuiltInOp.convertToNonAuxKernel.size()); } HWTEST2_P(AuxBuiltInTests, givenMoreKernelObjectsForAuxTranslationThanKernelInstancesWhenDispatchingThenResize, AuxBuiltinsMatcher) { MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); EXPECT_EQ(5u, mockAuxBuiltInOp.convertToAuxKernel.size()); EXPECT_EQ(5u, mockAuxBuiltInOp.convertToNonAuxKernel.size()); std::vector mockKernelObjForAuxTranslation; for (int i = 0; i < 7; i++) { mockKernelObjForAuxTranslation.push_back(MockKernelObjForAuxTranslation(kernelObjType)); } BuiltinOpParams builtinOpsParams; builtinOpsParams.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; auto kernelObjsForAuxTranslation = std::make_unique(); for (auto &kernelObj : mockKernelObjForAuxTranslation) { kernelObjsForAuxTranslation->insert(kernelObj); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); EXPECT_TRUE(mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpsParams)); EXPECT_EQ(7u, mockAuxBuiltInOp.convertToAuxKernel.size()); EXPECT_EQ(7u, mockAuxBuiltInOp.convertToNonAuxKernel.size()); } TEST_F(BuiltInTests, givenkAuxBuiltInWhenResizeIsCalledThenCloneAllNewInstancesFromBaseKernel) { MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); size_t newSize = mockAuxBuiltInOp.convertToAuxKernel.size() + 3; mockAuxBuiltInOp.resizeKernelInstances(newSize); EXPECT_EQ(newSize, mockAuxBuiltInOp.convertToAuxKernel.size()); for (auto &convertToAuxKernel : mockAuxBuiltInOp.convertToAuxKernel) { EXPECT_EQ(&mockAuxBuiltInOp.baseKernel->getKernelInfo(), &convertToAuxKernel->getKernelInfo()); } EXPECT_EQ(newSize, mockAuxBuiltInOp.convertToNonAuxKernel.size()); for (auto &convertToNonAuxKernel : mockAuxBuiltInOp.convertToNonAuxKernel) { EXPECT_EQ(&mockAuxBuiltInOp.baseKernel->getKernelInfo(), &convertToNonAuxKernel->getKernelInfo()); } } HWTEST2_P(AuxBuiltInTests, givenKernelWithAuxTranslationRequiredWhenEnqueueCalledThenLockOnBuiltin, AuxBuiltinsMatcher) { BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::AuxTranslation, *pClDevice); auto mockAuxBuiltInOp = new MockAuxBuilInOp(*pBuiltIns, *pClDevice); pClExecutionEnvironment->setBuiltinDispatchInfoBuilder(rootDeviceIndex, EBuiltInOps::AuxTranslation, std::unique_ptr(mockAuxBuiltInOp)); auto mockProgram = clUniquePtr(new MockProgram(toClDeviceVector(*pClDevice))); auto mockBuiltinKernel = MockKernel::create(*pDevice, mockProgram.get()); auto kernelInfos = MockKernel::toKernelInfoContainer(mockBuiltinKernel->getKernelInfo(), rootDeviceIndex); auto pMultiDeviceKernel = new MockMultiDeviceKernel(MockMultiDeviceKernel::toKernelVector(mockBuiltinKernel), kernelInfos); mockAuxBuiltInOp->usedKernels.at(0).reset(pMultiDeviceKernel); MockKernelWithInternals mockKernel(*pClDevice, pContext); MockCommandQueueHw cmdQ(pContext, pClDevice, nullptr); size_t gws[3] = {1, 0, 0}; mockKernel.kernelInfo.addArgBuffer(0, 0, sizeof(void *)); mockKernel.mockKernel->initialize(); std::unique_ptr gmm; MockKernelObjForAuxTranslation mockKernelObjForAuxTranslation(kernelObjType); if (kernelObjType == KernelObjForAuxTranslation::Type::MEM_OBJ) { MockBuffer::setAllocationType(mockKernelObjForAuxTranslation.mockBuffer->getGraphicsAllocation(0), pDevice->getRootDeviceEnvironment().getGmmHelper(), true); cl_mem clMem = mockKernelObjForAuxTranslation.mockBuffer.get(); mockKernel.mockKernel->setArgBuffer(0, sizeof(cl_mem *), &clMem); } else { auto gfxAllocation = mockKernelObjForAuxTranslation.mockGraphicsAllocation.get(); MockBuffer::setAllocationType(gfxAllocation, pDevice->getRootDeviceEnvironment().getGmmHelper(), true); auto ptr = reinterpret_cast(gfxAllocation->getGpuAddressToPatch()); mockKernel.mockKernel->setArgSvmAlloc(0, ptr, gfxAllocation, 0u); gmm.reset(gfxAllocation->getDefaultGmm()); } mockKernel.mockKernel->auxTranslationRequired = false; cmdQ.enqueueKernel(mockKernel.mockKernel, 1, nullptr, gws, nullptr, 0, nullptr, nullptr); EXPECT_EQ(0u, pMultiDeviceKernel->takeOwnershipCalls); EXPECT_EQ(0u, pMultiDeviceKernel->releaseOwnershipCalls); mockKernel.mockKernel->auxTranslationRequired = true; cmdQ.enqueueKernel(mockKernel.mockKernel, 1, nullptr, gws, nullptr, 0, nullptr, nullptr); EXPECT_EQ(1u, pMultiDeviceKernel->takeOwnershipCalls); EXPECT_EQ(1u, pMultiDeviceKernel->releaseOwnershipCalls); } HWCMDTEST_P(IGFX_GEN8_CORE, AuxBuiltInTests, givenAuxTranslationKernelWhenSettingKernelArgsThenSetValidMocs) { if (this->pDevice->areSharedSystemAllocationsAllowed()) { GTEST_SKIP(); } using RENDER_SURFACE_STATE = typename FamilyType::RENDER_SURFACE_STATE; MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); BuiltinOpParams builtinOpParamsToAux; builtinOpParamsToAux.auxTranslationDirection = AuxTranslationDirection::NonAuxToAux; BuiltinOpParams builtinOpParamsToNonAux; builtinOpParamsToNonAux.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; std::unique_ptr buffer = nullptr; std::unique_ptr gfxAllocation = nullptr; auto kernelObjsForAuxTranslation = std::make_unique(); if (kernelObjType == MockKernelObjForAuxTranslation::Type::MEM_OBJ) { cl_int retVal = CL_SUCCESS; buffer.reset(Buffer::create(pContext, 0, MemoryConstants::pageSize, nullptr, retVal)); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::MEM_OBJ, buffer.get()}); } else { gfxAllocation.reset(new MockGraphicsAllocation(nullptr, MemoryConstants::pageSize)); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::GFX_ALLOC, gfxAllocation.get()}); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParamsToAux); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParamsToNonAux); { // read args auto argNum = 0; auto expectedMocs = pDevice->getGmmHelper()->getMOCS(GMM_RESOURCE_USAGE_OCL_BUFFER_CACHELINE_MISALIGNED); auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); } { // write args auto argNum = 1; auto expectedMocs = pDevice->getGmmHelper()->getMOCS(GMM_RESOURCE_USAGE_OCL_BUFFER); auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(expectedMocs, surfaceState->getMemoryObjectControlState()); } } HWTEST2_P(AuxBuiltInTests, givenAuxToNonAuxTranslationWhenSettingSurfaceStateThenSetValidAuxMode, AuxBuiltinsMatcher) { const auto &compilerProductHelper = pDevice->getRootDeviceEnvironment().getHelper(); if (compilerProductHelper.isForceToStatelessRequired()) { GTEST_SKIP(); } using RENDER_SURFACE_STATE = typename FamilyType::RENDER_SURFACE_STATE; using AUXILIARY_SURFACE_MODE = typename RENDER_SURFACE_STATE::AUXILIARY_SURFACE_MODE; MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); BuiltinOpParams builtinOpParams; builtinOpParams.auxTranslationDirection = AuxTranslationDirection::AuxToNonAux; std::unique_ptr buffer = nullptr; std::unique_ptr gfxAllocation = nullptr; auto gmm = std::unique_ptr(new Gmm(pDevice->getGmmHelper(), nullptr, 1, 0, GMM_RESOURCE_USAGE_OCL_BUFFER, false, {}, true)); gmm->isCompressionEnabled = true; auto kernelObjsForAuxTranslation = std::make_unique(); if (kernelObjType == MockKernelObjForAuxTranslation::Type::MEM_OBJ) { cl_int retVal = CL_SUCCESS; buffer.reset(Buffer::create(pContext, 0, MemoryConstants::pageSize, nullptr, retVal)); buffer->getGraphicsAllocation(pClDevice->getRootDeviceIndex())->setDefaultGmm(gmm.release()); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::MEM_OBJ, buffer.get()}); } else { gfxAllocation.reset(new MockGraphicsAllocation(nullptr, MemoryConstants::pageSize)); gfxAllocation->setDefaultGmm(gmm.get()); kernelObjsForAuxTranslation->insert({KernelObjForAuxTranslation::Type::GFX_ALLOC, gfxAllocation.get()}); } MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParams); { // read arg auto argNum = 0; auto sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(AUXILIARY_SURFACE_MODE::AUXILIARY_SURFACE_MODE_AUX_CCS_E, surfaceState->getAuxiliarySurfaceMode()); } { // write arg auto argNum = 1; auto sshBase = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToNonAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(AUXILIARY_SURFACE_MODE::AUXILIARY_SURFACE_MODE_AUX_NONE, surfaceState->getAuxiliarySurfaceMode()); } } HWTEST2_P(AuxBuiltInTests, givenNonAuxToAuxTranslationWhenSettingSurfaceStateThenSetValidAuxMode, AuxBuiltinsMatcher) { const auto &compilerProductHelper = pDevice->getRootDeviceEnvironment().getHelper(); if (compilerProductHelper.isForceToStatelessRequired()) { GTEST_SKIP(); } using RENDER_SURFACE_STATE = typename FamilyType::RENDER_SURFACE_STATE; using AUXILIARY_SURFACE_MODE = typename