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// Copyright 2019 The Dawn Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "common/Math.h"
#include "tests/DawnTest.h"
#include "common/vulkan_platform.h"
#include "dawn_native/VulkanBackend.h"
#include "dawn_native/vulkan/AdapterVk.h"
#include "dawn_native/vulkan/DeviceVk.h"
#include "dawn_native/vulkan/FencedDeleter.h"
#include "dawn_native/vulkan/ResourceMemoryAllocatorVk.h"
#include "dawn_native/vulkan/TextureVk.h"
#include "utils/SystemUtils.h"
#include "utils/WGPUHelpers.h"
namespace dawn_native { namespace vulkan {
namespace {
class VulkanImageWrappingTestBase : public DawnTest {
public:
void SetUp() override {
DawnTest::SetUp();
DAWN_SKIP_TEST_IF(UsesWire());
deviceVk = reinterpret_cast<dawn_native::vulkan::Device*>(device.Get());
}
// Creates a VkImage with external memory
::VkResult CreateImage(dawn_native::vulkan::Device* deviceVk,
uint32_t width,
uint32_t height,
VkFormat format,
VkImage* image) {
VkExternalMemoryImageCreateInfoKHR externalInfo;
externalInfo.sType = VK_STRUCTURE_TYPE_EXTERNAL_MEMORY_IMAGE_CREATE_INFO_KHR;
externalInfo.pNext = nullptr;
externalInfo.handleTypes = VK_EXTERNAL_MEMORY_HANDLE_TYPE_OPAQUE_FD_BIT_KHR;
auto usage = VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT |
VK_IMAGE_USAGE_TRANSFER_DST_BIT;
VkImageCreateInfo createInfo;
createInfo.sType = VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO;
createInfo.pNext = &externalInfo;
createInfo.flags = VK_IMAGE_CREATE_ALIAS_BIT_KHR;
createInfo.imageType = VK_IMAGE_TYPE_2D;
createInfo.format = format;
createInfo.extent = {width, height, 1};
createInfo.mipLevels = 1;
createInfo.arrayLayers = 1;
createInfo.samples = VK_SAMPLE_COUNT_1_BIT;
createInfo.tiling = VK_IMAGE_TILING_OPTIMAL;
createInfo.usage = usage;
createInfo.sharingMode = VK_SHARING_MODE_EXCLUSIVE;
createInfo.queueFamilyIndexCount = 0;
createInfo.pQueueFamilyIndices = nullptr;
createInfo.initialLayout = VK_IMAGE_LAYOUT_UNDEFINED;
return deviceVk->fn.CreateImage(deviceVk->GetVkDevice(), &createInfo, nullptr,
&**image);
}
// Allocates memory for an image
::VkResult AllocateMemory(dawn_native::vulkan::Device* deviceVk,
VkImage handle,
VkDeviceMemory* allocation,
VkDeviceSize* allocationSize,
uint32_t* memoryTypeIndex) {
// Create the image memory and associate it with the container
VkMemoryRequirements requirements;
deviceVk->fn.GetImageMemoryRequirements(deviceVk->GetVkDevice(), handle,
&requirements);
// Import memory from file descriptor
VkExportMemoryAllocateInfoKHR externalInfo;
externalInfo.sType = VK_STRUCTURE_TYPE_EXPORT_MEMORY_ALLOCATE_INFO_KHR;
externalInfo.pNext = nullptr;
externalInfo.handleTypes = VK_EXTERNAL_MEMORY_HANDLE_TYPE_OPAQUE_FD_BIT_KHR;
int bestType = deviceVk->GetResourceMemoryAllocatorForTesting()->FindBestTypeIndex(
requirements, false);
VkMemoryAllocateInfo allocateInfo;
allocateInfo.sType = VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO;
allocateInfo.pNext = &externalInfo;
allocateInfo.allocationSize = requirements.size;
allocateInfo.memoryTypeIndex = static_cast<uint32_t>(bestType);
*allocationSize = allocateInfo.allocationSize;
*memoryTypeIndex = allocateInfo.memoryTypeIndex;
return deviceVk->fn.AllocateMemory(deviceVk->GetVkDevice(), &allocateInfo, nullptr,
&**allocation);
}
// Binds memory to an image
::VkResult BindMemory(dawn_native::vulkan::Device* deviceVk,
VkImage handle,
VkDeviceMemory* memory) {
return deviceVk->fn.BindImageMemory(deviceVk->GetVkDevice(), handle, *memory, 0);
}
// Extracts a file descriptor representing memory on a device
int GetMemoryFd(dawn_native::vulkan::Device* deviceVk, VkDeviceMemory memory) {
VkMemoryGetFdInfoKHR getFdInfo;
getFdInfo.sType = VK_STRUCTURE_TYPE_MEMORY_GET_FD_INFO_KHR;
