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fuchsia / third_party / vulkan-cts / a8c8a8df7a6b04c70caed1beff6307dfec871386 / . / external / vulkancts / modules / vulkan / wsi / vktWsiDisplayTimingTests.cpp
blob: a7087ac407f29e33296d9fee44234eba73f01a25 [file] [log] [blame]
/*-------------------------------------------------------------------------
* Vulkan Conformance Tests
* ------------------------
*
* Copyright (c) 2017 Google Inc.
*
* 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.
*
*//*!
* \file
* \brief Tests for VK_GOOGLE_display_timing
*//*--------------------------------------------------------------------*/
#include "vkRefUtil.hpp"
#include "vkWsiPlatform.hpp"
#include "vkWsiUtil.hpp"
#include "vkQueryUtil.hpp"
#include "vkDeviceUtil.hpp"
#include "vkPlatform.hpp"
#include "vkTypeUtil.hpp"
#include "vkPrograms.hpp"
#include "vkCmdUtil.hpp"
#include "vkWsiUtil.hpp"
#include "vkCmdUtil.hpp"
#include "vkObjUtil.hpp"
#include "vktWsiDisplayTimingTests.hpp"
#include "vktTestCaseUtil.hpp"
#include "vktTestGroupUtil.hpp"
#include "vktCustomInstancesDevices.hpp"
#include "tcuPlatform.hpp"
#include "tcuResultCollector.hpp"
#include "tcuTestLog.hpp"
#include "tcuCommandLine.hpp"
#include "deClock.h"
#include <vector>
#include <string>
using std::vector;
using std::string;
using tcu::Maybe;
using tcu::UVec2;
using tcu::TestLog;
namespace vkt
{
namespace wsi
{
namespace
{
static const deUint64 MILLISECOND = 1000ull * 1000ull;
static const deUint64 SECOND = 1000ull * MILLISECOND;
typedef vector<vk::VkExtensionProperties> Extensions;
void checkAllSupported (const Extensions& supportedExtensions, const vector<string>& requiredExtensions)
{
for (vector<string>::const_iterator requiredExtName = requiredExtensions.begin();
requiredExtName != requiredExtensions.end();
++requiredExtName)
{
if (!isExtensionSupported(supportedExtensions, vk::RequiredExtension(*requiredExtName)))
TCU_THROW(NotSupportedError, (*requiredExtName + " is not supported").c_str());
}
}
CustomInstance createInstanceWithWsi (Context& context,
const Extensions& supportedExtensions,
vk::wsi::Type wsiType)
{
vector<string> extensions;
extensions.push_back("VK_KHR_surface");
extensions.push_back(getExtensionName(wsiType));
checkAllSupported(supportedExtensions, extensions);
return vkt::createCustomInstanceWithExtensions(context, extensions);
}
vk::VkPhysicalDeviceFeatures getDeviceNullFeatures (void)
{
vk::VkPhysicalDeviceFeatures features;
deMemset(&features, 0, sizeof(features));
return features;
}
vk::Move<vk::VkDevice> createDeviceWithWsi (const vk::PlatformInterface& vkp,
const vk::VkInstance instance,
const vk::InstanceInterface& vki,
vk::VkPhysicalDevice physicalDevice,
const Extensions& supportedExtensions,
const deUint32 queueFamilyIndex,
bool requiresDisplayTiming,
bool validationEnabled,
const vk::VkAllocationCallbacks* pAllocator = DE_NULL)
{
const float queuePriorities[] = { 1.0f };
const vk::VkDeviceQueueCreateInfo queueInfos[] =
{
{
vk::VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO,
DE_NULL,
(vk::VkDeviceQueueCreateFlags)0,
queueFamilyIndex,
DE_LENGTH_OF_ARRAY(queuePriorities),
&queuePriorities[0]
}
};
const vk::VkPhysicalDeviceFeatures features = getDeviceNullFeatures();
const char* const extensions[] =
{
"VK_KHR_swapchain",
"VK_GOOGLE_display_timing"
};
const vk::VkDeviceCreateInfo deviceParams =
{
vk::VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO,
DE_NULL,
(vk::VkDeviceCreateFlags)0,
DE_LENGTH_OF_ARRAY(queueInfos),
&queueInfos[0],
0u,
DE_NULL,
requiresDisplayTiming ? 2u : 1u,
DE_ARRAY_BEGIN(extensions),
&features
};
for (int ndx = 0; ndx < DE_LENGTH_OF_ARRAY(extensions); ++ndx)
{
if (!isExtensionSupported(supportedExtensions, vk::RequiredExtension(extensions[ndx])))
TCU_THROW(NotSupportedError, (string(extensions[ndx]) + " is not supported").c_str());
}
return createCustomDevice(validationEnabled, vkp, instance, vki, physicalDevice, &deviceParams, pAllocator);
}
de::MovePtr<vk::wsi::Display> createDisplay (const vk::Platform& platform,
const Extensions& supportedExtensions,
vk::wsi::Type wsiType)
{
try
{
return de::MovePtr<vk::wsi::Display>(platform.createWsiDisplay(wsiType));
}
catch (const tcu::NotSupportedError& e)
{
if (isExtensionSupported(supportedExtensions, vk::RequiredExtension(getExtensionName(wsiType))) &&
platform.hasDisplay(wsiType))
{
// If VK_KHR_{platform}_surface was supported, vk::Platform implementation
// must support creating native display & window for that WSI type.