RENDER_SURFACE_STATE::AUXILIARY_SURFACE_MODE; MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); BuiltinOpParams builtinOpParams; builtinOpParams.auxTranslationDirection = AuxTranslationDirection::NonAuxToAux; MockKernelObjForAuxTranslation mockKernelObjForAuxTranslation(kernelObjType); auto gmm = std::make_unique(pDevice->getGmmHelper(), nullptr, 1, 0, GMM_RESOURCE_USAGE_OCL_BUFFER, false, StorageInfo{}, true); gmm->isCompressionEnabled = true; if (kernelObjType == MockKernelObjForAuxTranslation::Type::MEM_OBJ) { mockKernelObjForAuxTranslation.mockBuffer->getGraphicsAllocation(pClDevice->getRootDeviceIndex())->setDefaultGmm(gmm.release()); } else { mockKernelObjForAuxTranslation.mockGraphicsAllocation->setDefaultGmm(gmm.get()); } auto kernelObjsForAuxTranslation = std::make_unique(); kernelObjsForAuxTranslation->insert(mockKernelObjForAuxTranslation); MultiDispatchInfo multiDispatchInfo; multiDispatchInfo.setKernelObjsForAuxTranslation(std::move(kernelObjsForAuxTranslation)); mockAuxBuiltInOp.buildDispatchInfosForAuxTranslation(multiDispatchInfo, builtinOpParams); { // read arg auto argNum = 0; auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(AUXILIARY_SURFACE_MODE::AUXILIARY_SURFACE_MODE_AUX_NONE, surfaceState->getAuxiliarySurfaceMode()); } { // write arg auto argNum = 1; auto sshBase = mockAuxBuiltInOp.convertToAuxKernel[0]->getSurfaceStateHeap(); auto sshOffset = mockAuxBuiltInOp.convertToAuxKernel[0]->getKernelInfo().getArgDescriptorAt(argNum).as().bindful; auto surfaceState = reinterpret_cast(ptrOffset(sshBase, sshOffset)); EXPECT_EQ(AUXILIARY_SURFACE_MODE::AUXILIARY_SURFACE_MODE_AUX_CCS_E, surfaceState->getAuxiliarySurfaceMode()); } } TEST_F(BuiltInTests, GivenCopyBufferToBufferWhenDispatchInfoIsCreatedThenSizeIsAlignedToCachLineSize) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); AlignedBuffer src; AlignedBuffer dst; BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &src; builtinOpsParams.dstMemObj = &dst; builtinOpsParams.size = {src.getSize(), 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); const DispatchInfo *dispatchInfo = multiDispatchInfo.begin(); EXPECT_EQ(1u, dispatchInfo->getDim()); size_t leftSize = reinterpret_cast(dst.getCpuAddress()) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, leftSize); size_t rightSize = (reinterpret_cast(dst.getCpuAddress()) + dst.getSize()) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, rightSize); size_t middleElSize = sizeof(uint32_t) * 4; size_t middleSize = dst.getSize() / middleElSize; EXPECT_EQ(Vec3(middleSize, 1, 1), dispatchInfo->getGWS()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); } TEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyBufferToBufferStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBufferStateless, *pClDevice); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; uint64_t size = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &srcBuffer; builtinOpsParams.srcOffset = {static_cast(bigOffset), 0, 0}; builtinOpsParams.dstMemObj = &dstBuffer; builtinOpsParams.dstOffset = {0, 0, 0}; builtinOpsParams.size = {static_cast(size), 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); } TEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyBufferToSystemBufferRectStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferRectStateless, *pClDevice); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; uint64_t size = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); srcBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); BuiltinOpParams dc; dc.srcMemObj = &srcBuffer; dc.dstMemObj = &dstBuffer; dc.srcOffset = {static_cast(bigOffset), 0, 0}; dc.dstOffset = {0, 0, 0}; dc.size = {static_cast(size), 1, 1}; dc.srcRowPitch = static_cast(size); dc.srcSlicePitch = 0; dc.dstRowPitch = static_cast(size); dc.dstSlicePitch = 0; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_TRUE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } TEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyBufferToLocalBufferRectStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferRectStateless, *pClDevice); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; uint64_t size = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); srcBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER); BuiltinOpParams dc; dc.srcMemObj = &srcBuffer; dc.dstMemObj = &dstBuffer; dc.srcOffset = {static_cast(bigOffset), 0, 0}; dc.dstOffset = {0, 0, 0}; dc.size = {static_cast(size), 1, 1}; dc.srcRowPitch = static_cast(size); dc.srcSlicePitch = 0; dc.dstRowPitch = static_cast(size); dc.dstSlicePitch = 0; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_FALSE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } TEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderFillSystemBufferStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::FillBufferStateless, *pClDevice); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; uint64_t size = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); srcBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); BuiltinOpParams dc; dc.srcMemObj = &srcBuffer; dc.dstMemObj = &dstBuffer; dc.dstOffset = {static_cast(bigOffset), 0, 0}; dc.size = {static_cast(size), 0, 0}; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_TRUE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } TEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderFillLocalBufferStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::FillBufferStateless, *pClDevice); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; uint64_t size = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); srcBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER); BuiltinOpParams dc; dc.srcMemObj = &srcBuffer; dc.dstMemObj = &dstBuffer; dc.dstOffset = {static_cast(bigOffset), 0, 0}; dc.size = {static_cast(size), 0, 0}; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_FALSE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } HWTEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyBufferToImageStatelessIsUsedThenParamsAreCorrect) { REQUIRE_64BIT_OR_SKIP(); REQUIRE_IMAGES_OR_SKIP(defaultHwInfo); uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; MockBuffer srcBuffer; srcBuffer.size = static_cast(bigSize); std ::unique_ptr pDstImage(Image2dHelper<>::create(pContext)); ASSERT_NE(nullptr, pDstImage.get()); auto &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToImage3dStateless, *pClDevice); BuiltinOpParams dc; dc.srcPtr = &srcBuffer; dc.dstMemObj = pDstImage.get(); dc.srcOffset = {static_cast(bigOffset), 0, 0}; dc.dstOffset = {0, 0, 0}; dc.size = {1, 1, 1}; dc.dstRowPitch = 0; dc.dstSlicePitch = 0; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); auto kernel = multiDispatchInfo.begin()->getKernel(); ASSERT_NE(nullptr, kernel); EXPECT_TRUE(kernel->getKernelInfo().kernelDescriptor.kernelAttributes.supportsBuffersBiggerThan4Gb()); EXPECT_FALSE(kernel->getKernelInfo().getArgDescriptorAt(0).as().isPureStateful()); } HWTEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyImageToSystemBufferStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER_HOST_MEMORY); std ::unique_ptr pSrcImage(Image2dHelper<>::create(pContext)); ASSERT_NE(nullptr, pSrcImage.get()); auto &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyImage3dToBufferStateless, *pClDevice); BuiltinOpParams dc; dc.srcMemObj = pSrcImage.get(); dc.dstMemObj = &dstBuffer; dc.srcOffset = {0, 0, 0}; dc.dstOffset = {static_cast(bigOffset), 0, 0}; dc.size = {1, 1, 1}; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); auto kernel = multiDispatchInfo.begin()->getKernel(); ASSERT_NE(nullptr, kernel); EXPECT_TRUE(kernel->getKernelInfo().kernelDescriptor.kernelAttributes.supportsBuffersBiggerThan4Gb()); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_TRUE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } HWTEST_F(BuiltInTests, givenBigOffsetAndSizeWhenBuilderCopyImageToLocalBufferStatelessIsUsedThenParamsAreCorrect) { if (is32bit) { GTEST_SKIP(); } uint64_t bigSize = 10ull * MemoryConstants::gigaByte; uint64_t bigOffset = 4ull * MemoryConstants::gigaByte; MockBuffer dstBuffer; dstBuffer.size = static_cast(bigSize); dstBuffer.mockGfxAllocation.setAllocationType(AllocationType::BUFFER); std ::unique_ptr pSrcImage(Image2dHelper<>::create(pContext)); ASSERT_NE(nullptr, pSrcImage.get()); auto &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyImage3dToBufferStateless, *pClDevice); BuiltinOpParams