getFdInfo.pNext = nullptr;
getFdInfo.memory = memory;
getFdInfo.handleType = VK_EXTERNAL_MEMORY_HANDLE_TYPE_OPAQUE_FD_BIT_KHR;
int memoryFd = -1;
deviceVk->fn.GetMemoryFdKHR(deviceVk->GetVkDevice(), &getFdInfo, &memoryFd);
EXPECT_GE(memoryFd, 0) << "Failed to get file descriptor for external memory";
return memoryFd;
}
// Prepares and exports memory for an image on a given device
void CreateBindExportImage(dawn_native::vulkan::Device* deviceVk,
uint32_t width,
uint32_t height,
VkFormat format,
VkImage* handle,
VkDeviceMemory* allocation,
VkDeviceSize* allocationSize,
uint32_t* memoryTypeIndex,
int* memoryFd) {
::VkResult result = CreateImage(deviceVk, width, height, format, handle);
EXPECT_EQ(result, VK_SUCCESS) << "Failed to create external image";
::VkResult resultBool =
AllocateMemory(deviceVk, *handle, allocation, allocationSize, memoryTypeIndex);
EXPECT_EQ(resultBool, VK_SUCCESS) << "Failed to allocate external memory";
result = BindMemory(deviceVk, *handle, allocation);
EXPECT_EQ(result, VK_SUCCESS) << "Failed to bind image memory";
*memoryFd = GetMemoryFd(deviceVk, *allocation);
}
// Wraps a vulkan image from external memory
wgpu::Texture WrapVulkanImage(wgpu::Device dawnDevice,
const wgpu::TextureDescriptor* textureDescriptor,
int memoryFd,
VkDeviceSize allocationSize,
uint32_t memoryTypeIndex,
std::vector<int> waitFDs,
bool isCleared = true,
bool expectValid = true) {
dawn_native::vulkan::ExternalImageDescriptorOpaqueFD descriptor;
descriptor.cTextureDescriptor =
reinterpret_cast<const WGPUTextureDescriptor*>(textureDescriptor);
descriptor.isCleared = isCleared;
descriptor.allocationSize = allocationSize;
descriptor.memoryTypeIndex = memoryTypeIndex;
descriptor.memoryFD = memoryFd;
descriptor.waitFDs = waitFDs;
WGPUTexture texture =
dawn_native::vulkan::WrapVulkanImage(dawnDevice.Get(), &descriptor);
if (expectValid) {
EXPECT_NE(texture, nullptr) << "Failed to wrap image, are external memory / "
"semaphore extensions supported?";
} else {
EXPECT_EQ(texture, nullptr);
}
return wgpu::Texture::Acquire(texture);
}
// Exports the signal from a wrapped texture and ignores it
// We have to export the signal before destroying the wrapped texture else it's an
// assertion failure
void IgnoreSignalSemaphore(wgpu::Device dawnDevice, wgpu::Texture wrappedTexture) {
int fd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(dawnDevice.Get(),
wrappedTexture.Get());
ASSERT_NE(fd, -1);
close(fd);
}
protected:
dawn_native::vulkan::Device* deviceVk;
};
} // anonymous namespace
class VulkanImageWrappingValidationTests : public VulkanImageWrappingTestBase {
public:
void SetUp() override {
VulkanImageWrappingTestBase::SetUp();
if (UsesWire()) {
return;
}
CreateBindExportImage(deviceVk, 1, 1, VK_FORMAT_R8G8B8A8_UNORM, &defaultImage,
&defaultAllocation, &defaultAllocationSize,
&defaultMemoryTypeIndex, &defaultFd);
defaultDescriptor.dimension = wgpu::TextureDimension::e2D;
defaultDescriptor.format = wgpu::TextureFormat::RGBA8Unorm;
defaultDescriptor.size = {1, 1, 1};
defaultDescriptor.sampleCount = 1;
defaultDescriptor.arrayLayerCount = 1;
defaultDescriptor.mipLevelCount = 1;
defaultDescriptor.usage = wgpu::TextureUsage::OutputAttachment |
wgpu::TextureUsage::CopySrc | wgpu::TextureUsage::CopyDst;
}
void TearDown() override {
if (UsesWire()) {
VulkanImageWrappingTestBase::TearDown();
return;
}
deviceVk->GetFencedDeleter()->DeleteWhenUnused(defaultImage);
deviceVk->GetFencedDeleter()->DeleteWhenUnused(defaultAllocation);
VulkanImageWrappingTestBase::TearDown();
}
protected:
wgpu::TextureDescriptor defaultDescriptor;
VkImage defaultImage;
VkDeviceMemory defaultAllocation;
VkDeviceSize defaultAllocationSize;
uint32_t defaultMemoryTypeIndex;
int defaultFd;
};