throw tcu::TestError(e.getMessage());
}
else
throw;
}
}
de::MovePtr<vk::wsi::Window> createWindow (const vk::wsi::Display& display, const Maybe<UVec2>& initialSize)
{
try
{
return de::MovePtr<vk::wsi::Window>(display.createWindow(initialSize));
}
catch (const tcu::NotSupportedError& e)
{
// See createDisplay - assuming that wsi::Display was supported platform port
// should also support creating a window.
throw tcu::TestError(e.getMessage());
}
}
void initSemaphores (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkSemaphore>& semaphores)
{
for (size_t ndx = 0; ndx < semaphores.size(); ndx++)
semaphores[ndx] = createSemaphore(vkd, device).disown();
}
void deinitSemaphores (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkSemaphore>& semaphores)
{
for (size_t ndx = 0; ndx < semaphores.size(); ndx++)
{
if (semaphores[ndx] != (vk::VkSemaphore)0)
vkd.destroySemaphore(device, semaphores[ndx], DE_NULL);
semaphores[ndx] = (vk::VkSemaphore)0;
}
semaphores.clear();
}
void initFences (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkFence>& fences)
{
for (size_t ndx = 0; ndx < fences.size(); ndx++)
fences[ndx] = createFence(vkd, device).disown();
}
void deinitFences (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkFence>& fences)
{
for (size_t ndx = 0; ndx < fences.size(); ndx++)
{
if (fences[ndx] != (vk::VkFence)0)
vkd.destroyFence(device, fences[ndx], DE_NULL);
fences[ndx] = (vk::VkFence)0;
}
fences.clear();
}
void cmdRenderFrame (const vk::DeviceInterface& vkd,
vk::VkCommandBuffer commandBuffer,
vk::VkPipelineLayout pipelineLayout,
vk::VkPipeline pipeline,
size_t frameNdx,
deUint32 quadCount)
{
const deUint32 frameNdxValue = (deUint32)frameNdx;
vkd.cmdPushConstants(commandBuffer, pipelineLayout, vk::VK_SHADER_STAGE_FRAGMENT_BIT, 0u, 4u, &frameNdxValue);
vkd.cmdBindPipeline(commandBuffer, vk::VK_PIPELINE_BIND_POINT_GRAPHICS, pipeline);
vkd.cmdDraw(commandBuffer, quadCount * 6u, 1u, 0u, 0u);
}
vk::Move<vk::VkCommandBuffer> createCommandBuffer (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkCommandPool commandPool,
vk::VkPipelineLayout pipelineLayout,
vk::VkRenderPass renderPass,
vk::VkFramebuffer framebuffer,
vk::VkPipeline pipeline,
vk::VkImage image,
bool isFirst,
size_t frameNdx,
deUint32 quadCount,
deUint32 imageWidth,
deUint32 imageHeight)
{
const vk::VkCommandBufferAllocateInfo allocateInfo =
{
vk::VK_STRUCTURE_TYPE_COMMAND_BUFFER_ALLOCATE_INFO,
DE_NULL,
commandPool,
vk::VK_COMMAND_BUFFER_LEVEL_PRIMARY,
1
};
vk::Move<vk::VkCommandBuffer> commandBuffer (vk::allocateCommandBuffer(vkd, device, &allocateInfo));
beginCommandBuffer(vkd, *commandBuffer, 0u);
{
const vk::VkImageSubresourceRange subRange =
{
vk::VK_IMAGE_ASPECT_COLOR_BIT,
0,
1,
0,
1
};
const vk::VkImageMemoryBarrier barrier =
{
vk::VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER,
DE_NULL,
vk::VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT,
vk::VK_ACCESS_COLOR_ATTACHMENT_READ_BIT | vk::VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT,
isFirst ? vk::VK_IMAGE_LAYOUT_UNDEFINED : vk::VK_IMAGE_LAYOUT_PRESENT_SRC_KHR,
vk::VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,
VK_QUEUE_FAMILY_IGNORED,
VK_QUEUE_FAMILY_IGNORED,
image,
subRange
};
vkd.cmdPipelineBarrier(*commandBuffer, vk::VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT, vk::VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT, 0, 0, DE_NULL, 0, DE_NULL, 1, &barrier);
}
beginRenderPass(vkd, *commandBuffer, renderPass, framebuffer, vk::makeRect2D(imageWidth, imageHeight), tcu::Vec4(0.25f, 0.5f, 0.75f, 1.0f));
