481 lines
21 KiB
C++
481 lines
21 KiB
C++
/*
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* Copyright (C) 2017-2019 Intel Corporation
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*
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* SPDX-License-Identifier: MIT
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*
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*/
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#include "runtime/built_ins/builtins_dispatch_builder.h"
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#include "runtime/memory_manager/allocations_list.h"
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#include "runtime/memory_manager/memory_manager.h"
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#include "test.h"
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#include "unit_tests/command_queue/enqueue_write_image_fixture.h"
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#include "unit_tests/gen_common/gen_commands_common_validation.h"
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#include "unit_tests/helpers/unit_test_helper.h"
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#include "unit_tests/mocks/mock_builtin_dispatch_info_builder.h"
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#include "reg_configs_common.h"
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using namespace OCLRT;
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HWCMDTEST_F(IGFX_GEN8_CORE, EnqueueWriteImageTest, gpgpuWalker) {
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typedef typename FamilyType::GPGPU_WALKER GPGPU_WALKER;
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enqueueWriteImage<FamilyType>();
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auto *cmd = reinterpret_cast<GPGPU_WALKER *>(cmdWalker);
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ASSERT_NE(nullptr, cmd);
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// Verify GPGPU_WALKER parameters
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EXPECT_NE(0u, cmd->getThreadGroupIdXDimension());
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EXPECT_NE(0u, cmd->getThreadGroupIdYDimension());
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EXPECT_NE(0u, cmd->getThreadGroupIdZDimension());
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EXPECT_NE(0u, cmd->getRightExecutionMask());
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EXPECT_NE(0u, cmd->getBottomExecutionMask());
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EXPECT_EQ(GPGPU_WALKER::SIMD_SIZE_SIMD32, cmd->getSimdSize());
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EXPECT_NE(0u, cmd->getIndirectDataLength());
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EXPECT_FALSE(cmd->getIndirectParameterEnable());
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// Compute the SIMD lane mask
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size_t simd =
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cmd->getSimdSize() == GPGPU_WALKER::SIMD_SIZE_SIMD32 ? 32 : cmd->getSimdSize() == GPGPU_WALKER::SIMD_SIZE_SIMD16 ? 16 : 8;
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uint64_t simdMask = (1ull << simd) - 1;
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// Mask off lanes based on the execution masks
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auto laneMaskRight = cmd->getRightExecutionMask() & simdMask;
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auto lanesPerThreadX = 0;
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while (laneMaskRight) {
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lanesPerThreadX += laneMaskRight & 1;
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laneMaskRight >>= 1;
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}
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}
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HWTEST_F(EnqueueWriteImageTest, alignsToCSR_Blocking) {
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//this test case assumes IOQ
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auto &csr = pDevice->getUltCommandStreamReceiver<FamilyType>();
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csr.taskCount = pCmdQ->taskCount + 100;
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csr.taskLevel = pCmdQ->taskLevel + 50;
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auto oldCsrTaskLevel = csr.peekTaskLevel();
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage, CL_TRUE);
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EXPECT_EQ(csr.peekTaskCount(), pCmdQ->taskCount);
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EXPECT_EQ(oldCsrTaskLevel, pCmdQ->taskLevel);
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}
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HWTEST_F(EnqueueWriteImageTest, alignsToCSR_NonBlocking) {
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//this test case assumes IOQ
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auto &csr = pDevice->getUltCommandStreamReceiver<FamilyType>();
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csr.taskCount = pCmdQ->taskCount + 100;
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csr.taskLevel = pCmdQ->taskLevel + 50;
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage, CL_FALSE);
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EXPECT_EQ(csr.peekTaskCount(), pCmdQ->taskCount);
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EXPECT_EQ(csr.peekTaskLevel(), pCmdQ->taskLevel + 1);
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}
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HWTEST_F(EnqueueWriteImageTest, bumpsTaskLevel) {
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auto taskLevelBefore = pCmdQ->taskLevel;
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage, EnqueueWriteImageTraits::blocking);
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EXPECT_GT(pCmdQ->taskLevel, taskLevelBefore);