// Test no error occurs if the import is valid
TEST_P(VulkanImageWrappingValidationTests, SuccessfulImport) {
DAWN_SKIP_TEST_IF(UsesWire());
wgpu::Texture texture =
WrapVulkanImage(device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, true);
EXPECT_NE(texture.Get(), nullptr);
IgnoreSignalSemaphore(device, texture);
}
// Test an error occurs if the texture descriptor is missing
TEST_P(VulkanImageWrappingValidationTests, MissingTextureDescriptor) {
DAWN_SKIP_TEST_IF(UsesWire());
ASSERT_DEVICE_ERROR(wgpu::Texture texture =
WrapVulkanImage(device, nullptr, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if the texture descriptor is invalid
TEST_P(VulkanImageWrappingValidationTests, InvalidTextureDescriptor) {
DAWN_SKIP_TEST_IF(UsesWire());
wgpu::ChainedStruct chainedDescriptor;
defaultDescriptor.nextInChain = &chainedDescriptor;
ASSERT_DEVICE_ERROR(wgpu::Texture texture = WrapVulkanImage(
device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if the descriptor dimension isn't 2D
TEST_P(VulkanImageWrappingValidationTests, InvalidTextureDimension) {
DAWN_SKIP_TEST_IF(UsesWire());
defaultDescriptor.dimension = wgpu::TextureDimension::e1D;
ASSERT_DEVICE_ERROR(wgpu::Texture texture = WrapVulkanImage(
device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if the descriptor mip level count isn't 1
TEST_P(VulkanImageWrappingValidationTests, InvalidMipLevelCount) {
DAWN_SKIP_TEST_IF(UsesWire());
defaultDescriptor.mipLevelCount = 2;
ASSERT_DEVICE_ERROR(wgpu::Texture texture = WrapVulkanImage(
device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if the descriptor array layer count isn't 1
TEST_P(VulkanImageWrappingValidationTests, InvalidArrayLayerCount) {
DAWN_SKIP_TEST_IF(UsesWire());
defaultDescriptor.arrayLayerCount = 2;
ASSERT_DEVICE_ERROR(wgpu::Texture texture = WrapVulkanImage(
device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if the descriptor sample count isn't 1
TEST_P(VulkanImageWrappingValidationTests, InvalidSampleCount) {
DAWN_SKIP_TEST_IF(UsesWire());
defaultDescriptor.sampleCount = 4;
ASSERT_DEVICE_ERROR(wgpu::Texture texture = WrapVulkanImage(
device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, false));
EXPECT_EQ(texture.Get(), nullptr);
}
// Test an error occurs if we try to export the signal semaphore twice
TEST_P(VulkanImageWrappingValidationTests, DoubleSignalSemaphoreExport) {
DAWN_SKIP_TEST_IF(UsesWire());
wgpu::Texture texture =
WrapVulkanImage(device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {}, true, true);
ASSERT_NE(texture.Get(), nullptr);
IgnoreSignalSemaphore(device, texture);
ASSERT_DEVICE_ERROR(int fd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
device.Get(), texture.Get()));
ASSERT_EQ(fd, -1);
}
// Test an error occurs if we try to export the signal semaphore from a normal texture
TEST_P(VulkanImageWrappingValidationTests, NormalTextureSignalSemaphoreExport) {
DAWN_SKIP_TEST_IF(UsesWire());
wgpu::Texture texture = device.CreateTexture(&defaultDescriptor);
ASSERT_NE(texture.Get(), nullptr);
ASSERT_DEVICE_ERROR(int fd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
device.Get(), texture.Get()));
ASSERT_EQ(fd, -1);
}
// Test an error occurs if we try to export the signal semaphore from a destroyed texture
TEST_P(VulkanImageWrappingValidationTests, DestroyedTextureSignalSemaphoreExport) {
DAWN_SKIP_TEST_IF(UsesWire());
wgpu::Texture texture = device.CreateTexture(&defaultDescriptor);
ASSERT_NE(texture.Get(), nullptr);
texture.Destroy();
ASSERT_DEVICE_ERROR(int fd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
device.Get(), texture.Get()));
ASSERT_EQ(fd, -1);
}
// Fixture to test using external memory textures through different usages.
// These tests are skipped if the harness is using the wire.