cmdRenderFrame(vkd, *commandBuffer, pipelineLayout, pipeline, frameNdx, quadCount);
endRenderPass(vkd, *commandBuffer);
endCommandBuffer(vkd, *commandBuffer);
return commandBuffer;
}
void deinitCommandBuffers (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkCommandPool commandPool,
std::vector<vk::VkCommandBuffer>& commandBuffers)
{
for (size_t ndx = 0; ndx < commandBuffers.size(); ndx++)
{
if (commandBuffers[ndx] != (vk::VkCommandBuffer)0)
vkd.freeCommandBuffers(device, commandPool, 1u, &commandBuffers[ndx]);
commandBuffers[ndx] = (vk::VkCommandBuffer)0;
}
commandBuffers.clear();
}
vk::Move<vk::VkCommandPool> createCommandPool (const vk::DeviceInterface& vkd,
vk::VkDevice device,
deUint32 queueFamilyIndex)
{
const vk::VkCommandPoolCreateInfo createInfo =
{
vk::VK_STRUCTURE_TYPE_COMMAND_POOL_CREATE_INFO,
DE_NULL,
0u,
queueFamilyIndex
};
return vk::createCommandPool(vkd, device, &createInfo);
}
vk::Move<vk::VkFramebuffer> createFramebuffer (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkRenderPass renderPass,
vk::VkImageView imageView,
deUint32 width,
deUint32 height)
{
const vk::VkFramebufferCreateInfo createInfo =
{
vk::VK_STRUCTURE_TYPE_FRAMEBUFFER_CREATE_INFO,
DE_NULL,
0u,
renderPass,
1u,
&imageView,
width,
height,
1u
};
return vk::createFramebuffer(vkd, device, &createInfo);
}
void initFramebuffers (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkRenderPass renderPass,
std::vector<vk::VkImageView> imageViews,
deUint32 width,
deUint32 height,
std::vector<vk::VkFramebuffer>& framebuffers)
{
DE_ASSERT(framebuffers.size() == imageViews.size());
for (size_t ndx = 0; ndx < framebuffers.size(); ndx++)
framebuffers[ndx] = createFramebuffer(vkd, device, renderPass, imageViews[ndx], width, height).disown();
}
void deinitFramebuffers (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkFramebuffer>& framebuffers)
{
for (size_t ndx = 0; ndx < framebuffers.size(); ndx++)
{
if (framebuffers[ndx] != (vk::VkFramebuffer)0)
vkd.destroyFramebuffer(device, framebuffers[ndx], DE_NULL);
framebuffers[ndx] = (vk::VkFramebuffer)0;
}
framebuffers.clear();
}
vk::Move<vk::VkImageView> createImageView (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkImage image,
vk::VkFormat format)
{
const vk::VkImageViewCreateInfo createInfo =
{
vk::VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO,
DE_NULL,
0u,
image,
vk::VK_IMAGE_VIEW_TYPE_2D,
format,
vk::makeComponentMappingRGBA(),
{
vk::VK_IMAGE_ASPECT_COLOR_BIT,
0u,
1u,
0u,
1u
}
};
return vk::createImageView(vkd, device, &createInfo, DE_NULL);
}
void initImageViews (const vk::DeviceInterface& vkd,
vk::VkDevice device,
const std::vector<vk::VkImage>& images,
vk::VkFormat format,
std::vector<vk::VkImageView>& imageViews)
{
DE_ASSERT(images.size() == imageViews.size());
for (size_t ndx = 0; ndx < imageViews.size(); ndx++)
imageViews[ndx] = createImageView(vkd, device, images[ndx], format).disown();
}
void deinitImageViews (const vk::DeviceInterface& vkd,
vk::VkDevice device,
std::vector<vk::VkImageView>& imageViews)
{
for (size_t ndx = 0; ndx < imageViews.size(); ndx++)
{
if (imageViews[ndx] != (vk::VkImageView)0)
vkd.destroyImageView(device, imageViews[ndx], DE_NULL);
imageViews[ndx] = (vk::VkImageView)0;
}
imageViews.clear();
}
vk::Move<vk::VkRenderPass> createRenderPass (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkFormat format)
{
return vk::makeRenderPass(vkd, device, format, vk::VK_FORMAT_UNDEFINED, vk::VK_ATTACHMENT_LOAD_OP_LOAD, vk::VK_IMAGE_LAYOUT_PRESENT_SRC_KHR);