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}
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HWTEST_F(EnqueueWriteImageTest, addsCommands) {
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auto usedCmdBufferBefore = pCS->getUsed();
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage, EnqueueWriteImageTraits::blocking);
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EXPECT_NE(usedCmdBufferBefore, pCS->getUsed());
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}
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HWTEST_F(EnqueueWriteImageTest, addsIndirectData) {
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auto dshBefore = pDSH->getUsed();
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auto iohBefore = pIOH->getUsed();
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auto sshBefore = pSSH->getUsed();
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage, EnqueueWriteImageTraits::blocking);
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EXPECT_TRUE(UnitTestHelper<FamilyType>::evaluateDshUsage(dshBefore, pDSH->getUsed(), nullptr));
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EXPECT_NE(iohBefore, pIOH->getUsed());
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EXPECT_NE(sshBefore, pSSH->getUsed());
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}
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HWTEST_F(EnqueueWriteImageTest, loadRegisterImmediateL3CNTLREG) {
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enqueueWriteImage<FamilyType>();
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validateL3Programming<FamilyType>(cmdList, itorWalker);
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}
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HWCMDTEST_F(IGFX_GEN8_CORE, EnqueueWriteImageTest, WhenEnqueueIsDoneThenStateBaseAddressIsProperlyProgrammed) {
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enqueueWriteImage<FamilyType>();
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validateStateBaseAddress<FamilyType>(this->pCmdQ->getCommandStreamReceiver().getMemoryManager()->getInternalHeapBaseAddress(),
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pDSH, pIOH, pSSH, itorPipelineSelect, itorWalker, cmdList, 0llu);
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}
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HWCMDTEST_F(IGFX_GEN8_CORE, EnqueueWriteImageTest, mediaInterfaceDescriptorLoad) {
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typedef typename FamilyType::MEDIA_INTERFACE_DESCRIPTOR_LOAD MEDIA_INTERFACE_DESCRIPTOR_LOAD;
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typedef typename FamilyType::INTERFACE_DESCRIPTOR_DATA INTERFACE_DESCRIPTOR_DATA;
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enqueueWriteImage<FamilyType>();
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// All state should be programmed before walker
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auto cmd = reinterpret_cast<MEDIA_INTERFACE_DESCRIPTOR_LOAD *>(cmdMediaInterfaceDescriptorLoad);
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ASSERT_NE(nullptr, cmd);
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// Verify we have a valid length -- multiple of INTERFACE_DESCRIPTOR_DATAs
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EXPECT_EQ(0u, cmd->getInterfaceDescriptorTotalLength() % sizeof(INTERFACE_DESCRIPTOR_DATA));
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// Validate the start address
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size_t alignmentStartAddress = 64 * sizeof(uint8_t);
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EXPECT_EQ(0u, cmd->getInterfaceDescriptorDataStartAddress() % alignmentStartAddress);
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// Validate the length
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EXPECT_NE(0u, cmd->getInterfaceDescriptorTotalLength());
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size_t alignmentTotalLength = 32 * sizeof(uint8_t);
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EXPECT_EQ(0u, cmd->getInterfaceDescriptorTotalLength() % alignmentTotalLength);
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// Generically validate this command
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FamilyType::PARSE::template validateCommand<MEDIA_INTERFACE_DESCRIPTOR_LOAD *>(cmdList.begin(), itorMediaInterfaceDescriptorLoad);
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}
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HWCMDTEST_F(IGFX_GEN8_CORE, EnqueueWriteImageTest, interfaceDescriptorData) {
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typedef typename FamilyType::STATE_BASE_ADDRESS STATE_BASE_ADDRESS;
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typedef typename FamilyType::INTERFACE_DESCRIPTOR_DATA INTERFACE_DESCRIPTOR_DATA;
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enqueueWriteImage<FamilyType>();
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// Extract the interfaceDescriptorData
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auto cmdSBA = (STATE_BASE_ADDRESS *)cmdStateBaseAddress;
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auto &interfaceDescriptorData = *(INTERFACE_DESCRIPTOR_DATA *)cmdInterfaceDescriptorData;
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// Validate the kernel start pointer. Technically, a kernel can start at address 0 but let's force a value.
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auto kernelStartPointer = ((uint64_t)interfaceDescriptorData.getKernelStartPointerHigh() << 32) + interfaceDescriptorData.getKernelStartPointer();
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EXPECT_LE(kernelStartPointer, cmdSBA->getInstructionBufferSize() * MemoryConstants::pageSize);
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// EnqueueWriteImage uses a byte copy. Need to convert to bytes.