class VulkanImageWrappingUsageTests : public VulkanImageWrappingTestBase {
public:
void SetUp() override {
VulkanImageWrappingTestBase::SetUp();
if (UsesWire()) {
return;
}
// Create another device based on the original
backendAdapter =
reinterpret_cast<dawn_native::vulkan::Adapter*>(deviceVk->GetAdapter());
deviceDescriptor.forceEnabledToggles = GetParam().forceEnabledWorkarounds;
deviceDescriptor.forceDisabledToggles = GetParam().forceDisabledWorkarounds;
secondDeviceVk = reinterpret_cast<dawn_native::vulkan::Device*>(
backendAdapter->CreateDevice(&deviceDescriptor));
secondDevice = wgpu::Device::Acquire(reinterpret_cast<WGPUDevice>(secondDeviceVk));
CreateBindExportImage(deviceVk, 1, 1, VK_FORMAT_R8G8B8A8_UNORM, &defaultImage,
&defaultAllocation, &defaultAllocationSize,
&defaultMemoryTypeIndex, &defaultFd);
defaultDescriptor.dimension = wgpu::TextureDimension::e2D;
defaultDescriptor.format = wgpu::TextureFormat::RGBA8Unorm;
defaultDescriptor.size = {1, 1, 1};
defaultDescriptor.sampleCount = 1;
defaultDescriptor.arrayLayerCount = 1;
defaultDescriptor.mipLevelCount = 1;
defaultDescriptor.usage = wgpu::TextureUsage::OutputAttachment |
wgpu::TextureUsage::CopySrc | wgpu::TextureUsage::CopyDst;
}
void TearDown() override {
if (UsesWire()) {
VulkanImageWrappingTestBase::TearDown();
return;
}
deviceVk->GetFencedDeleter()->DeleteWhenUnused(defaultImage);
deviceVk->GetFencedDeleter()->DeleteWhenUnused(defaultAllocation);
VulkanImageWrappingTestBase::TearDown();
}
protected:
wgpu::Device secondDevice;
dawn_native::vulkan::Device* secondDeviceVk;
dawn_native::vulkan::Adapter* backendAdapter;
dawn_native::DeviceDescriptor deviceDescriptor;
wgpu::TextureDescriptor defaultDescriptor;
VkImage defaultImage;
VkDeviceMemory defaultAllocation;
VkDeviceSize defaultAllocationSize;
uint32_t defaultMemoryTypeIndex;
int defaultFd;
// Clear a texture on a given device
void ClearImage(wgpu::Device dawnDevice,
wgpu::Texture wrappedTexture,
wgpu::Color clearColor) {
wgpu::TextureView wrappedView = wrappedTexture.CreateView();
// Submit a clear operation
utils::ComboRenderPassDescriptor renderPassDescriptor({wrappedView}, {});
renderPassDescriptor.cColorAttachments[0].clearColor = clearColor;
wgpu::CommandEncoder encoder = dawnDevice.CreateCommandEncoder();
wgpu::RenderPassEncoder pass = encoder.BeginRenderPass(&renderPassDescriptor);
pass.EndPass();
wgpu::CommandBuffer commands = encoder.Finish();
wgpu::Queue queue = dawnDevice.GetDefaultQueue();
queue.Submit(1, &commands);
}
// Submits a 1x1x1 copy from source to destination
void SimpleCopyTextureToTexture(wgpu::Device dawnDevice,
wgpu::Queue dawnQueue,
wgpu::Texture source,
wgpu::Texture destination) {
wgpu::TextureCopyView copySrc;
copySrc.texture = source;
copySrc.mipLevel = 0;
copySrc.arrayLayer = 0;
copySrc.origin = {0, 0, 0};
wgpu::TextureCopyView copyDst;
copyDst.texture = destination;
copyDst.mipLevel = 0;
copyDst.arrayLayer = 0;
copyDst.origin = {0, 0, 0};
wgpu::Extent3D copySize = {1, 1, 1};
wgpu::CommandEncoder encoder = dawnDevice.CreateCommandEncoder();
encoder.CopyTextureToTexture(&copySrc, &copyDst, &copySize);
wgpu::CommandBuffer commands = encoder.Finish();
dawnQueue.Submit(1, &commands);
}
};
// Clear an image in |secondDevice|
// Verify clear color is visible in |device|
TEST_P(VulkanImageWrappingUsageTests, ClearImageAcrossDevices) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on signalFd
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture nextWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Verify |device| sees the changes from |secondDevice|
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), nextWrappedTexture, 0, 0);
IgnoreSignalSemaphore(device, nextWrappedTexture);
}
// Import texture to |device| and |secondDevice|
// Clear image in |secondDevice|
// Verify clear color is visible in |device|
// Verify the very first import into |device| also sees the change, since it should
// alias the same memory
TEST_P(VulkanImageWrappingUsageTests, ClearImageAcrossDevicesAliased) {
DAWN_SKIP_TEST_IF(UsesWire());
// WrapVulkanImage consumes the file descriptor so we can't import defaultFd twice.
// Duplicate the file descriptor so we can import it twice.
int defaultFdCopy = dup(defaultFd);
ASSERT(defaultFdCopy != -1);
// Import the image on |device
wgpu::Texture wrappedTextureAlias =
WrapVulkanImage(device, &defaultDescriptor, defaultFdCopy, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on signalFd
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture nextWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Verify |device| sees the changes from |secondDevice| (waits)
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), nextWrappedTexture, 0, 0);
// Verify aliased texture sees changes from |secondDevice| (without waiting!)