}
vk::Move<vk::VkPipeline> createPipeline (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkRenderPass renderPass,
vk::VkPipelineLayout layout,
vk::VkShaderModule vertexShaderModule,
vk::VkShaderModule fragmentShaderModule,
deUint32 width,
deUint32 height)
{
const vk::VkPipelineVertexInputStateCreateInfo vertexInputState =
{
vk::VK_STRUCTURE_TYPE_PIPELINE_VERTEX_INPUT_STATE_CREATE_INFO,
DE_NULL,
0u,
0u,
DE_NULL,
0u,
DE_NULL
};
const std::vector<vk::VkViewport> viewports (1, vk::makeViewport(tcu::UVec2(width, height)));
const std::vector<vk::VkRect2D> scissors (1, vk::makeRect2D(tcu::UVec2(width, height)));
return vk::makeGraphicsPipeline(vkd, // const DeviceInterface& vk
device, // const VkDevice device
layout, // const VkPipelineLayout pipelineLayout
vertexShaderModule, // const VkShaderModule vertexShaderModule
DE_NULL, // const VkShaderModule tessellationControlShaderModule
DE_NULL, // const VkShaderModule tessellationEvalShaderModule
DE_NULL, // const VkShaderModule geometryShaderModule
fragmentShaderModule, // const VkShaderModule fragmentShaderModule
renderPass, // const VkRenderPass renderPass
viewports, // const std::vector<VkViewport>& viewports
scissors, // const std::vector<VkRect2D>& scissors
vk::VK_PRIMITIVE_TOPOLOGY_TRIANGLE_LIST, // const VkPrimitiveTopology topology
0u, // const deUint32 subpass
0u, // const deUint32 patchControlPoints
&vertexInputState); // const VkPipelineVertexInputStateCreateInfo* vertexInputStateCreateInfo
}
vk::Move<vk::VkPipelineLayout> createPipelineLayout (const vk::DeviceInterface& vkd,
vk::VkDevice device)
{
const vk::VkPushConstantRange pushConstants[] =
{
{
vk::VK_SHADER_STAGE_FRAGMENT_BIT,
0u,
4u
}
};
const vk::VkPipelineLayoutCreateInfo createInfo =
{
vk::VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO,
DE_NULL,
0u,
0u,
DE_NULL,
DE_LENGTH_OF_ARRAY(pushConstants),
pushConstants
};
return vk::createPipelineLayout(vkd, device, &createInfo);
}
struct TestConfig
{
vk::wsi::Type wsiType;
bool useDisplayTiming;
vk::VkPresentModeKHR presentMode;
};
class DisplayTimingTestInstance : public TestInstance
{
public:
DisplayTimingTestInstance (Context& context, const TestConfig& testConfig);
~DisplayTimingTestInstance (void);
tcu::TestStatus iterate (void);
private:
const bool m_useDisplayTiming;
const deUint32 m_quadCount;
const vk::PlatformInterface& m_vkp;
const Extensions m_instanceExtensions;
const CustomInstance m_instance;
const vk::InstanceDriver& m_vki;
const vk::VkPhysicalDevice m_physicalDevice;
const de::UniquePtr<vk::wsi::Display> m_nativeDisplay;
const de::UniquePtr<vk::wsi::Window> m_nativeWindow;
const vk::Unique<vk::VkSurfaceKHR> m_surface;
const deUint32 m_queueFamilyIndex;
const Extensions m_deviceExtensions;
const vk::Unique<vk::VkDevice> m_device;
const vk::DeviceDriver m_vkd;
const vk::VkQueue m_queue;
const vk::Unique<vk::VkCommandPool> m_commandPool;
const vk::Unique<vk::VkShaderModule> m_vertexShaderModule;
const vk::Unique<vk::VkShaderModule> m_fragmentShaderModule;
const vk::Unique<vk::VkPipelineLayout> m_pipelineLayout;
const vk::VkSurfaceCapabilitiesKHR m_surfaceProperties;
const vector<vk::VkSurfaceFormatKHR> m_surfaceFormats;
const vector<vk::VkPresentModeKHR> m_presentModes;
tcu::ResultCollector m_resultCollector;
vk::Move<vk::VkSwapchainKHR> m_swapchain;
std::vector<vk::VkImage> m_swapchainImages;
std::vector<bool> m_isFirst;
vk::Move<vk::VkRenderPass> m_renderPass;
vk::Move<vk::VkPipeline> m_pipeline;
std::vector<vk::VkImageView> m_swapchainImageViews;