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auto localWorkSize = 2 * 2 * sizeof(float);
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auto simd = 32;
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auto threadsPerThreadGroup = (localWorkSize + simd - 1) / simd;
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EXPECT_EQ(threadsPerThreadGroup, interfaceDescriptorData.getNumberOfThreadsInGpgpuThreadGroup());
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EXPECT_NE(0u, interfaceDescriptorData.getCrossThreadConstantDataReadLength());
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EXPECT_NE(0u, interfaceDescriptorData.getConstantIndirectUrbEntryReadLength());
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// We shouldn't have these pointers the same.
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EXPECT_NE(kernelStartPointer, interfaceDescriptorData.getBindingTablePointer());
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}
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HWTEST_F(EnqueueWriteImageTest, surfaceState) {
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typedef typename FamilyType::RENDER_SURFACE_STATE RENDER_SURFACE_STATE;
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enqueueWriteImage<FamilyType>();
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// BufferToImage kernel uses BTI=1 for destSurface
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uint32_t bindingTableIndex = 1;
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const auto &surfaceState = getSurfaceState<FamilyType>(&pCmdQ->getIndirectHeap(IndirectHeap::SURFACE_STATE, 0), bindingTableIndex);
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// EnqueueWriteImage uses multi-byte copies depending on per-pixel-size-in-bytes
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const auto &imageDesc = dstImage->getImageDesc();
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EXPECT_EQ(imageDesc.image_width, surfaceState.getWidth());
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EXPECT_EQ(imageDesc.image_height, surfaceState.getHeight());
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EXPECT_NE(0u, surfaceState.getSurfacePitch());
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EXPECT_NE(0u, surfaceState.getSurfaceType());
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EXPECT_EQ(RENDER_SURFACE_STATE::SURFACE_FORMAT_R32_UINT, surfaceState.getSurfaceFormat());
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EXPECT_EQ(RENDER_SURFACE_STATE::SURFACE_HORIZONTAL_ALIGNMENT_HALIGN_4, surfaceState.getSurfaceHorizontalAlignment());
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EXPECT_EQ(RENDER_SURFACE_STATE::SURFACE_VERTICAL_ALIGNMENT_VALIGN_4, surfaceState.getSurfaceVerticalAlignment());
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EXPECT_EQ(reinterpret_cast<uint64_t>(dstImage->getCpuAddress()), surfaceState.getSurfaceBaseAddress());
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}
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HWTEST_F(EnqueueWriteImageTest, pipelineSelect) {
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enqueueWriteImage<FamilyType>();
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int numCommands = getNumberOfPipelineSelectsThatEnablePipelineSelect<FamilyType>();
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EXPECT_EQ(1, numCommands);
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}
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HWCMDTEST_F(IGFX_GEN8_CORE, EnqueueWriteImageTest, mediaVFEState) {
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enqueueWriteImage<FamilyType>();
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validateMediaVFEState<FamilyType>(&pDevice->getHardwareInfo(), cmdMediaVfeState, cmdList, itorMediaVfeState);
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}
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HWTEST_F(EnqueueWriteImageTest, GivenImage1DarrayWhenReadWriteImageIsCalledThenHostPtrSizeIsCalculatedProperly) {
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auto dstImage2 = Image1dArrayHelper<>::create(context);
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auto imageDesc = dstImage2->getImageDesc();
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auto imageSize = imageDesc.image_width * imageDesc.image_array_size * 4;
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size_t origin[] = {0, 0, 0};
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size_t region[] = {imageDesc.image_width, imageDesc.image_array_size, 1};
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage2, CL_FALSE, origin, region);
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auto &csr = pCmdQ->getCommandStreamReceiver();
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auto temporaryAllocation1 = csr.getTemporaryAllocations().peekHead();
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ASSERT_NE(nullptr, temporaryAllocation1);
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EXPECT_EQ(temporaryAllocation1->getUnderlyingBufferSize(), imageSize);
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EnqueueReadImageHelper<>::enqueueReadImage(pCmdQ, dstImage2, CL_FALSE, origin, region);
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auto temporaryAllocation2 = temporaryAllocation1->next;
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ASSERT_NE(nullptr, temporaryAllocation2);
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EXPECT_EQ(temporaryAllocation2->getUnderlyingBufferSize(), imageSize);
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delete dstImage2;
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}