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), wrappedTextureAlias, 0, 0);
IgnoreSignalSemaphore(device, nextWrappedTexture);
IgnoreSignalSemaphore(device, wrappedTextureAlias);
}
// Clear an image in |secondDevice|
// Verify clear color is not visible in |device| if we import the texture as not cleared
TEST_P(VulkanImageWrappingUsageTests, UnclearedTextureIsCleared) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on signalFd
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture nextWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd}, false);
// Verify |device| doesn't see the changes from |secondDevice|
EXPECT_PIXEL_RGBA8_EQ(RGBA8(0, 0, 0, 0), nextWrappedTexture, 0, 0);
IgnoreSignalSemaphore(device, nextWrappedTexture);
}
// Import a texture into |secondDevice|
// Issue a copy of the imported texture inside |device| to |copyDstTexture|
// Verify the clear color from |secondDevice| is visible in |copyDstTexture|
TEST_P(VulkanImageWrappingUsageTests, CopyTextureToTextureSrcSync) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on |signalFd|
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture deviceWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Create a second texture on |device|
wgpu::Texture copyDstTexture = device.CreateTexture(&defaultDescriptor);
// Copy |deviceWrappedTexture| into |copyDstTexture|
SimpleCopyTextureToTexture(device, queue, deviceWrappedTexture, copyDstTexture);
// Verify |copyDstTexture| sees changes from |secondDevice|
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), copyDstTexture, 0, 0);
IgnoreSignalSemaphore(device, deviceWrappedTexture);
}
// Import a texture into |device|
// Copy color A into texture on |device|
// Import same texture into |secondDevice|, waiting on the copy signal
// Copy color B using Texture to Texture copy on |secondDevice|
// Import texture back into |device|, waiting on color B signal
// Verify texture contains color B
// If texture destination isn't synchronized, |secondDevice| could copy color B
// into the texture first, then |device| writes color A
TEST_P(VulkanImageWrappingUsageTests, CopyTextureToTextureDstSync) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |device|
wgpu::Texture wrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |device|
ClearImage(device, wrappedTexture, {5 / 255.0f, 6 / 255.0f, 7 / 255.0f, 8 / 255.0f});
int signalFd =
dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(device.Get(), wrappedTexture.Get());
// Import the image to |secondDevice|, making sure we wait on |signalFd|
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture secondDeviceWrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Create a texture with color B on |secondDevice|
wgpu::Texture copySrcTexture = secondDevice.CreateTexture(&defaultDescriptor);
ClearImage(secondDevice, copySrcTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
// Copy color B on |secondDevice|
wgpu::Queue secondDeviceQueue = secondDevice.GetDefaultQueue();
SimpleCopyTextureToTexture(secondDevice, secondDeviceQueue, copySrcTexture,
secondDeviceWrappedTexture);
// Re-import back into |device|, waiting on |secondDevice|'s signal
signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
secondDevice.Get(), secondDeviceWrappedTexture.Get());
memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture nextWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Verify |nextWrappedTexture| contains the color from our copy
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), nextWrappedTexture, 0, 0);
IgnoreSignalSemaphore(device, nextWrappedTexture);
}
// Import a texture from |secondDevice|
// Issue a copy of the imported texture inside |device| to |copyDstBuffer|
// Verify the clear color from |secondDevice| is visible in |copyDstBuffer|
TEST_P(VulkanImageWrappingUsageTests, CopyTextureToBufferSrcSync) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on |signalFd|
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture deviceWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Create a destination buffer on |device|
wgpu::BufferDescriptor bufferDesc;
bufferDesc.size = 4;
bufferDesc.usage = wgpu::BufferUsage::CopyDst | wgpu::BufferUsage::CopySrc;
wgpu::Buffer copyDstBuffer = device.CreateBuffer(&bufferDesc);
// Copy |deviceWrappedTexture| into |copyDstBuffer|
wgpu::TextureCopyView copySrc;
copySrc.texture = deviceWrappedTexture;