std::vector<vk::VkFramebuffer> m_framebuffers;
std::vector<vk::VkCommandBuffer> m_commandBuffers;
std::vector<vk::VkSemaphore> m_acquireSemaphores;
std::vector<vk::VkSemaphore> m_renderSemaphores;
std::vector<vk::VkFence> m_fences;
vk::VkSemaphore m_freeAcquireSemaphore;
vk::VkSemaphore m_freeRenderSemaphore;
vk::VkSwapchainCreateInfoKHR m_swapchainConfig;
const size_t m_frameCount;
size_t m_frameNdx;
const size_t m_maxOutOfDateCount;
size_t m_outOfDateCount;
std::map<deUint32, deUint64> m_queuePresentTimes;
vk::VkRefreshCycleDurationGOOGLE m_rcDuration;
deUint64 m_refreshDurationMultiplier;
deUint64 m_targetIPD;
deUint64 m_prevDesiredPresentTime;
deUint32 m_nextPresentID;
deUint32 m_ignoreThruPresentID;
bool m_ExpectImage80Late;
void initSwapchainResources (void);
void deinitSwapchainResources (void);
void render (void);
};
vk::VkSwapchainCreateInfoKHR createSwapchainConfig (vk::VkSurfaceKHR surface,
deUint32 queueFamilyIndex,
const vk::VkSurfaceCapabilitiesKHR& properties,
const vector<vk::VkSurfaceFormatKHR>& formats,
const vector<vk::VkPresentModeKHR>& presentModes,
vk::VkPresentModeKHR presentMode)
{
const deUint32 imageLayers = 1u;
const vk::VkImageUsageFlags imageUsage = properties.supportedUsageFlags;
const vk::VkBool32 clipped = VK_FALSE;
const deUint32 imageWidth = (properties.currentExtent.width != 0xFFFFFFFFu)
? properties.currentExtent.width
: de::min(1024u, properties.minImageExtent.width + ((properties.maxImageExtent.width - properties.minImageExtent.width) / 2));
const deUint32 imageHeight = (properties.currentExtent.height != 0xFFFFFFFFu)
? properties.currentExtent.height
: de::min(1024u, properties.minImageExtent.height + ((properties.maxImageExtent.height - properties.minImageExtent.height) / 2));
const vk::VkExtent2D imageSize = { imageWidth, imageHeight };
{
size_t presentModeNdx;
for (presentModeNdx = 0; presentModeNdx < presentModes.size(); presentModeNdx++)
{
if (presentModes[presentModeNdx] == presentMode)
break;
}
if (presentModeNdx == presentModes.size())
TCU_THROW(NotSupportedError, "Present mode not supported");
}
// Pick the first supported transform, alpha, and format:
vk::VkSurfaceTransformFlagsKHR transform;
for (transform = 1u; transform <= properties.supportedTransforms; transform = transform << 1u)
{
if ((properties.supportedTransforms & transform) != 0)
break;
}
vk::VkCompositeAlphaFlagsKHR alpha;
for (alpha = 1u; alpha <= properties.supportedCompositeAlpha; alpha = alpha << 1u)
{
if ((alpha & properties.supportedCompositeAlpha) != 0)
break;
}
{
const vk::VkSurfaceTransformFlagBitsKHR preTransform = (vk::VkSurfaceTransformFlagBitsKHR)transform;
const vk::VkCompositeAlphaFlagBitsKHR compositeAlpha = (vk::VkCompositeAlphaFlagBitsKHR)alpha;
const vk::VkFormat imageFormat = formats[0].format;
const vk::VkColorSpaceKHR imageColorSpace = formats[0].colorSpace;
const vk::VkSwapchainCreateInfoKHR createInfo =
{
vk::VK_STRUCTURE_TYPE_SWAPCHAIN_CREATE_INFO_KHR,
DE_NULL,
0u,
surface,
properties.minImageCount,
imageFormat,
imageColorSpace,
imageSize,
imageLayers,
imageUsage,
vk::VK_SHARING_MODE_EXCLUSIVE,
1u,
&queueFamilyIndex,
preTransform,
compositeAlpha,
presentMode,
clipped,
(vk::VkSwapchainKHR)0
};
return createInfo;
}
}
DisplayTimingTestInstance::DisplayTimingTestInstance (Context& context, const TestConfig& testConfig)
: TestInstance (context)
, m_useDisplayTiming (testConfig.useDisplayTiming)
, m_quadCount (16u)
, m_vkp (context.getPlatformInterface())
, m_instanceExtensions (vk::enumerateInstanceExtensionProperties(m_vkp, DE_NULL))