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HWTEST_F(EnqueueWriteImageTest, GivenImage2DarrayWhenReadWriteImageIsCalledThenHostPtrSizeIsCalculatedProperly) {
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auto dstImage2 = Image2dArrayHelper<>::create(context);
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auto imageDesc = dstImage2->getImageDesc();
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auto imageSize = imageDesc.image_width * imageDesc.image_height * imageDesc.image_array_size * 4;
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size_t origin[] = {0, 0, 0};
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size_t region[] = {imageDesc.image_width, imageDesc.image_height, imageDesc.image_array_size};
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EnqueueWriteImageHelper<>::enqueueWriteImage(pCmdQ, dstImage2, CL_FALSE, origin, region);
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auto &csr = pCmdQ->getCommandStreamReceiver();
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auto temporaryAllocation1 = csr.getTemporaryAllocations().peekHead();
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ASSERT_NE(nullptr, temporaryAllocation1);
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EXPECT_EQ(temporaryAllocation1->getUnderlyingBufferSize(), imageSize);
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EnqueueReadImageHelper<>::enqueueReadImage(pCmdQ, dstImage, CL_FALSE, origin, region);
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auto temporaryAllocation2 = temporaryAllocation1->next;
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ASSERT_NE(nullptr, temporaryAllocation2);
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EXPECT_EQ(temporaryAllocation1->getUnderlyingBufferSize(), imageSize);
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delete dstImage2;
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}
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HWTEST_F(EnqueueWriteImageTest, GivenImage1DAndImageShareTheSameStorageWithHostPtrWhenReadWriteImageIsCalledThenImageIsNotWritten) {
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cl_int retVal = CL_SUCCESS;
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std::unique_ptr<Image> dstImage2(Image1dHelper<>::create(context));
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auto imageDesc = dstImage2->getImageDesc();
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std::unique_ptr<CommandQueue> pCmdOOQ(createCommandQueue(pDevice, CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE));
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size_t origin[] = {0, 0, 0};
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size_t region[] = {imageDesc.image_width, 1, 1};
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void *ptr = dstImage2->getCpuAddressForMemoryTransfer();
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size_t rowPitch = dstImage2->getHostPtrRowPitch();
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size_t slicePitch = dstImage2->getHostPtrSlicePitch();
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retVal = pCmdOOQ->enqueueWriteImage(dstImage2.get(),
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CL_FALSE,
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origin,
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region,
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rowPitch,
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slicePitch,
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ptr,
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0,
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nullptr,
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nullptr);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(pCmdOOQ->taskLevel, 0u);
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}
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HWTEST_F(EnqueueWriteImageTest, GivenImage1DArrayAndImageShareTheSameStorageWithHostPtrWhenReadWriteImageIsCalledThenImageIsNotWritten) {
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cl_int retVal = CL_SUCCESS;
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std::unique_ptr<Image> dstImage2(Image1dArrayHelper<>::create(context));
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auto imageDesc = dstImage2->getImageDesc();
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size_t origin[] = {imageDesc.image_width / 2, imageDesc.image_array_size / 2, 0};
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size_t region[] = {imageDesc.image_width - (imageDesc.image_width / 2), imageDesc.image_array_size - (imageDesc.image_array_size / 2), 1};
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void *ptr = dstImage2->getCpuAddressForMemoryTransfer();
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auto bytesPerPixel = 4;
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size_t rowPitch = dstImage2->getHostPtrRowPitch();
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size_t slicePitch = dstImage2->getHostPtrSlicePitch();
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auto pOffset = origin[2] * rowPitch + origin[1] * slicePitch + origin[0] * bytesPerPixel;
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void *ptrStorage = ptrOffset(ptr, pOffset);
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retVal = pCmdQ->enqueueWriteImage(dstImage2.get(),
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CL_FALSE,
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origin,
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region,
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rowPitch,
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slicePitch,
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ptrStorage,
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0,