copySrc.mipLevel = 0;
copySrc.arrayLayer = 0;
copySrc.origin = {0, 0, 0};
wgpu::BufferCopyView copyDst;
copyDst.buffer = copyDstBuffer;
copyDst.offset = 0;
copyDst.bytesPerRow = 256;
copyDst.rowsPerImage = 0;
wgpu::Extent3D copySize = {1, 1, 1};
wgpu::CommandEncoder encoder = device.CreateCommandEncoder();
encoder.CopyTextureToBuffer(&copySrc, &copyDst, &copySize);
wgpu::CommandBuffer commands = encoder.Finish();
queue.Submit(1, &commands);
// Verify |copyDstBuffer| sees changes from |secondDevice|
uint32_t expected = 0x04030201;
EXPECT_BUFFER_U32_EQ(expected, copyDstBuffer, 0);
IgnoreSignalSemaphore(device, deviceWrappedTexture);
}
// Import a texture into |device|
// Copy color A into texture on |device|
// Import same texture into |secondDevice|, waiting on the copy signal
// Copy color B using Buffer to Texture copy on |secondDevice|
// Import texture back into |device|, waiting on color B signal
// Verify texture contains color B
// If texture destination isn't synchronized, |secondDevice| could copy color B
// into the texture first, then |device| writes color A
TEST_P(VulkanImageWrappingUsageTests, CopyBufferToTextureDstSync) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |device|
wgpu::Texture wrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |device|
ClearImage(device, wrappedTexture, {5 / 255.0f, 6 / 255.0f, 7 / 255.0f, 8 / 255.0f});
int signalFd =
dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(device.Get(), wrappedTexture.Get());
// Import the image to |secondDevice|, making sure we wait on |signalFd|
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture secondDeviceWrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Copy color B on |secondDevice|
wgpu::Queue secondDeviceQueue = secondDevice.GetDefaultQueue();
// Create a buffer on |secondDevice|
wgpu::Buffer copySrcBuffer =
utils::CreateBufferFromData(secondDevice, wgpu::BufferUsage::CopySrc, {0x04030201});
// Copy |copySrcBuffer| into |secondDeviceWrappedTexture|
wgpu::BufferCopyView copySrc;
copySrc.buffer = copySrcBuffer;
copySrc.offset = 0;
copySrc.bytesPerRow = 256;
copySrc.rowsPerImage = 0;
wgpu::TextureCopyView copyDst;
copyDst.texture = secondDeviceWrappedTexture;
copyDst.mipLevel = 0;
copyDst.arrayLayer = 0;
copyDst.origin = {0, 0, 0};
wgpu::Extent3D copySize = {1, 1, 1};
wgpu::CommandEncoder encoder = secondDevice.CreateCommandEncoder();
encoder.CopyBufferToTexture(&copySrc, &copyDst, &copySize);
wgpu::CommandBuffer commands = encoder.Finish();
secondDeviceQueue.Submit(1, &commands);
// Re-import back into |device|, waiting on |secondDevice|'s signal
signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
secondDevice.Get(), secondDeviceWrappedTexture.Get());
memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture nextWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Verify |nextWrappedTexture| contains the color from our copy
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), nextWrappedTexture, 0, 0);
IgnoreSignalSemaphore(device, nextWrappedTexture);
}
// Import a texture from |secondDevice|
// Issue a copy of the imported texture inside |device| to |copyDstTexture|
// Issue second copy to |secondCopyDstTexture|
// Verify the clear color from |secondDevice| is visible in both copies
TEST_P(VulkanImageWrappingUsageTests, DoubleTextureUsage) {
DAWN_SKIP_TEST_IF(UsesWire());
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture =
WrapVulkanImage(secondDevice, &defaultDescriptor, defaultFd, defaultAllocationSize,
defaultMemoryTypeIndex, {});
// Clear |wrappedTexture| on |secondDevice|
ClearImage(secondDevice, wrappedTexture, {1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
// Import the image to |device|, making sure we wait on |signalFd|
int memoryFd = GetMemoryFd(deviceVk, defaultAllocation);
wgpu::Texture deviceWrappedTexture =
WrapVulkanImage(device, &defaultDescriptor, memoryFd, defaultAllocationSize,
defaultMemoryTypeIndex, {signalFd});
// Create a second texture on |device|
wgpu::Texture copyDstTexture = device.CreateTexture(&defaultDescriptor);
// Create a third texture on |device|
wgpu::Texture secondCopyDstTexture = device.CreateTexture(&defaultDescriptor);
// Copy |deviceWrappedTexture| into |copyDstTexture|
SimpleCopyTextureToTexture(device, queue, deviceWrappedTexture, copyDstTexture);
// Copy |deviceWrappedTexture| into |secondCopyDstTexture|