, m_instance (createInstanceWithWsi(context, m_instanceExtensions, testConfig.wsiType))
, m_vki (m_instance.getDriver())
, m_physicalDevice (vk::chooseDevice(m_vki, m_instance, context.getTestContext().getCommandLine()))
, m_nativeDisplay (createDisplay(context.getTestContext().getPlatform().getVulkanPlatform(), m_instanceExtensions, testConfig.wsiType))
, m_nativeWindow (createWindow(*m_nativeDisplay, tcu::Nothing))
, m_surface (vk::wsi::createSurface(m_vki, m_instance, testConfig.wsiType, *m_nativeDisplay, *m_nativeWindow))
, m_queueFamilyIndex (vk::wsi::chooseQueueFamilyIndex(m_vki, m_physicalDevice, *m_surface))
, m_deviceExtensions (vk::enumerateDeviceExtensionProperties(m_vki, m_physicalDevice, DE_NULL))
, m_device (createDeviceWithWsi(m_vkp, m_instance, m_vki, m_physicalDevice, m_deviceExtensions, m_queueFamilyIndex, testConfig.useDisplayTiming, context.getTestContext().getCommandLine().isValidationEnabled()))
, m_vkd (m_vkp, m_instance, *m_device)
, m_queue (getDeviceQueue(m_vkd, *m_device, m_queueFamilyIndex, 0u))
, m_commandPool (createCommandPool(m_vkd, *m_device, m_queueFamilyIndex))
, m_vertexShaderModule (vk::createShaderModule(m_vkd, *m_device, context.getBinaryCollection().get("quad-vert"), 0u))
, m_fragmentShaderModule (vk::createShaderModule(m_vkd, *m_device, context.getBinaryCollection().get("quad-frag"), 0u))
, m_pipelineLayout (createPipelineLayout(m_vkd, *m_device))
, m_surfaceProperties (vk::wsi::getPhysicalDeviceSurfaceCapabilities(m_vki, m_physicalDevice, *m_surface))
, m_surfaceFormats (vk::wsi::getPhysicalDeviceSurfaceFormats(m_vki, m_physicalDevice, *m_surface))
, m_presentModes (vk::wsi::getPhysicalDeviceSurfacePresentModes(m_vki, m_physicalDevice, *m_surface))
, m_freeAcquireSemaphore ((vk::VkSemaphore)0)
, m_freeRenderSemaphore ((vk::VkSemaphore)0)
, m_swapchainConfig (createSwapchainConfig(*m_surface, m_queueFamilyIndex, m_surfaceProperties, m_surfaceFormats, m_presentModes, testConfig.presentMode))
, m_frameCount (60u * 5u)
, m_frameNdx (0u)
, m_maxOutOfDateCount (20u)
, m_outOfDateCount (0u)
, m_ExpectImage80Late (false)
{
{
const tcu::ScopedLogSection surfaceInfo (m_context.getTestContext().getLog(), "SurfaceCapabilities", "SurfaceCapabilities");
m_context.getTestContext().getLog() << TestLog::Message << m_surfaceProperties << TestLog::EndMessage;
}
}
DisplayTimingTestInstance::~DisplayTimingTestInstance (void)
{
deinitSwapchainResources();
}
void DisplayTimingTestInstance::initSwapchainResources (void)
{
const size_t fenceCount = 6;
const deUint32 imageWidth = m_swapchainConfig.imageExtent.width;
const deUint32 imageHeight = m_swapchainConfig.imageExtent.height;
const vk::VkFormat imageFormat = m_swapchainConfig.imageFormat;
m_swapchain = vk::createSwapchainKHR(m_vkd, *m_device, &m_swapchainConfig);
m_swapchainImages = vk::wsi::getSwapchainImages(m_vkd, *m_device, *m_swapchain);
m_isFirst.resize(m_swapchainImages.size(), true);
m_renderPass = createRenderPass(m_vkd, *m_device, imageFormat);
m_pipeline = createPipeline(m_vkd, *m_device, *m_renderPass, *m_pipelineLayout, *m_vertexShaderModule, *m_fragmentShaderModule, imageWidth, imageHeight);
m_swapchainImageViews = std::vector<vk::VkImageView>(m_swapchainImages.size(), (vk::VkImageView)0);
m_framebuffers = std::vector<vk::VkFramebuffer>(m_swapchainImages.size(), (vk::VkFramebuffer)0);
m_acquireSemaphores = std::vector<vk::VkSemaphore>(m_swapchainImages.size(), (vk::VkSemaphore)0);
m_renderSemaphores = std::vector<vk::VkSemaphore>(m_swapchainImages.size(), (vk::VkSemaphore)0);