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nullptr,
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nullptr);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(pCmdQ->taskLevel, 0u);
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}
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HWTEST_F(EnqueueWriteImageTest, GivenSharedContextZeroCopy2DImageWhenEnqueueWriteImageWithMappedPointerIsCalledThenImageIsNotWritten) {
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cl_int retVal = CL_SUCCESS;
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context->isSharedContext = true;
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std::unique_ptr<Image> dstImage(ImageHelper<ImageUseHostPtr<Image2dDefaults>>::create(context));
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EXPECT_TRUE(dstImage->isMemObjZeroCopy());
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auto imageDesc = dstImage->getImageDesc();
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size_t origin[] = {0, 0, 0};
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size_t region[] = {imageDesc.image_width, imageDesc.image_height, 1};
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void *ptr = dstImage->getCpuAddressForMemoryTransfer();
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size_t rowPitch = dstImage->getHostPtrRowPitch();
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size_t slicePitch = dstImage->getHostPtrSlicePitch();
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retVal = pCmdQ->enqueueReadImage(dstImage.get(),
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CL_FALSE,
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origin,
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region,
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rowPitch,
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slicePitch,
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ptr,
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0,
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nullptr,
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nullptr);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(pCmdQ->taskLevel, 0u);
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}
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HWTEST_F(EnqueueWriteImageTest, GivenImage1DThatIsZeroCopyWhenWriteImageWithTheSamePointerAndOutputEventIsPassedThenEventHasCorrectCommandTypeSet) {
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cl_int retVal = CL_SUCCESS;
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std::unique_ptr<Image> srcImage(Image1dHelper<>::create(context));
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auto imageDesc = srcImage->getImageDesc();
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size_t origin[] = {0, 0, 0};
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size_t region[] = {imageDesc.image_width, imageDesc.image_height, 1};
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void *ptr = srcImage->getCpuAddressForMemoryTransfer();
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size_t rowPitch = srcImage->getHostPtrRowPitch();
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size_t slicePitch = srcImage->getHostPtrSlicePitch();
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cl_uint numEventsInWaitList = 0;
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cl_event event = nullptr;
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retVal = pCmdQ->enqueueWriteImage(srcImage.get(),
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CL_FALSE,
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origin,
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region,
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rowPitch,
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slicePitch,
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ptr,
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numEventsInWaitList,
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nullptr,
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&event);
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EXPECT_EQ(CL_SUCCESS, retVal);
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EXPECT_EQ(CL_SUCCESS, retVal);
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ASSERT_NE(nullptr, event);
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auto pEvent = static_cast<Event *>(event);
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EXPECT_EQ(static_cast<cl_command_type>(CL_COMMAND_WRITE_IMAGE), pEvent->getCommandType());
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pEvent->release();
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}
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typedef EnqueueWriteImageMipMapTest MipMapWriteImageTest;
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HWTEST_P(MipMapWriteImageTest, GivenImageWithMipLevelNonZeroWhenReadImageIsCalledThenProperMipLevelIsSet) {
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auto image_type = (cl_mem_object_type)GetParam();
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auto &builtIns = *pCmdQ->getDevice().getExecutionEnvironment()->getBuiltIns();
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auto &origBuilder = builtIns.getBuiltinDispatchInfoBuilder(
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EBuiltInOps::CopyBufferToImage3d,
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pCmdQ->getContext(),
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pCmdQ->getDevice());
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// substitute original builder with mock builder
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auto oldBuilder = builtIns.setBuiltinDispatchInfoBuilder(