SimpleCopyTextureToTexture(device, queue, deviceWrappedTexture, secondCopyDstTexture);
// Verify |copyDstTexture| sees changes from |secondDevice|
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), copyDstTexture, 0, 0);
// Verify |secondCopyDstTexture| sees changes from |secondDevice|
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), secondCopyDstTexture, 0, 0);
IgnoreSignalSemaphore(device, deviceWrappedTexture);
}
// Tex A on device 3 (external export)
// Tex B on device 2 (external export)
// Tex C on device 1 (external export)
// Clear color for A on device 3
// Copy A->B on device 3
// Copy B->C on device 2 (wait on B from previous op)
// Copy C->D on device 1 (wait on C from previous op)
// Verify D has same color as A
TEST_P(VulkanImageWrappingUsageTests, ChainTextureCopy) {
DAWN_SKIP_TEST_IF(UsesWire());
// Close |defaultFd| since this test doesn't import it anywhere
close(defaultFd);
// device 1 = |device|
// device 2 = |secondDevice|
// Create device 3
dawn_native::vulkan::Device* thirdDeviceVk = reinterpret_cast<dawn_native::vulkan::Device*>(
backendAdapter->CreateDevice(&deviceDescriptor));
wgpu::Device thirdDevice =
wgpu::Device::Acquire(reinterpret_cast<WGPUDevice>(thirdDeviceVk));
// Make queue for device 2 and 3
wgpu::Queue secondDeviceQueue = secondDevice.GetDefaultQueue();
wgpu::Queue thirdDeviceQueue = thirdDevice.GetDefaultQueue();
// Allocate memory for A, B, C
VkImage imageA;
VkDeviceMemory allocationA;
int memoryFdA;
VkDeviceSize allocationSizeA;
uint32_t memoryTypeIndexA;
CreateBindExportImage(thirdDeviceVk, 1, 1, VK_FORMAT_R8G8B8A8_UNORM, &imageA, &allocationA,
&allocationSizeA, &memoryTypeIndexA, &memoryFdA);
VkImage imageB;
VkDeviceMemory allocationB;
int memoryFdB;
VkDeviceSize allocationSizeB;
uint32_t memoryTypeIndexB;
CreateBindExportImage(secondDeviceVk, 1, 1, VK_FORMAT_R8G8B8A8_UNORM, &imageB, &allocationB,
&allocationSizeB, &memoryTypeIndexB, &memoryFdB);
VkImage imageC;
VkDeviceMemory allocationC;
int memoryFdC;
VkDeviceSize allocationSizeC;
uint32_t memoryTypeIndexC;
CreateBindExportImage(deviceVk, 1, 1, VK_FORMAT_R8G8B8A8_UNORM, &imageC, &allocationC,
&allocationSizeC, &memoryTypeIndexC, &memoryFdC);
// Import TexA, TexB on device 3
wgpu::Texture wrappedTexADevice3 = WrapVulkanImage(
thirdDevice, &defaultDescriptor, memoryFdA, allocationSizeA, memoryTypeIndexA, {});
wgpu::Texture wrappedTexBDevice3 = WrapVulkanImage(
thirdDevice, &defaultDescriptor, memoryFdB, allocationSizeB, memoryTypeIndexB, {});
// Clear TexA
ClearImage(thirdDevice, wrappedTexADevice3,
{1 / 255.0f, 2 / 255.0f, 3 / 255.0f, 4 / 255.0f});
// Copy A->B
SimpleCopyTextureToTexture(thirdDevice, thirdDeviceQueue, wrappedTexADevice3,
wrappedTexBDevice3);
int signalFdTexBDevice3 = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
thirdDevice.Get(), wrappedTexBDevice3.Get());
IgnoreSignalSemaphore(thirdDevice, wrappedTexADevice3);
// Import TexB, TexC on device 2
memoryFdB = GetMemoryFd(secondDeviceVk, allocationB);
wgpu::Texture wrappedTexBDevice2 =
WrapVulkanImage(secondDevice, &defaultDescriptor, memoryFdB, allocationSizeB,
memoryTypeIndexB, {signalFdTexBDevice3});
wgpu::Texture wrappedTexCDevice2 = WrapVulkanImage(
secondDevice, &defaultDescriptor, memoryFdC, allocationSizeC, memoryTypeIndexC, {});
// Copy B->C on device 2
SimpleCopyTextureToTexture(secondDevice, secondDeviceQueue, wrappedTexBDevice2,
wrappedTexCDevice2);
int signalFdTexCDevice2 = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(
secondDevice.Get(), wrappedTexCDevice2.Get());
IgnoreSignalSemaphore(secondDevice, wrappedTexBDevice2);
// Import TexC on device 1
memoryFdC = GetMemoryFd(deviceVk, allocationC);
wgpu::Texture wrappedTexCDevice1 =
WrapVulkanImage(device, &defaultDescriptor, memoryFdC, allocationSizeC,
memoryTypeIndexC, {signalFdTexCDevice2});
// Create TexD on device 1
wgpu::Texture texD = device.CreateTexture(&defaultDescriptor);
// Copy C->D on device 1
SimpleCopyTextureToTexture(device, queue, wrappedTexCDevice1, texD);
// Verify D matches clear color
EXPECT_PIXEL_RGBA8_EQ(RGBA8(1, 2, 3, 4), texD, 0, 0);
thirdDeviceVk->GetFencedDeleter()->DeleteWhenUnused(imageA);
thirdDeviceVk->GetFencedDeleter()->DeleteWhenUnused(allocationA);
secondDeviceVk->GetFencedDeleter()->DeleteWhenUnused(imageB);
secondDeviceVk->GetFencedDeleter()->DeleteWhenUnused(allocationB);
deviceVk->GetFencedDeleter()->DeleteWhenUnused(imageC);