m_fences = std::vector<vk::VkFence>(fenceCount, (vk::VkFence)0);
m_commandBuffers = std::vector<vk::VkCommandBuffer>(m_fences.size(), (vk::VkCommandBuffer)0);
m_freeAcquireSemaphore = (vk::VkSemaphore)0;
m_freeRenderSemaphore = (vk::VkSemaphore)0;
m_freeAcquireSemaphore = createSemaphore(m_vkd, *m_device).disown();
m_freeRenderSemaphore = createSemaphore(m_vkd, *m_device).disown();
initImageViews(m_vkd, *m_device, m_swapchainImages, imageFormat, m_swapchainImageViews);
initFramebuffers(m_vkd, *m_device, *m_renderPass, m_swapchainImageViews, imageWidth, imageHeight, m_framebuffers);
initSemaphores(m_vkd, *m_device, m_acquireSemaphores);
initSemaphores(m_vkd, *m_device, m_renderSemaphores);
initFences(m_vkd, *m_device, m_fences);
if (m_useDisplayTiming)
{
// This portion should do interesting bits
m_queuePresentTimes = std::map<deUint32, deUint64>();
m_vkd.getRefreshCycleDurationGOOGLE(*m_device, *m_swapchain, &m_rcDuration);
m_refreshDurationMultiplier = 1u;
m_targetIPD = m_rcDuration.refreshDuration;
m_prevDesiredPresentTime = 0u;
m_nextPresentID = 0u;
m_ignoreThruPresentID = 0u;
}
}
void DisplayTimingTestInstance::deinitSwapchainResources (void)
{
VK_CHECK(m_vkd.queueWaitIdle(m_queue));
if (m_freeAcquireSemaphore != (vk::VkSemaphore)0)
{
m_vkd.destroySemaphore(*m_device, m_freeAcquireSemaphore, DE_NULL);
m_freeAcquireSemaphore = (vk::VkSemaphore)0;
}
if (m_freeRenderSemaphore != (vk::VkSemaphore)0)
{
m_vkd.destroySemaphore(*m_device, m_freeRenderSemaphore, DE_NULL);
m_freeRenderSemaphore = (vk::VkSemaphore)0;
}
deinitSemaphores(m_vkd, *m_device, m_acquireSemaphores);
deinitSemaphores(m_vkd, *m_device, m_renderSemaphores);
deinitFences(m_vkd, *m_device, m_fences);
deinitCommandBuffers(m_vkd, *m_device, *m_commandPool, m_commandBuffers);
deinitFramebuffers(m_vkd, *m_device, m_framebuffers);
deinitImageViews(m_vkd, *m_device, m_swapchainImageViews);
m_swapchainImages.clear();
m_isFirst.clear();
m_swapchain = vk::Move<vk::VkSwapchainKHR>();
m_renderPass = vk::Move<vk::VkRenderPass>();
m_pipeline = vk::Move<vk::VkPipeline>();
}
vector<vk::VkPastPresentationTimingGOOGLE> getPastPresentationTiming (const vk::DeviceInterface& vkd,
vk::VkDevice device,
vk::VkSwapchainKHR swapchain)
{
vector<vk::VkPastPresentationTimingGOOGLE> pastPresentationTimings;
deUint32 numPastPresentationTimings = 0;
vkd.getPastPresentationTimingGOOGLE(device, swapchain, &numPastPresentationTimings, DE_NULL);
pastPresentationTimings.resize(numPastPresentationTimings);
if (numPastPresentationTimings > 0)
vkd.getPastPresentationTimingGOOGLE(device, swapchain, &numPastPresentationTimings, &pastPresentationTimings[0]);
return pastPresentationTimings;
}
void DisplayTimingTestInstance::render (void)
{
const deUint64 foreverNs = ~0x0ull;
const vk::VkFence fence = m_fences[m_frameNdx % m_fences.size()];
const deUint32 width = m_swapchainConfig.imageExtent.width;
const deUint32 height = m_swapchainConfig.imageExtent.height;
tcu::TestLog& log = m_context.getTestContext().getLog();
// Throttle execution
if (m_frameNdx >= m_fences.size())
{
VK_CHECK(m_vkd.waitForFences(*m_device, 1u, &fence, VK_TRUE, foreverNs));
VK_CHECK(m_vkd.resetFences(*m_device, 1u, &fence));
m_vkd.freeCommandBuffers(*m_device, *m_commandPool, 1u, &m_commandBuffers[m_frameNdx % m_commandBuffers.size()]);
m_commandBuffers[m_frameNdx % m_commandBuffers.size()] = (vk::VkCommandBuffer)0;
}
vk::VkSemaphore currentAcquireSemaphore = m_freeAcquireSemaphore;
vk::VkSemaphore currentRenderSemaphore = m_freeRenderSemaphore;