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EBuiltInOps::CopyBufferToImage3d,
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pCmdQ->getContext(),
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pCmdQ->getDevice(),
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std::unique_ptr<OCLRT::BuiltinDispatchInfoBuilder>(new MockBuiltinDispatchInfoBuilder(builtIns, &origBuilder)));
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cl_int retVal = CL_SUCCESS;
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cl_image_desc imageDesc = {};
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uint32_t expectedMipLevel = 3;
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imageDesc.image_type = image_type;
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imageDesc.num_mip_levels = 10;
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imageDesc.image_width = 4;
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imageDesc.image_height = 1;
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imageDesc.image_depth = 1;
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size_t origin[] = {0, 0, 0, 0};
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size_t region[] = {imageDesc.image_width, 1, 1};
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std::unique_ptr<Image> image;
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switch (image_type) {
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case CL_MEM_OBJECT_IMAGE1D:
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origin[1] = expectedMipLevel;
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image = std::unique_ptr<Image>(ImageHelper<Image1dDefaults>::create(context, &imageDesc));
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break;
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case CL_MEM_OBJECT_IMAGE1D_ARRAY:
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imageDesc.image_array_size = 2;
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origin[2] = expectedMipLevel;
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image = std::unique_ptr<Image>(ImageHelper<Image1dArrayDefaults>::create(context, &imageDesc));
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break;
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case CL_MEM_OBJECT_IMAGE2D:
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origin[2] = expectedMipLevel;
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image = std::unique_ptr<Image>(ImageHelper<Image2dDefaults>::create(context, &imageDesc));
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break;
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case CL_MEM_OBJECT_IMAGE2D_ARRAY:
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imageDesc.image_array_size = 2;
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origin[3] = expectedMipLevel;
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image = std::unique_ptr<Image>(ImageHelper<Image2dArrayDefaults>::create(context, &imageDesc));
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break;
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case CL_MEM_OBJECT_IMAGE3D:
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origin[3] = expectedMipLevel;
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image = std::unique_ptr<Image>(ImageHelper<Image3dDefaults>::create(context, &imageDesc));
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break;
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}
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EXPECT_NE(nullptr, image.get());
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auto hostPtrSize = Image::calculateHostPtrSize(region, image->getHostPtrRowPitch(), image->getHostPtrSlicePitch(),
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image->getSurfaceFormatInfo().ImageElementSizeInBytes, image_type);
|
|
std::unique_ptr<uint32_t[]> ptr = std::unique_ptr<uint32_t[]>(new uint32_t[hostPtrSize]);
|
|
|
|
retVal = pCmdQ->enqueueWriteImage(image.get(),
|
|
CL_FALSE,
|
|
origin,
|
|
region,
|
|
0,
|
|
0,
|
|
ptr.get(),
|
|
0,
|
|
nullptr,
|
|
nullptr);
|
|
|
|
EXPECT_EQ(CL_SUCCESS, retVal);
|
|
|
|
auto &mockBuilder = static_cast<MockBuiltinDispatchInfoBuilder &>(builtIns.getBuiltinDispatchInfoBuilder(EBuiltInOps::CopyBufferToImage3d,
|
|
pCmdQ->getContext(),
|
|
pCmdQ->getDevice()));
|
|
auto params = mockBuilder.getBuiltinOpParams();
|
|
|
|
EXPECT_EQ(expectedMipLevel, params->dstMipLevel);
|
|
|
|
// restore original builder and retrieve mock builder
|
|
auto newBuilder = builtIns.setBuiltinDispatchInfoBuilder(
|
|
EBuiltInOps::CopyBufferToImage3d,
|
|
pCmdQ->getContext(),
|
|
pCmdQ->getDevice(),
|
|
std::move(oldBuilder));
|
|
EXPECT_NE(nullptr, newBuilder);
|
|
}
|
|
|
|
INSTANTIATE_TEST_CASE_P(MipMapWriteImageTest_GivenImageWithMipLevelNonZeroWhenReadImageIsCalledThenProperMipLevelIsSet,
|
|
MipMapWriteImageTest, ::testing::Values(CL_MEM_OBJECT_IMAGE1D, CL_MEM_OBJECT_IMAGE1D_ARRAY, CL_MEM_OBJECT_IMAGE2D, CL_MEM_OBJECT_IMAGE2D_ARRAY, CL_MEM_OBJECT_IMAGE3D));
|
|
|
|
using NegativeFailAllocationTest = Test<NegativeFailAllocationCommandEnqueueBaseFixture>;
|
|
|
|
HWTEST_F(NegativeFailAllocationTest, givenEnqueueReadImageWhenHostPtrAllocationCreationFailsThenReturnOutOfResource) {
|
|
cl_int retVal = CL_SUCCESS;
|
|
auto imageDesc = image->getImageDesc();
|
|
|
|
size_t origin[] = {0, 0, 0};
|
|
size_t region[] = {imageDesc.image_width, imageDesc.image_height, 1};
|
|
|
|
size_t rowPitch = image->getHostPtrRowPitch();
|
|
size_t slicePitch = image->getHostPtrSlicePitch();
|
|
|
|
retVal = pCmdQ->enqueueReadImage(image.get(),
|
|
CL_FALSE,
|
|
origin,
|
|
region,
|
|
rowPitch,
|
|
slicePitch,
|
|
ptr,
|
|
0,
|
|
nullptr,
|
|
nullptr);
|
|
|
|
EXPECT_EQ(CL_OUT_OF_RESOURCES, retVal);
|
|
}
|