deviceVk->GetFencedDeleter()->DeleteWhenUnused(allocationC);
IgnoreSignalSemaphore(device, wrappedTexCDevice1);
}
// Tests a larger image is preserved when importing
// TODO(http://crbug.com/dawn/206): This fails on AMD
TEST_P(VulkanImageWrappingUsageTests, LargerImage) {
DAWN_SKIP_TEST_IF(UsesWire() || IsAMD());
close(defaultFd);
wgpu::TextureDescriptor descriptor;
descriptor.dimension = wgpu::TextureDimension::e2D;
descriptor.size.width = 640;
descriptor.size.height = 480;
descriptor.size.depth = 1;
descriptor.arrayLayerCount = 1;
descriptor.sampleCount = 1;
descriptor.format = wgpu::TextureFormat::BGRA8Unorm;
descriptor.mipLevelCount = 1;
descriptor.usage = wgpu::TextureUsage::CopyDst | wgpu::TextureUsage::CopySrc;
// Fill memory with textures to trigger layout issues on AMD
std::vector<wgpu::Texture> textures;
for (int i = 0; i < 20; i++) {
textures.push_back(device.CreateTexture(&descriptor));
}
wgpu::Queue secondDeviceQueue = secondDevice.GetDefaultQueue();
// Make an image on |secondDevice|
VkImage imageA;
VkDeviceMemory allocationA;
int memoryFdA;
VkDeviceSize allocationSizeA;
uint32_t memoryTypeIndexA;
CreateBindExportImage(secondDeviceVk, 640, 480, VK_FORMAT_R8G8B8A8_UNORM, &imageA,
&allocationA, &allocationSizeA, &memoryTypeIndexA, &memoryFdA);
// Import the image on |secondDevice|
wgpu::Texture wrappedTexture = WrapVulkanImage(secondDevice, &descriptor, memoryFdA,
allocationSizeA, memoryTypeIndexA, {});
// Draw a non-trivial picture
uint32_t width = 640, height = 480, pixelSize = 4;
uint32_t bytesPerRow = Align(width * pixelSize, kTextureBytesPerRowAlignment);
std::vector<unsigned char> data(bytesPerRow * (height - 1) + width * pixelSize);
for (uint32_t row = 0; row < height; row++) {
for (uint32_t col = 0; col < width; col++) {
float normRow = static_cast<float>(row) / height;
float normCol = static_cast<float>(col) / width;
float dist = sqrt(normRow * normRow + normCol * normCol) * 3;
dist = dist - static_cast<int>(dist);
data[4 * (row * width + col)] = static_cast<unsigned char>(dist * 255);
data[4 * (row * width + col) + 1] = static_cast<unsigned char>(dist * 255);
data[4 * (row * width + col) + 2] = static_cast<unsigned char>(dist * 255);
data[4 * (row * width + col) + 3] = 255;
}
}
// Write the picture
{
wgpu::Buffer copySrcBuffer = utils::CreateBufferFromData(
secondDevice, data.data(), data.size(), wgpu::BufferUsage::CopySrc);
wgpu::BufferCopyView copySrc =
utils::CreateBufferCopyView(copySrcBuffer, 0, bytesPerRow, 0);
wgpu::TextureCopyView copyDst =
utils::CreateTextureCopyView(wrappedTexture, 0, 0, {0, 0, 0});
wgpu::Extent3D copySize = {width, height, 1};
wgpu::CommandEncoder encoder = secondDevice.CreateCommandEncoder();
encoder.CopyBufferToTexture(&copySrc, &copyDst, &copySize);
wgpu::CommandBuffer commands = encoder.Finish();
secondDeviceQueue.Submit(1, &commands);
}
int signalFd = dawn_native::vulkan::ExportSignalSemaphoreOpaqueFD(secondDevice.Get(),
wrappedTexture.Get());
int memoryFd = GetMemoryFd(secondDeviceVk, allocationA);
// Import the image on |device|
wgpu::Texture nextWrappedTexture = WrapVulkanImage(
device, &descriptor, memoryFd, allocationSizeA, memoryTypeIndexA, {signalFd});
// Copy the image into a buffer for comparison
wgpu::BufferDescriptor copyDesc;
copyDesc.size = data.size();
copyDesc.usage = wgpu::BufferUsage::CopySrc | wgpu::BufferUsage::CopyDst;
wgpu::Buffer copyDstBuffer = device.CreateBuffer(&copyDesc);
{
wgpu::TextureCopyView copySrc =
utils::CreateTextureCopyView(nextWrappedTexture, 0, 0, {0, 0, 0});
wgpu::BufferCopyView copyDst =
utils::CreateBufferCopyView(copyDstBuffer, 0, bytesPerRow, 0);
wgpu::Extent3D copySize = {width, height, 1};
wgpu::CommandEncoder encoder = device.CreateCommandEncoder();
encoder.CopyTextureToBuffer(&copySrc, &copyDst, &copySize);
wgpu::CommandBuffer commands = encoder.Finish();
queue.Submit(1, &commands);
}
// Check the image is not corrupted on |device|
EXPECT_BUFFER_U32_RANGE_EQ(reinterpret_cast<uint32_t*>(data.data()), copyDstBuffer, 0,
data.size() / 4);
IgnoreSignalSemaphore(device, nextWrappedTexture);
secondDeviceVk->GetFencedDeleter()->DeleteWhenUnused(imageA);
secondDeviceVk->GetFencedDeleter()->DeleteWhenUnused(allocationA);
}
DAWN_INSTANTIATE_TEST(VulkanImageWrappingValidationTests, VulkanBackend());
DAWN_INSTANTIATE_TEST(VulkanImageWrappingUsageTests, VulkanBackend());
}} // namespace dawn_native::vulkan