dc; dc.srcMemObj = pSrcImage.get(); dc.dstMemObj = &dstBuffer; dc.srcOffset = {0, 0, 0}; dc.dstOffset = {static_cast(bigOffset), 0, 0}; dc.size = {1, 1, 1}; MultiDispatchInfo multiDispatchInfo(dc); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), dc)); auto kernel = multiDispatchInfo.begin()->getKernel(); ASSERT_NE(nullptr, kernel); EXPECT_TRUE(kernel->getKernelInfo().kernelDescriptor.kernelAttributes.supportsBuffersBiggerThan4Gb()); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_FALSE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } } TEST_F(BuiltInTests, GivenUnalignedCopyBufferToBufferWhenDispatchInfoIsCreatedThenParamsAreCorrect) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); AlignedBuffer src; AlignedBuffer dst; BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &src; builtinOpsParams.srcOffset.x = 5; // causes misalignment from 4-byte boundary by 1 byte (8 bits) builtinOpsParams.dstMemObj = &dst; builtinOpsParams.size = {src.getSize(), 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); const Kernel *kernel = multiDispatchInfo.begin()->getKernel(); EXPECT_EQ(kernel->getKernelInfo().kernelDescriptor.kernelMetadata.kernelName, "CopyBufferToBufferMiddleMisaligned"); const auto crossThreadData = kernel->getCrossThreadData(); const auto crossThreadOffset = kernel->getKernelInfo().getArgDescriptorAt(4).as().elements[0].offset; EXPECT_EQ(8u, *reinterpret_cast(ptrOffset(crossThreadData, crossThreadOffset))); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); } TEST_F(BuiltInTests, GivenReadBufferAlignedWhenDispatchInfoIsCreatedThenParamsAreCorrect) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); AlignedBuffer srcMemObj; auto size = 10 * MemoryConstants::cacheLineSize; auto dstPtr = alignedMalloc(size, MemoryConstants::cacheLineSize); BuiltinOpParams builtinOpsParams; builtinOpsParams.srcMemObj = &srcMemObj; builtinOpsParams.dstPtr = dstPtr; builtinOpsParams.size = {size, 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); const DispatchInfo *dispatchInfo = multiDispatchInfo.begin(); EXPECT_EQ(1u, dispatchInfo->getDim()); size_t leftSize = reinterpret_cast(dstPtr) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, leftSize); size_t rightSize = (reinterpret_cast(dstPtr) + size) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, rightSize); size_t middleElSize = sizeof(uint32_t) * 4; size_t middleSize = size / middleElSize; EXPECT_EQ(Vec3(middleSize, 1, 1), dispatchInfo->getGWS()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); for (auto &dispatchInfo : multiDispatchInfo) { EXPECT_TRUE(dispatchInfo.getKernel()->getDestinationAllocationInSystemMemory()); } alignedFree(dstPtr); } TEST_F(BuiltInTests, GivenWriteBufferAlignedWhenDispatchInfoIsCreatedThenParamsAreCorrect) { BuiltinDispatchInfoBuilder &builder = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); auto size = 10 * MemoryConstants::cacheLineSize; auto srcPtr = alignedMalloc(size, MemoryConstants::cacheLineSize); AlignedBuffer dstMemObj; BuiltinOpParams builtinOpsParams; builtinOpsParams.srcPtr = srcPtr; builtinOpsParams.dstMemObj = &dstMemObj; builtinOpsParams.size = {size, 0, 0}; MultiDispatchInfo multiDispatchInfo(builtinOpsParams); ASSERT_TRUE(builder.buildDispatchInfos(multiDispatchInfo)); EXPECT_EQ(1u, multiDispatchInfo.size()); const DispatchInfo *dispatchInfo = multiDispatchInfo.begin(); EXPECT_EQ(1u, dispatchInfo->getDim()); size_t leftSize = reinterpret_cast(srcPtr) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, leftSize); size_t rightSize = (reinterpret_cast(srcPtr) + size) % MemoryConstants::cacheLineSize; EXPECT_EQ(0u, rightSize); size_t middleElSize = sizeof(uint32_t) * 4; size_t middleSize = size / middleElSize; EXPECT_EQ(Vec3(middleSize, 1, 1), dispatchInfo->getGWS()); EXPECT_TRUE(compareBuiltinOpParams(multiDispatchInfo.peekBuiltinOpParams(), builtinOpsParams)); alignedFree(srcPtr); } TEST_F(BuiltInTests, WhenGettingBuilderInfoTwiceThenPointerIsSame) { BuiltinDispatchInfoBuilder &builder1 = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); BuiltinDispatchInfoBuilder &builder2 = BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToBuffer, *pClDevice); EXPECT_EQ(&builder1, &builder2); } TEST_F(BuiltInTests, GivenUnknownBuiltInOpWhenGettingBuilderInfoThenExceptionThrown) { EXPECT_THROW( BuiltInDispatchBuilderOp::getBuiltinDispatchInfoBuilder(EBuiltInOps::COUNT, *pClDevice), std::runtime_error); } TEST_F(BuiltInTests, GivenUnsupportedBuildTypeWhenBuildingDispatchInfoThenFalseIsReturned) { auto &builtIns = *pDevice->getBuiltIns(); BuiltinDispatchInfoBuilder dispatchInfoBuilder{builtIns, *pClDevice}; BuiltinOpParams params; MultiDispatchInfo multiDispatchInfo(params); auto ret = dispatchInfoBuilder.buildDispatchInfos(multiDispatchInfo); EXPECT_FALSE(ret); ASSERT_EQ(0U, multiDispatchInfo.size()); ret = dispatchInfoBuilder.buildDispatchInfos(multiDispatchInfo, nullptr, 0, Vec3{0, 0, 0}, Vec3{0, 0, 0}, Vec3{0, 0, 0}); EXPECT_FALSE(ret); EXPECT_EQ(0U, multiDispatchInfo.size()); } TEST_F(BuiltInTests, GivenDefaultBuiltinDispatchInfoBuilderWhenValidateDispatchIsCalledThenClSuccessIsReturned) { auto &builtIns = *pDevice->getBuiltIns(); BuiltinDispatchInfoBuilder dispatchInfoBuilder{builtIns, *pClDevice}; auto ret = dispatchInfoBuilder.validateDispatch(nullptr, 1, Vec3{0, 0, 0}, Vec3{0, 0, 0}, Vec3{0, 0, 0}); EXPECT_EQ(CL_SUCCESS, ret); } TEST_F(BuiltInTests, WhenSettingExplictArgThenTrueIsReturned) { auto &builtIns = *pDevice->getBuiltIns(); BuiltinDispatchInfoBuilder dispatchInfoBuilder{builtIns, *pClDevice}; MultiDispatchInfo multiDispatchInfo; BuiltinOpParams params; cl_int err; auto ret = dispatchInfoBuilder.setExplicitArg(1, 5, nullptr, err); EXPECT_TRUE(ret); } TEST_F(VmeBuiltInTests, GivenVmeBuilderWhenGettingDispatchInfoThenValidPointerIsReturned) { overwriteBuiltInBinaryName("media_kernels_backend"); EBuiltInOps::Type vmeOps[] = {EBuiltInOps::VmeBlockMotionEstimateIntel, EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel, EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel}; for (auto op : vmeOps) { BuiltinDispatchInfoBuilder &builder = Vme::getBuiltinDispatchInfoBuilder(op, *pClDevice); EXPECT_NE(nullptr, &builder); } restoreBuiltInBinaryName(); } TEST_F(VmeBuiltInTests, givenInvalidBuiltInOpWhenGetVmeBuilderInfoThenExceptionIsThrown) { EXPECT_THROW(Vme::getBuiltinDispatchInfoBuilder(EBuiltInOps::COUNT, *pClDevice), std::exception); } TEST_F(VmeBuiltInTests, GivenVmeBuilderAndInvalidParamsWhenGettingDispatchInfoThenEmptyKernelIsReturned) { overwriteBuiltInBinaryName("media_kernels_backend"); EBuiltInOps::Type vmeOps[] = {EBuiltInOps::VmeBlockMotionEstimateIntel, EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel, EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel}; for (auto op : vmeOps) { BuiltinDispatchInfoBuilder &builder = Vme::getBuiltinDispatchInfoBuilder(op, *pClDevice); MultiDispatchInfo outMdi; Vec3 gws{352, 288, 0}; Vec3 elws{0, 0, 0}; Vec3 offset{0, 0, 0}; auto ret = builder.buildDispatchInfos(outMdi, nullptr, 0, gws, elws, offset); EXPECT_FALSE(ret); EXPECT_EQ(0U, outMdi.size()); } restoreBuiltInBinaryName(); } TEST_F(VmeBuiltInTests, GivenVmeBuilderWhenGettingDispatchInfoThenParamsAreCorrect) { MockKernelWithInternals mockKernel{*pClDevice}; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.simdSize = 16; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[0] = 16; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[1] = 0; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[2] = 0; overwriteBuiltInBinaryName("media_kernels_backend"); BuiltinDispatchInfoBuilder &builder = Vme::getBuiltinDispatchInfoBuilder(EBuiltInOps::VmeBlockMotionEstimateIntel, *pClDevice); restoreBuiltInBinaryName(); MultiDispatchInfo outMdi; Vec3 gws{352, 288, 0}; Vec3 elws{0, 0, 0}; Vec3 offset{16, 0, 0}; MockBuffer mb; cl_mem bufferArg = static_cast(&mb); cl_int err; constexpr uint32_t bufferArgNum = 3; bool ret = builder.setExplicitArg(bufferArgNum, sizeof(cl_mem), &bufferArg, err); EXPECT_FALSE(ret); EXPECT_EQ(CL_SUCCESS, err); ret = builder.buildDispatchInfos(outMdi, mockKernel.mockKernel, 0, gws, elws, offset); EXPECT_TRUE(ret); EXPECT_EQ(1U, outMdi.size()); auto outDi = outMdi.begin(); EXPECT_EQ(Vec3(352, 1, 1), outDi->getGWS()); EXPECT_EQ(Vec3(16, 1, 1), outDi->getEnqueuedWorkgroupSize()); EXPECT_EQ(Vec3(16, 0, 0), outDi->getOffset()); EXPECT_NE(mockKernel.mockKernel, outDi->getKernel()); EXPECT_EQ(bufferArg, outDi->getKernel()->getKernelArg(bufferArgNum)); constexpr uint32_t vmeImplicitArgsBase = 6; constexpr uint32_t vmeImplicitArgs = 3; ASSERT_EQ(vmeImplicitArgsBase + vmeImplicitArgs, outDi->getKernel()->getKernelInfo().kernelDescriptor.payloadMappings.explicitArgs.size()); uint32_t vmeExtraArgsExpectedVals[] = {18, 22, 18}; // height, width, stride for (uint32_t i = 0; i < vmeImplicitArgs; ++i) { auto &argAsVal = outDi->getKernel()->getKernelInfo().getArgDescriptorAt(vmeImplicitArgsBase + i).as(); EXPECT_EQ(vmeExtraArgsExpectedVals[i], *((uint32_t *)(outDi->getKernel()->getCrossThreadData() + argAsVal.elements[0].offset))); } } TEST_F(VmeBuiltInTests, GivenAdvancedVmeBuilderWhenGettingDispatchInfoThenParamsAreCorrect) { MockKernelWithInternals mockKernel{*pClDevice}; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.simdSize = 16; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[0] = 16; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[1] = 0; mockKernel.kernelInfo.kernelDescriptor.kernelAttributes.requiredWorkgroupSize[2] = 0; Vec3 gws{352, 288, 0}; Vec3 elws{0, 0, 0}; Vec3 offset{0, 0, 0}; cl_int err; constexpr uint32_t bufferArgNum = 7; MockBuffer mb; cl_mem bufferArg = static_cast(&mb); constexpr uint32_t srcImageArgNum = 1; auto image = std::unique_ptr(Image2dHelper<>::create(pContext)); cl_mem srcImageArg = static_cast(image.get()); EBuiltInOps::Type vmeOps[] = {EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel, EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel}; for (auto op : vmeOps) { MultiDispatchInfo outMdi; overwriteBuiltInBinaryName("media_kernels_backend"); BuiltinDispatchInfoBuilder &builder = Vme::getBuiltinDispatchInfoBuilder(op, *pClDevice); restoreBuiltInBinaryName(); bool ret = builder.setExplicitArg(srcImageArgNum, sizeof(cl_mem), &srcImageArg, err); EXPECT_FALSE(ret); EXPECT_EQ(CL_SUCCESS, err); ret = builder.setExplicitArg(bufferArgNum, sizeof(cl_mem), &bufferArg, err); EXPECT_FALSE(ret); EXPECT_EQ(CL_SUCCESS, err); ret = builder.buildDispatchInfos(outMdi, mockKernel.mockKernel, 0, gws, elws, offset); EXPECT_TRUE(ret); EXPECT_EQ(1U, outMdi.size()); auto outDi = outMdi.begin(); EXPECT_EQ(Vec3(352, 1, 1), outDi->getGWS()); EXPECT_EQ(Vec3(16, 1, 1), outDi->getEnqueuedWorkgroupSize()); EXPECT_NE(mockKernel.mockKernel, outDi->getKernel()); EXPECT_EQ(srcImageArg, outDi->getKernel()->getKernelArg(srcImageArgNum)); uint32_t vmeImplicitArgsBase = outDi->getKernel()->getKernelInfo().getArgNumByName("intraSrcImg"); uint32_t vmeImplicitArgs = 4; ASSERT_EQ(vmeImplicitArgsBase + vmeImplicitArgs, outDi->getKernel()->getKernelInfo().getExplicitArgs().size()); EXPECT_EQ(srcImageArg, outDi->getKernel()->getKernelArg(vmeImplicitArgsBase)); ++vmeImplicitArgsBase; --vmeImplicitArgs; uint32_t vmeExtraArgsExpectedVals[] = {18, 22, 18}; // height, width, stride for (uint32_t i = 0; i < vmeImplicitArgs; ++i) { auto &argAsVal = outDi->getKernel()->getKernelInfo().getArgDescriptorAt(vmeImplicitArgsBase + i).as(); EXPECT_EQ(vmeExtraArgsExpectedVals[i], *((uint32_t *)(outDi->getKernel()->getCrossThreadData() + argAsVal.elements[0].offset))); } } } TEST_F(VmeBuiltInTests, WhenGettingBuiltinAsStringThenCorrectStringIsReturned) { EXPECT_EQ(0, strcmp("aux_translation.builtin_kernel", getBuiltinAsString(EBuiltInOps::AuxTranslation))); EXPECT_EQ(0, strcmp("copy_buffer_to_buffer.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyBufferToBuffer))); EXPECT_EQ(0, strcmp("copy_buffer_rect.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyBufferRect))); EXPECT_EQ(0, strcmp("fill_buffer.builtin_kernel", getBuiltinAsString(EBuiltInOps::FillBuffer))); EXPECT_EQ(0, strcmp("copy_buffer_to_image3d.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyBufferToImage3d))); EXPECT_EQ(0, strcmp("copy_image3d_to_buffer.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyImage3dToBuffer))); EXPECT_EQ(0, strcmp("copy_image_to_image1d.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyImageToImage1d))); EXPECT_EQ(0, strcmp("copy_image_to_image2d.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyImageToImage2d))); EXPECT_EQ(0, strcmp("copy_image_to_image3d.builtin_kernel", getBuiltinAsString(EBuiltInOps::CopyImageToImage3d))); EXPECT_EQ(0, strcmp("copy_kernel_timestamps.builtin_kernel", getBuiltinAsString(EBuiltInOps::QueryKernelTimestamps))); EXPECT_EQ(0, strcmp("fill_image1d.builtin_kernel", getBuiltinAsString(EBuiltInOps::FillImage1d))); EXPECT_EQ(0, strcmp("fill_image2d.builtin_kernel", getBuiltinAsString(EBuiltInOps::FillImage2d))); EXPECT_EQ(0, strcmp("fill_image3d.builtin_kernel", getBuiltinAsString(EBuiltInOps::FillImage3d))); EXPECT_EQ(0, strcmp("vme_block_motion_estimate_intel.builtin_kernel", getBuiltinAsString(EBuiltInOps::VmeBlockMotionEstimateIntel))); EXPECT_EQ(0, strcmp("vme_block_advanced_motion_estimate_check_intel.builtin_kernel", getBuiltinAsString(EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel))); EXPECT_EQ(0, strcmp("vme_block_advanced_motion_estimate_bidirectional_check_intel", getBuiltinAsString(EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel))); EXPECT_EQ(0, strcmp("unknown", getBuiltinAsString(EBuiltInOps::COUNT))); } TEST_F(BuiltInTests, GivenEncodeTypeWhenGettingExtensionThenCorrectStringIsReturned) { EXPECT_EQ(0, strcmp("", BuiltinCode::getExtension(BuiltinCode::ECodeType::Any))); EXPECT_EQ(0, strcmp(".bin", BuiltinCode::getExtension(BuiltinCode::ECodeType::Binary))); EXPECT_EQ(0, strcmp(".bc", BuiltinCode::getExtension(BuiltinCode::ECodeType::Intermediate))); EXPECT_EQ(0, strcmp(".cl", BuiltinCode::getExtension(BuiltinCode::ECodeType::Source))); EXPECT_EQ(0, strcmp("", BuiltinCode::getExtension(BuiltinCode::ECodeType::COUNT))); EXPECT_EQ(0, strcmp("", BuiltinCode::getExtension(BuiltinCode::ECodeType::INVALID))); } TEST_F(BuiltInTests, GivenBuiltinResourceWhenCreatingBuiltinResourceThenSizesAreEqual) { std::string resource = "__kernel"; auto br1 = createBuiltinResource(resource.data(), resource.size()); EXPECT_NE(0u, br1.size()); auto br2 = createBuiltinResource(br1); EXPECT_NE(0u, br2.size()); EXPECT_EQ(br1, br2); } TEST_F(BuiltInTests, WhenJoiningPathThenPathsAreJoinedWithCorrectSeparator) { std::string resourceName = "copy_buffer_to_buffer.builtin_kernel.cl"; std::string resourcePath = "path"; EXPECT_EQ(0, strcmp(resourceName.c_str(), joinPath("", resourceName).c_str())); EXPECT_EQ(0, strcmp(resourcePath.c_str(), joinPath(resourcePath, "").c_str())); EXPECT_EQ(0, strcmp((resourcePath + PATH_SEPARATOR + resourceName).c_str(), joinPath(resourcePath + PATH_SEPARATOR, resourceName).c_str())); EXPECT_EQ(0, strcmp((resourcePath + PATH_SEPARATOR + resourceName).c_str(), joinPath(resourcePath, resourceName).c_str())); } TEST_F(BuiltInTests, GivenFileNameWhenGettingKernelFromEmbeddedStorageRegistryThenValidPtrIsReturnedForExisitngKernels) { class MockEmbeddedStorageRegistry : public EmbeddedStorageRegistry { using EmbeddedStorageRegistry::EmbeddedStorageRegistry; }; MockEmbeddedStorageRegistry storageRegistry; std::string resource = "__kernel"; storageRegistry.store("kernel.cl", createBuiltinResource(resource.data(), resource.size() + 1)); const BuiltinResourceT *br = storageRegistry.get("kernel.cl"); EXPECT_NE(nullptr, br); EXPECT_EQ(0, strcmp(resource.data(), br->data())); const BuiltinResourceT *bnr = storageRegistry.get("unknown.cl"); EXPECT_EQ(nullptr, bnr); } TEST_F(BuiltInTests, WhenStoringRootPathThenPathIsSavedCorrectly) { class MockStorage : Storage { public: MockStorage(const std::string &rootPath) : Storage(rootPath){}; std::string &getRootPath() { return Storage::rootPath; } protected: BuiltinResourceT loadImpl(const std::string &fullResourceName) override { BuiltinResourceT ret; return ret; } }; const std::string rootPath("root"); MockStorage mockStorage(rootPath); EXPECT_EQ(0, strcmp(rootPath.data(), mockStorage.getRootPath().data())); } TEST_F(BuiltInTests, GivenFiledNameWhenLoadingImplKernelFromEmbeddedStorageRegistryThenValidPtrIsReturnedForExisitngKernels) { class MockEmbeddedStorage : EmbeddedStorage { public: MockEmbeddedStorage(const std::string &rootPath) : EmbeddedStorage(rootPath){}; BuiltinResourceT loadImpl(const std::string &fullResourceName) override { return EmbeddedStorage::loadImpl(fullResourceName); } }; MockEmbeddedStorage mockEmbeddedStorage("root"); BuiltinResourceT br = mockEmbeddedStorage.loadImpl("copy_buffer_to_buffer.builtin_kernel.cl"); EXPECT_NE(0u, br.size()); BuiltinResourceT bnr = mockEmbeddedStorage.loadImpl("unknown.cl"); EXPECT_EQ(0u, bnr.size()); } TEST_F(BuiltInTests, GivenFiledNameWhenLoadingImplKernelFromFileStorageThenValidPtrIsReturnedForExisitngKernels) { class MockFileStorage : FileStorage { public: MockFileStorage(const std::string &rootPath) : FileStorage(rootPath){}; BuiltinResourceT loadImpl(const std::string &fullResourceName) override { return FileStorage::loadImpl(fullResourceName); } }; MockFileStorage mockEmbeddedStorage("root"); BuiltinResourceT br = mockEmbeddedStorage.loadImpl(clFiles + "copybuffer.cl"); EXPECT_NE(0u, br.size()); BuiltinResourceT bnr = mockEmbeddedStorage.loadImpl("unknown.cl"); EXPECT_EQ(0u, bnr.size()); } TEST_F(BuiltInTests, WhenBuiltinsLibIsCreatedThenAllStoragesSizeIsTwo) { auto mockBuiltinsLib = std::unique_ptr(new MockBuiltinsLib()); EXPECT_EQ(2u, mockBuiltinsLib->allStorages.size()); } TEST_F(BuiltInTests, GivenTypeAnyWhenGettingBuiltinCodeThenCorrectBuiltinReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Any, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Binary, code.type); EXPECT_NE(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, GivenTypeBinaryWhenGettingBuiltinCodeThenCorrectBuiltinReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Binary, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Binary, code.type); EXPECT_NE(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, GivenTypeIntermediateWhenGettingBuiltinCodeThenCorrectBuiltinReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Intermediate, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Intermediate, code.type); EXPECT_EQ(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, GivenTypeSourceWhenGettingBuiltinCodeThenCorrectBuiltinReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Source, code.type); EXPECT_NE(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, GivenTypeInvalidWhenGettingBuiltinCodeThenKernelIsEmpty) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::INVALID, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::INVALID, code.type); EXPECT_EQ(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, GivenBuiltinTypeSourceWhenGettingBuiltinResourceThenResourceSizeIsNonZero) { auto mockBuiltinsLib = std::unique_ptr(new MockBuiltinsLib()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::AuxTranslation, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferRect, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImage3dToBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage1d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage2d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage1d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage2d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockMotionEstimateIntel, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::COUNT, BuiltinCode::ECodeType::Source, *pDevice).size()); } HWCMDTEST_F(IGFX_GEN8_CORE, BuiltInTests, GivenBuiltinTypeBinaryWhenGettingBuiltinResourceThenResourceSizeIsNonZero) { auto mockBuiltinsLib = std::unique_ptr(new MockBuiltinsLib()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferRect, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillBuffer, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToImage3d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImage3dToBuffer, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage1d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage2d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage3d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage1d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage2d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage3d, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockMotionEstimateIntel, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockAdvancedMotionEstimateCheckIntel, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::VmeBlockAdvancedMotionEstimateBidirectionalCheckIntel, BuiltinCode::ECodeType::Binary, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::COUNT, BuiltinCode::ECodeType::Binary, *pDevice).size()); } TEST_F(BuiltInTests, GivenBuiltinTypeSourceWhenGettingBuiltinResourceForNotRegisteredRevisionThenResourceSizeIsNonZero) { pDevice->getRootDeviceEnvironment().getMutableHardwareInfo()->platform.usRevId += 0xdead; auto mockBuiltinsLib = std::unique_ptr(new MockBuiltinsLib()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferRect, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyBufferToImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImage3dToBuffer, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage1d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage2d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::CopyImageToImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage1d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage2d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_NE(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::FillImage3d, BuiltinCode::ECodeType::Source, *pDevice).size()); EXPECT_EQ(0u, mockBuiltinsLib->getBuiltinResource(EBuiltInOps::COUNT, BuiltinCode::ECodeType::Source, *pDevice).size()); } TEST_F(BuiltInTests, GivenTypeAnyWhenCreatingProgramFromCodeThenValidPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Any, *pDevice); EXPECT_NE(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_NE(nullptr, program.get()); } TEST_F(BuiltInTests, GivenTypeSourceWhenCreatingProgramFromCodeThenValidPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice); EXPECT_NE(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_NE(nullptr, program.get()); } TEST_F(BuiltInTests, givenCreateProgramFromSourceWhenForceToStatelessRequiredOr32BitThenInternalOptionsHasGreaterThan4gbBuffersRequired) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice); EXPECT_NE(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_NE(nullptr, program.get()); auto builtinInternalOptions = program->getInternalOptions(); const auto &compilerProductHelper = pDevice->getRootDeviceEnvironment().getHelper(); if (compilerProductHelper.isForceToStatelessRequired() || is32bit) { EXPECT_TRUE(hasSubstr(builtinInternalOptions, std::string(CompilerOptions::greaterThan4gbBuffersRequired))); } else { EXPECT_FALSE(hasSubstr(builtinInternalOptions, std::string(CompilerOptions::greaterThan4gbBuffersRequired))); } } TEST_F(BuiltInTests, GivenTypeIntermediateWhenCreatingProgramFromCodeThenNullPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Intermediate, *pDevice); EXPECT_EQ(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_EQ(nullptr, program.get()); } TEST_F(BuiltInTests, GivenTypeBinaryWhenCreatingProgramFromCodeThenValidPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Binary, *pDevice); EXPECT_NE(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_NE(nullptr, program.get()); } TEST_F(BuiltInTests, GivenTypeInvalidWhenCreatingProgramFromCodeThenNullPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::INVALID, *pDevice); EXPECT_EQ(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_EQ(nullptr, program.get()); } TEST_F(BuiltInTests, GivenInvalidBuiltinWhenCreatingProgramFromCodeThenNullPointerIsReturned) { auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::COUNT, BuiltinCode::ECodeType::Any, *pDevice); EXPECT_EQ(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); EXPECT_EQ(nullptr, program.get()); } TEST_F(BuiltInTests, GivenForce32bitWhenCreatingProgramThenCorrectKernelIsCreated) { bool force32BitAddressess = pDevice->getDeviceInfo().force32BitAddressess; const_cast(&pDevice->getDeviceInfo())->force32BitAddressess = true; auto builtinsLib = std::unique_ptr(new BuiltinsLib()); const BuiltinCode bc = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Source, *pDevice); ASSERT_NE(0u, bc.resource.size()); auto program = std::unique_ptr(BuiltinDispatchInfoBuilder::createProgramFromCode(bc, toClDeviceVector(*pClDevice))); ASSERT_NE(nullptr, program.get()); auto builtinInternalOptions = program->getInternalOptions(); auto it = builtinInternalOptions.find(NEO::CompilerOptions::arch32bit.data()); EXPECT_EQ(std::string::npos, it); it = builtinInternalOptions.find(NEO::CompilerOptions::greaterThan4gbBuffersRequired.data()); const auto &compilerProductHelper = pDevice->getRootDeviceEnvironment().getHelper(); if (is32bit || compilerProductHelper.isForceToStatelessRequired()) { EXPECT_NE(std::string::npos, it); } else { EXPECT_EQ(std::string::npos, it); } const_cast(&pDevice->getDeviceInfo())->force32BitAddressess = force32BitAddressess; } TEST_F(BuiltInTests, GivenVmeKernelWhenGettingDeviceInfoThenCorrectVmeVersionIsReturned) { if (!pDevice->getHardwareInfo().capabilityTable.supportsVme) { GTEST_SKIP(); } cl_uint param; auto ret = pClDevice->getDeviceInfo(CL_DEVICE_ME_VERSION_INTEL, sizeof(param), ¶m, nullptr); EXPECT_EQ(CL_SUCCESS, ret); EXPECT_EQ(static_cast(CL_ME_VERSION_ADVANCED_VER_2_INTEL), param); } TEST_F(VmeBuiltInTests, WhenVmeKernelIsCreatedThenParamsAreCorrect) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; { int32_t bufArgNum = 7; cl_mem mem = 0; vmeBuilder.setExplicitArg(bufArgNum, sizeof(cl_mem), &mem, err); EXPECT_TRUE(vmeBuilder.validateBufferSize(-1, 16)); EXPECT_TRUE(vmeBuilder.validateBufferSize(bufArgNum, 16)); MockBuffer mb; mem = &mb; vmeBuilder.setExplicitArg(bufArgNum, sizeof(cl_mem), &mem, err); EXPECT_TRUE(vmeBuilder.validateBufferSize(bufArgNum, mb.getSize())); EXPECT_TRUE(vmeBuilder.validateBufferSize(bufArgNum, mb.getSize() / 2)); EXPECT_FALSE(vmeBuilder.validateBufferSize(bufArgNum, mb.getSize() * 2)); mem = 0; vmeBuilder.setExplicitArg(bufArgNum, sizeof(cl_mem), &mem, err); } { EXPECT_TRUE(vmeBuilder.validateEnumVal(1, 1, 2, 3, 4)); EXPECT_TRUE(vmeBuilder.validateEnumVal(1, 1)); EXPECT_TRUE(vmeBuilder.validateEnumVal(3, 1, 2, 3)); EXPECT_FALSE(vmeBuilder.validateEnumVal(1, 3, 4)); EXPECT_FALSE(vmeBuilder.validateEnumVal(1)); EXPECT_FALSE(vmeBuilder.validateEnumVal(1, 2)); int32_t valArgNum = 3; uint32_t val = 7; vmeBuilder.setExplicitArg(valArgNum, sizeof(val), &val, err); EXPECT_FALSE(vmeBuilder.validateEnumArg(valArgNum, 3)); EXPECT_TRUE(vmeBuilder.validateEnumArg(valArgNum, 7)); val = 0; vmeBuilder.setExplicitArg(valArgNum, sizeof(val), &val, err); } { int32_t valArgNum = 3; uint32_t val = 7; vmeBuilder.setExplicitArg(valArgNum, sizeof(val), &val, err); EXPECT_EQ(val, vmeBuilder.getKernelArgByValValue(valArgNum)); val = 11; vmeBuilder.setExplicitArg(valArgNum, sizeof(val), &val, err); EXPECT_EQ(val, vmeBuilder.getKernelArgByValValue(valArgNum)); val = 0; vmeBuilder.setExplicitArg(valArgNum, sizeof(val), &val, err); } } TEST_F(VmeBuiltInTests, WhenVmeKernelIsCreatedThenDispatchIsBidirectional) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp avmeBuilder(*this->pBuiltIns, *pClDevice); BuiltInOp avmeBidirBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); EXPECT_FALSE(avmeBuilder.isBidirKernel()); EXPECT_TRUE(avmeBidirBuilder.isBidirKernel()); } struct ImageVmeValidFormat : Image2dDefaults { static const cl_image_format imageFormat; static const cl_image_desc iamgeDesc; }; const cl_image_format ImageVmeValidFormat::imageFormat = { CL_R, CL_UNORM_INT8}; const cl_image_desc ImageVmeValidFormat::iamgeDesc = { CL_MEM_OBJECT_IMAGE1D, 8192, 16, 1, 1, 0, 0, 0, 0, {nullptr}}; struct ImageVmeInvalidDataType : Image2dDefaults { static const cl_image_format imageFormat; }; const cl_image_format ImageVmeInvalidDataType::imageFormat = { CL_R, CL_FLOAT}; struct ImageVmeInvalidChannelOrder : Image2dDefaults { static const cl_image_format imageFormat; }; const cl_image_format ImageVmeInvalidChannelOrder::imageFormat = { CL_RGBA, CL_UNORM_INT8}; TEST_F(VmeBuiltInTests, WhenValidatingImagesThenCorrectResponses) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); uint32_t srcImgArgNum = 1; uint32_t refImgArgNum = 2; cl_int err; { // validate images are not null std::unique_ptr image1(ImageHelper::create(pContext)); cl_mem srcImgMem = 0; EXPECT_EQ(CL_INVALID_KERNEL_ARGS, vmeBuilder.validateImages(Vec3{3, 3, 0}, Vec3{0, 0, 0})); srcImgMem = image1.get(); vmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); EXPECT_EQ(CL_INVALID_KERNEL_ARGS, vmeBuilder.validateImages(Vec3{3, 3, 0}, Vec3{0, 0, 0})); } { // validate image formats std::unique_ptr imageValid(ImageHelper::create(pContext)); std::unique_ptr imageInvalidDataType(ImageHelper::create(pContext)); std::unique_ptr imageChannelOrder(ImageHelper::create(pContext)); Image *images[] = {imageValid.get(), imageInvalidDataType.get(), imageChannelOrder.get()}; for (Image *srcImg : images) { for (Image *dstImg : images) { cl_mem srcImgMem = srcImg; cl_mem refImgMem = dstImg; vmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); vmeBuilder.setExplicitArg(refImgArgNum, sizeof(refImgMem), &refImgMem, err); bool shouldSucceed = (srcImg == imageValid.get()) && (dstImg == imageValid.get()); if (shouldSucceed) { EXPECT_EQ(CL_SUCCESS, vmeBuilder.validateImages(Vec3{1, 1, 0}, Vec3{0, 0, 0})); } else { EXPECT_EQ(CL_INVALID_IMAGE_FORMAT_DESCRIPTOR, vmeBuilder.validateImages(Vec3{1, 1, 0}, Vec3{0, 0, 0})); } } } } { // validate image tiling std::unique_ptr imageValid(ImageHelper::create(pContext)); DebugManagerStateRestore restorer; DebugManager.flags.ForceLinearImages.set(true); std::unique_ptr imageLinear(ImageHelper::create(pContext)); Image *images[] = {imageValid.get(), imageLinear.get()}; for (Image *srcImg : images) { for (Image *dstImg : images) { cl_mem srcImgMem = srcImg; cl_mem refImgMem = dstImg; vmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); vmeBuilder.setExplicitArg(refImgArgNum, sizeof(refImgMem), &refImgMem, err); bool shouldSucceed = (srcImg == imageValid.get()) && (dstImg == imageValid.get()); if (shouldSucceed) { EXPECT_EQ(CL_SUCCESS, vmeBuilder.validateImages(Vec3{1, 1, 0}, Vec3{0, 0, 0})); } else { EXPECT_EQ(CL_OUT_OF_RESOURCES, vmeBuilder.validateImages(Vec3{1, 1, 0}, Vec3{0, 0, 0})); } } } } { // validate region size std::unique_ptr imageValid(ImageHelper::create(pContext)); cl_mem imgValidMem = imageValid.get(); vmeBuilder.setExplicitArg(srcImgArgNum, sizeof(imgValidMem), &imgValidMem, err); vmeBuilder.setExplicitArg(refImgArgNum, sizeof(imgValidMem), &imgValidMem, err); EXPECT_EQ(CL_INVALID_IMAGE_SIZE, vmeBuilder.validateImages(Vec3{imageValid->getImageDesc().image_width + 1, 1, 0}, Vec3{0, 0, 0})); EXPECT_EQ(CL_INVALID_IMAGE_SIZE, vmeBuilder.validateImages(Vec3{1, imageValid->getImageDesc().image_height + 1, 0}, Vec3{0, 0, 0})); } } TEST_F(VmeBuiltInTests, WhenValidatingFlagsThenValidFlagCombinationsReturnTrue) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); uint32_t defaultSkipBlockVal = 8192; uint32_t flagsArgNum = 3; std::tuple flagsToTest[] = { std::make_tuple(CL_ME_CHROMA_INTRA_PREDICT_ENABLED_INTEL, false, defaultSkipBlockVal), std::make_tuple(CL_ME_SKIP_BLOCK_TYPE_16x16_INTEL, true, CL_ME_MB_TYPE_16x16_INTEL), std::make_tuple(CL_ME_SKIP_BLOCK_TYPE_8x8_INTEL, true, CL_ME_MB_TYPE_8x8_INTEL), std::make_tuple(defaultSkipBlockVal, true, defaultSkipBlockVal), }; cl_int err; for (auto &conf : flagsToTest) { uint32_t skipBlock = defaultSkipBlockVal; vmeBuilder.setExplicitArg(flagsArgNum, sizeof(uint32_t), &std::get<0>(conf), err); bool validationResult = vmeBuilder.validateFlags(skipBlock); if (std::get<1>(conf)) { EXPECT_TRUE(validationResult); } else { EXPECT_FALSE(validationResult); } EXPECT_EQ(std::get<2>(conf), skipBlock); } } TEST_F(VmeBuiltInTests, WhenValidatingSkipBlockTypeThenCorrectResponses) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp avmeBidirectionalBuilder(*this->pBuiltIns, *pClDevice); BuiltInOp avmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; uint32_t skipBlockTypeArgNum = 4; uint32_t skipBlockType = 8192; bool ret = avmeBidirectionalBuilder.validateSkipBlockTypeArg(skipBlockType); EXPECT_TRUE(ret); EXPECT_EQ(8192U, skipBlockType); skipBlockType = 8192U; avmeBuilder.setExplicitArg(skipBlockTypeArgNum, sizeof(uint32_t), &skipBlockType, err); ret = avmeBuilder.validateSkipBlockTypeArg(skipBlockType); EXPECT_FALSE(ret); skipBlockType = CL_ME_MB_TYPE_16x16_INTEL; avmeBuilder.setExplicitArg(skipBlockTypeArgNum, sizeof(uint32_t), &skipBlockType, err); skipBlockType = 8192U; ret = avmeBuilder.validateSkipBlockTypeArg(skipBlockType); EXPECT_TRUE(ret); EXPECT_EQ(static_cast(CL_ME_MB_TYPE_16x16_INTEL), skipBlockType); skipBlockType = CL_ME_MB_TYPE_8x8_INTEL; avmeBuilder.setExplicitArg(skipBlockTypeArgNum, sizeof(uint32_t), &skipBlockType, err); skipBlockType = 8192U; ret = avmeBuilder.validateSkipBlockTypeArg(skipBlockType); EXPECT_TRUE(ret); EXPECT_EQ(static_cast(CL_ME_MB_TYPE_8x8_INTEL), skipBlockType); } TEST_F(VmeBuiltInTests, GivenAcceleratorWhenExplicitlySettingArgThenFalseIsReturned) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; uint32_t aceleratorArgNum = 0; bool ret = vmeBuilder.setExplicitArg(aceleratorArgNum, sizeof(cl_accelerator_intel), nullptr, err); EXPECT_FALSE(ret); EXPECT_EQ(CL_INVALID_ACCELERATOR_INTEL, err); cl_motion_estimation_desc_intel acceleratorDesc; acceleratorDesc.subpixel_mode = CL_ME_SUBPIXEL_MODE_INTEGER_INTEL; acceleratorDesc.sad_adjust_mode = CL_ME_SAD_ADJUST_MODE_NONE_INTEL; acceleratorDesc.search_path_type = CL_ME_SEARCH_PATH_RADIUS_2_2_INTEL; acceleratorDesc.mb_block_type = CL_ME_MB_TYPE_16x16_INTEL; auto neoAccelerator = std::unique_ptr(VmeAccelerator::create(pContext, CL_ACCELERATOR_TYPE_MOTION_ESTIMATION_INTEL, sizeof(acceleratorDesc), &acceleratorDesc, err)); ASSERT_NE(nullptr, neoAccelerator.get()); cl_accelerator_intel clAccel = neoAccelerator.get(); ret = vmeBuilder.setExplicitArg(aceleratorArgNum, sizeof(cl_accelerator_intel), &clAccel, err); EXPECT_FALSE(ret); EXPECT_EQ(CL_SUCCESS, err); } TEST_F(VmeBuiltInTests, WhenValidatingDispatchThenCorrectReturns) { overwriteBuiltInBinaryName("media_kernels_backend"); struct MockVmeBuilder : BuiltInOp { using BuiltInOp::BuiltInOp; cl_int validateVmeDispatch(const Vec3 &inputRegion, const Vec3 &offset, size_t blkNum, size_t blkMul) const override { receivedInputRegion = inputRegion; receivedOffset = offset; receivedBlkNum = blkNum; receivedBlkMul = blkMul; wasValidateVmeDispatchCalled = true; return valueToReturn; } mutable bool wasValidateVmeDispatchCalled = false; mutable Vec3 receivedInputRegion = {0, 0, 0}; mutable Vec3 receivedOffset = {0, 0, 0}; mutable size_t receivedBlkNum = 0; mutable size_t receivedBlkMul = 0; mutable cl_int valueToReturn = CL_SUCCESS; }; uint32_t aaceleratorArgNum = 0; MockVmeBuilder vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int ret = vmeBuilder.validateDispatch(nullptr, 1, Vec3{16, 16, 0}, Vec3{16, 1, 0}, Vec3{0, 0, 0}); EXPECT_EQ(CL_INVALID_WORK_DIMENSION, ret); ret = vmeBuilder.validateDispatch(nullptr, 3, Vec3{16, 16, 0}, Vec3{16, 1, 0}, Vec3{0, 0, 0}); EXPECT_EQ(CL_INVALID_WORK_DIMENSION, ret); ret = vmeBuilder.validateDispatch(nullptr, 2, Vec3{16, 16, 0}, Vec3{16, 1, 0}, Vec3{0, 0, 0}); EXPECT_EQ(CL_INVALID_KERNEL_ARGS, ret); // accelerator not set EXPECT_FALSE(vmeBuilder.wasValidateVmeDispatchCalled); cl_int err; cl_motion_estimation_desc_intel acceleratorDesc; acceleratorDesc.subpixel_mode = CL_ME_SUBPIXEL_MODE_INTEGER_INTEL; acceleratorDesc.sad_adjust_mode = CL_ME_SAD_ADJUST_MODE_NONE_INTEL; acceleratorDesc.search_path_type = CL_ME_SEARCH_PATH_RADIUS_2_2_INTEL; Vec3 gws{16, 16, 0}; Vec3 lws{16, 1, 0}; Vec3 off{0, 0, 0}; size_t gwWidthInBlk = 0; size_t gwHeightInBlk = 0; vmeBuilder.getBlkTraits(gws, gwWidthInBlk, gwHeightInBlk); { acceleratorDesc.mb_block_type = CL_ME_MB_TYPE_16x16_INTEL; auto neoAccelerator = std::unique_ptr(VmeAccelerator::create(pContext, CL_ACCELERATOR_TYPE_MOTION_ESTIMATION_INTEL, sizeof(acceleratorDesc), &acceleratorDesc, err)); ASSERT_NE(nullptr, neoAccelerator.get()); cl_accelerator_intel clAccel = neoAccelerator.get(); vmeBuilder.setExplicitArg(aaceleratorArgNum, sizeof(clAccel), &clAccel, err); vmeBuilder.wasValidateVmeDispatchCalled = false; auto ret = vmeBuilder.validateDispatch(nullptr, 2, gws, lws, off); EXPECT_EQ(CL_SUCCESS, ret); EXPECT_TRUE(vmeBuilder.wasValidateVmeDispatchCalled); EXPECT_EQ(gws, vmeBuilder.receivedInputRegion); EXPECT_EQ(off, vmeBuilder.receivedOffset); EXPECT_EQ(gwWidthInBlk * gwHeightInBlk, vmeBuilder.receivedBlkNum); EXPECT_EQ(1U, vmeBuilder.receivedBlkMul); } { acceleratorDesc.mb_block_type = CL_ME_MB_TYPE_4x4_INTEL; auto neoAccelerator = std::unique_ptr(VmeAccelerator::create(pContext, CL_ACCELERATOR_TYPE_MOTION_ESTIMATION_INTEL, sizeof(acceleratorDesc), &acceleratorDesc, err)); ASSERT_NE(nullptr, neoAccelerator.get()); cl_accelerator_intel clAccel = neoAccelerator.get(); vmeBuilder.setExplicitArg(aaceleratorArgNum, sizeof(clAccel), &clAccel, err); vmeBuilder.wasValidateVmeDispatchCalled = false; auto ret = vmeBuilder.validateDispatch(nullptr, 2, gws, lws, off); EXPECT_EQ(CL_SUCCESS, ret); EXPECT_TRUE(vmeBuilder.wasValidateVmeDispatchCalled); EXPECT_EQ(gws, vmeBuilder.receivedInputRegion); EXPECT_EQ(off, vmeBuilder.receivedOffset); EXPECT_EQ(gwWidthInBlk * gwHeightInBlk, vmeBuilder.receivedBlkNum); EXPECT_EQ(16U, vmeBuilder.receivedBlkMul); } { acceleratorDesc.mb_block_type = CL_ME_MB_TYPE_8x8_INTEL; auto neoAccelerator = std::unique_ptr(VmeAccelerator::create(pContext, CL_ACCELERATOR_TYPE_MOTION_ESTIMATION_INTEL, sizeof(acceleratorDesc), &acceleratorDesc, err)); ASSERT_NE(nullptr, neoAccelerator.get()); cl_accelerator_intel clAccel = neoAccelerator.get(); vmeBuilder.setExplicitArg(aaceleratorArgNum, sizeof(clAccel), &clAccel, err); vmeBuilder.wasValidateVmeDispatchCalled = false; vmeBuilder.valueToReturn = 37; auto ret = vmeBuilder.validateDispatch(nullptr, 2, gws, lws, off); EXPECT_EQ(37, ret); EXPECT_TRUE(vmeBuilder.wasValidateVmeDispatchCalled); EXPECT_EQ(gws, vmeBuilder.receivedInputRegion); EXPECT_EQ(off, vmeBuilder.receivedOffset); EXPECT_EQ(gwWidthInBlk * gwHeightInBlk, vmeBuilder.receivedBlkNum); EXPECT_EQ(4U, vmeBuilder.receivedBlkMul); } } TEST_F(VmeBuiltInTests, WhenValidatingVmeDispatchThenCorrectReturns) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; // images not set EXPECT_EQ(CL_INVALID_KERNEL_ARGS, vmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); uint32_t srcImgArgNum = 1; uint32_t refImgArgNum = 2; std::unique_ptr imageValid(ImageHelper::create(pContext)); cl_mem srcImgMem = imageValid.get(); vmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); vmeBuilder.setExplicitArg(refImgArgNum, sizeof(srcImgMem), &srcImgMem, err); // null buffers are valid EXPECT_EQ(CL_SUCCESS, vmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); // too small buffers should fail MockBuffer mb; cl_mem mem = &mb; uint32_t predictionMotionVectorBufferArgNum = 3; uint32_t motionVectorBufferArgNum = 4; uint32_t residualsBufferArgNum = 5; for (uint32_t argNum : {predictionMotionVectorBufferArgNum, motionVectorBufferArgNum, residualsBufferArgNum}) { EXPECT_EQ(CL_SUCCESS, vmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, mb.getSize() * 2, 1)); vmeBuilder.setExplicitArg(argNum, sizeof(cl_mem), &mem, err); EXPECT_EQ(CL_INVALID_BUFFER_SIZE, vmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, mb.getSize() * 2, 1)); vmeBuilder.setExplicitArg(argNum, sizeof(cl_mem), nullptr, err); } } TEST_F(VmeBuiltInTests, GivenAdvancedVmeWhenValidatingVmeDispatchThenCorrectReturns) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp avmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; // images not set ASSERT_EQ(CL_INVALID_KERNEL_ARGS, avmeBuilder.VmeBuiltinDispatchInfoBuilder::validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); EXPECT_EQ(CL_INVALID_KERNEL_ARGS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); uint32_t srcImgArgNum = 1; uint32_t refImgArgNum = 2; std::unique_ptr imageValid(ImageHelper::create(pContext)); cl_mem srcImgMem = imageValid.get(); avmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); avmeBuilder.setExplicitArg(refImgArgNum, sizeof(srcImgMem), &srcImgMem, err); ASSERT_EQ(CL_SUCCESS, avmeBuilder.VmeBuiltinDispatchInfoBuilder::validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); uint32_t flagsArgNum = 3; uint32_t val = CL_ME_CHROMA_INTRA_PREDICT_ENABLED_INTEL; avmeBuilder.setExplicitArg(flagsArgNum, sizeof(val), &val, err); EXPECT_EQ(CL_INVALID_KERNEL_ARGS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); val = CL_ME_SKIP_BLOCK_TYPE_8x8_INTEL; avmeBuilder.setExplicitArg(flagsArgNum, sizeof(val), &val, err); uint32_t skipBlockTypeArgNum = 4; val = 8192; avmeBuilder.setExplicitArg(skipBlockTypeArgNum, sizeof(uint32_t), &val, err); EXPECT_EQ(CL_OUT_OF_RESOURCES, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); val = CL_ME_MB_TYPE_16x16_INTEL; avmeBuilder.setExplicitArg(skipBlockTypeArgNum, sizeof(uint32_t), &val, err); uint32_t searchCostPenaltyArgNum = 5; val = 8192; avmeBuilder.setExplicitArg(searchCostPenaltyArgNum, sizeof(uint32_t), &val, err); EXPECT_EQ(CL_OUT_OF_RESOURCES, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); val = CL_ME_COST_PENALTY_NONE_INTEL; avmeBuilder.setExplicitArg(searchCostPenaltyArgNum, sizeof(uint32_t), &val, err); uint32_t searchCostPrecisionArgNum = 6; val = 8192; avmeBuilder.setExplicitArg(searchCostPrecisionArgNum, sizeof(uint32_t), &val, err); EXPECT_EQ(CL_OUT_OF_RESOURCES, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); val = CL_ME_COST_PRECISION_QPEL_INTEL; avmeBuilder.setExplicitArg(searchCostPrecisionArgNum, sizeof(uint32_t), &val, err); // for non-bidirectional avme kernel, countMotionVectorBuffer must be set uint32_t countMotionVectorBufferArgNum = 7; EXPECT_EQ(CL_INVALID_BUFFER_SIZE, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); MockBuffer mb; cl_mem mem = &mb; avmeBuilder.setExplicitArg(countMotionVectorBufferArgNum, sizeof(cl_mem), &mem, err); EXPECT_EQ(CL_SUCCESS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 1, 1)); } TEST_F(VmeBuiltInTests, GivenAdvancedBidirectionalVmeWhenValidatingVmeDispatchThenCorrectReturns) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp avmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); cl_int err; uint32_t srcImgArgNum = 1; uint32_t refImgArgNum = 2; std::unique_ptr imageValid(ImageHelper::create(pContext)); cl_mem srcImgMem = imageValid.get(); avmeBuilder.setExplicitArg(srcImgArgNum, sizeof(srcImgMem), &srcImgMem, err); avmeBuilder.setExplicitArg(refImgArgNum, sizeof(srcImgMem), &srcImgMem, err); ASSERT_EQ(CL_SUCCESS, avmeBuilder.VmeBuiltinDispatchInfoBuilder::validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); uint32_t flagsArgNum = 6; uint32_t val = CL_ME_SKIP_BLOCK_TYPE_8x8_INTEL; avmeBuilder.setExplicitArg(flagsArgNum, sizeof(val), &val, err); uint32_t searchCostPenaltyArgNum = 7; val = CL_ME_COST_PENALTY_NONE_INTEL; avmeBuilder.setExplicitArg(searchCostPenaltyArgNum, sizeof(uint32_t), &val, err); uint32_t searchCostPrecisionArgNum = 8; val = CL_ME_COST_PRECISION_QPEL_INTEL; avmeBuilder.setExplicitArg(searchCostPrecisionArgNum, sizeof(uint32_t), &val, err); uint32_t bidirWeightArgNum = 10; val = 255; avmeBuilder.setExplicitArg(bidirWeightArgNum, sizeof(uint8_t), &val, err); EXPECT_EQ(CL_INVALID_KERNEL_ARGS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); val = CL_ME_BIDIR_WEIGHT_QUARTER_INTEL; avmeBuilder.setExplicitArg(bidirWeightArgNum, sizeof(uint8_t), &val, err); EXPECT_EQ(CL_SUCCESS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 64, 1)); // test bufferSize checking uint32_t countMotionVectorBufferArgNum = 11; MockBuffer mb; cl_mem mem = &mb; avmeBuilder.setExplicitArg(countMotionVectorBufferArgNum, sizeof(cl_mem), &mem, err); EXPECT_EQ(CL_SUCCESS, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, 1, 1)); EXPECT_EQ(CL_INVALID_BUFFER_SIZE, avmeBuilder.validateVmeDispatch(Vec3{1, 1, 0}, Vec3{0, 0, 0}, mb.getSize() * 2, 1)); } TEST_F(VmeBuiltInTests, GivenAdvancedVmeWhenGettingSkipResidualsBuffExpSizeThenDefaultSizeIsReturned) { overwriteBuiltInBinaryName("media_kernels_backend"); BuiltInOp vmeBuilder(*this->pBuiltIns, *pClDevice); restoreBuiltInBinaryName(); auto size16x16 = vmeBuilder.getSkipResidualsBuffExpSize(CL_ME_MB_TYPE_16x16_INTEL, 4); auto sizeDefault = vmeBuilder.getSkipResidualsBuffExpSize(8192, 4); EXPECT_EQ(size16x16, sizeDefault); } TEST_F(BuiltInTests, GivenInvalidBuiltinKernelNameWhenCreatingBuiltInProgramThenInvalidValueErrorIsReturned) { const char *kernelNames = "invalid_kernel"; cl_int retVal = CL_SUCCESS; cl_program program = Vme::createBuiltInProgram( *pContext, pContext->getDevices(), kernelNames, retVal); EXPECT_EQ(CL_INVALID_VALUE, retVal); EXPECT_EQ(nullptr, program); } TEST_F(BuiltInTests, WhenGettingSipKernelThenReturnProgramCreatedFromIsaAcquiredThroughCompilerInterface) { auto mockCompilerInterface = new MockCompilerInterface(); pDevice->getExecutionEnvironment()->rootDeviceEnvironments[rootDeviceIndex]->compilerInterface.reset(mockCompilerInterface); auto builtins = new BuiltIns; pDevice->getExecutionEnvironment()->rootDeviceEnvironments[rootDeviceIndex]->builtins.reset(builtins); mockCompilerInterface->sipKernelBinaryOverride = mockCompilerInterface->getDummyGenBinary(); const SipKernel &sipKernel = builtins->getSipKernel(SipKernelType::Csr, *pDevice); auto expectedMem = mockCompilerInterface->sipKernelBinaryOverride.data(); EXPECT_EQ(0, memcmp(expectedMem, sipKernel.getSipAllocation()->getUnderlyingBuffer(), mockCompilerInterface->sipKernelBinaryOverride.size())); EXPECT_EQ(SipKernelType::Csr, mockCompilerInterface->requestedSipKernel); mockCompilerInterface->releaseDummyGenBinary(); } TEST_F(BuiltInTests, givenSipKernelWhenItIsCreatedThenItHasGraphicsAllocationForKernel) { const SipKernel &sipKern = pDevice->getBuiltIns()->getSipKernel(SipKernelType::Csr, pContext->getDevice(0)->getDevice()); auto sipAllocation = sipKern.getSipAllocation(); EXPECT_NE(nullptr, sipAllocation); } TEST_F(BuiltInTests, givenSipKernelWhenAllocationFailsThenItHasNullptrGraphicsAllocation) { auto executionEnvironment = new MockExecutionEnvironment; executionEnvironment->prepareRootDeviceEnvironments(1); auto memoryManager = new MockMemoryManager(*executionEnvironment); executionEnvironment->memoryManager.reset(memoryManager); auto device = std::unique_ptr(Device::create(executionEnvironment, 0u)); EXPECT_NE(nullptr, device); memoryManager->failAllocate32Bit = true; auto builtins = std::make_unique(); const SipKernel &sipKern = builtins->getSipKernel(SipKernelType::Csr, *device); auto sipAllocation = sipKern.getSipAllocation(); EXPECT_EQ(nullptr, sipAllocation); } TEST_F(BuiltInTests, givenDebugFlagForceUseSourceWhenArgIsBinaryThenReturnBuiltinCodeBinary) { DebugManager.flags.RebuildPrecompiledKernels.set(true); auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Binary, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Binary, code.type); EXPECT_NE(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } TEST_F(BuiltInTests, givenDebugFlagForceUseSourceWhenArgIsAnyThenReturnBuiltinCodeSource) { DebugManager.flags.RebuildPrecompiledKernels.set(true); auto builtinsLib = std::unique_ptr(new BuiltinsLib()); BuiltinCode code = builtinsLib->getBuiltinCode(EBuiltInOps::CopyBufferToBuffer, BuiltinCode::ECodeType::Any, *pDevice); EXPECT_EQ(BuiltinCode::ECodeType::Source, code.type); EXPECT_NE(0u, code.resource.size()); EXPECT_EQ(pDevice, code.targetDevice); } using BuiltInOwnershipWrapperTests = BuiltInTests; TEST_F(BuiltInOwnershipWrapperTests, givenBuiltinWhenConstructedThenLockAndUnlockOnDestruction) { MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); MockContext context(pClDevice); { EXPECT_EQ(nullptr, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); BuiltInOwnershipWrapper lock(mockAuxBuiltInOp, &context); EXPECT_TRUE(mockAuxBuiltInOp.baseKernel->getMultiDeviceKernel()->hasOwnership()); EXPECT_TRUE(mockAuxBuiltInOp.baseKernel->getProgram()->hasOwnership()); EXPECT_EQ(&context, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); } EXPECT_FALSE(mockAuxBuiltInOp.baseKernel->getMultiDeviceKernel()->hasOwnership()); EXPECT_FALSE(mockAuxBuiltInOp.baseKernel->getProgram()->hasOwnership()); EXPECT_EQ(nullptr, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); } TEST_F(BuiltInOwnershipWrapperTests, givenLockWithoutParametersWhenConstructingThenLockOnlyWhenRequested) { MockAuxBuilInOp mockAuxBuiltInOp(*pBuiltIns, *pClDevice); MockContext context(pClDevice); { BuiltInOwnershipWrapper lock; EXPECT_EQ(nullptr, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); lock.takeOwnership(mockAuxBuiltInOp, &context); EXPECT_TRUE(mockAuxBuiltInOp.baseKernel->getMultiDeviceKernel()->hasOwnership()); EXPECT_TRUE(mockAuxBuiltInOp.baseKernel->getProgram()->hasOwnership()); EXPECT_EQ(&context, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); } EXPECT_FALSE(mockAuxBuiltInOp.baseKernel->getMultiDeviceKernel()->hasOwnership()); EXPECT_FALSE(mockAuxBuiltInOp.baseKernel->getProgram()->hasOwnership()); EXPECT_EQ(nullptr, mockAuxBuiltInOp.baseKernel->getProgram()->getContextPtr()); } TEST_F(BuiltInOwnershipWrapperTests, givenLockWithAcquiredOwnershipWhenTakeOwnershipCalledThenAbort) { MockAuxBuilInOp mockAuxBuiltInOp1(*pBuiltIns, *pClDevice); MockAuxBuilInOp mockAuxBuiltInOp2(*pBuiltIns, *pClDevice); MockContext context(pClDevice); BuiltInOwnershipWrapper lock(mockAuxBuiltInOp1, &context); EXPECT_THROW(lock.takeOwnership(mockAuxBuiltInOp1, &context), std::exception); EXPECT_THROW(lock.takeOwnership(mockAuxBuiltInOp2, &context), std::exception); } HWTEST_F(BuiltInOwnershipWrapperTests, givenBuiltInOwnershipWrapperWhenAskedForTypeTraitsThenDisableCopyConstructorAndOperator) { EXPECT_FALSE(std::is_copy_constructible::value); EXPECT_FALSE(std::is_copy_assignable::value); }