deUint32 imageIndex;
// Acquire next image
VK_CHECK(m_vkd.acquireNextImageKHR(*m_device, *m_swapchain, foreverNs, currentAcquireSemaphore, (vk::VkFence)0, &imageIndex));
// Create command buffer
m_commandBuffers[m_frameNdx % m_commandBuffers.size()] = createCommandBuffer(m_vkd, *m_device, *m_commandPool, *m_pipelineLayout, *m_renderPass, m_framebuffers[imageIndex], *m_pipeline,
m_swapchainImages[imageIndex], m_isFirst[imageIndex], m_frameNdx, m_quadCount, width, height).disown();
m_isFirst[imageIndex] = false;
// Obtain timing data from previous frames
if (m_useDisplayTiming)
{
const vector<vk::VkPastPresentationTimingGOOGLE> pastPresentationTimings (getPastPresentationTiming(m_vkd, *m_device, *m_swapchain));
bool isEarly = false;
bool isLate = false;
for (size_t pastPresentationInfoNdx = 0 ; pastPresentationInfoNdx < pastPresentationTimings.size(); pastPresentationInfoNdx++)
{
if (m_queuePresentTimes[pastPresentationTimings[pastPresentationInfoNdx].presentID] > pastPresentationTimings[pastPresentationInfoNdx].actualPresentTime)
{
m_resultCollector.fail("Image with PresentID " + de::toString(pastPresentationTimings[pastPresentationInfoNdx].presentID) + "was displayed before vkQueuePresentKHR was called.");
}
if (!m_ignoreThruPresentID)
{
// This is the first time that we've received an
// actualPresentTime for this swapchain. In order to not
// perceive these early frames as "late", we need to sync-up
// our future desiredPresentTime's with the
// actualPresentTime(s) that we're receiving now.
const deInt64 multiple = m_nextPresentID - pastPresentationTimings.back().presentID;
m_prevDesiredPresentTime = pastPresentationTimings.back().actualPresentTime + (multiple * m_targetIPD);
m_ignoreThruPresentID = pastPresentationTimings[pastPresentationInfoNdx].presentID + 1;
}
else if (pastPresentationTimings[pastPresentationInfoNdx].presentID > m_ignoreThruPresentID)
{
if (pastPresentationTimings[pastPresentationInfoNdx].actualPresentTime > (pastPresentationTimings[pastPresentationInfoNdx].desiredPresentTime + m_rcDuration.refreshDuration + MILLISECOND))
{
const deUint64 actual = pastPresentationTimings[pastPresentationInfoNdx].actualPresentTime;
const deUint64 desired = pastPresentationTimings[pastPresentationInfoNdx].desiredPresentTime;
const deUint64 rdur = m_rcDuration.refreshDuration;
const deUint64 diff1 = actual - (desired + rdur);
const deUint64 diff2 = actual - desired;
log << TestLog::Message << "Image PresentID " << pastPresentationTimings[pastPresentationInfoNdx].presentID << " was " << diff1 << " nsec late." << TestLog::EndMessage;
if (m_ExpectImage80Late && (pastPresentationTimings[pastPresentationInfoNdx].presentID == 80))
{
if (diff1 > (SECOND / 2))
log << TestLog::Message << "\tNote: Image PresentID 80 was expected to be late by approximately 1 second." << TestLog::EndMessage;
else
m_resultCollector.fail("Image PresentID 80 was not late by approximately 1 second, as expected.");
}
log << TestLog::Message << "\t\t actualPresentTime = " << actual << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t - desiredPresentTime= " << desired << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t =========================================" << TestLog::EndMessage;
log << TestLog::Message << "\t\t diff = " << diff2 << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t - refreshDuration = " << rdur << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t =========================================" << TestLog::EndMessage;
log << TestLog::Message << "\t\t diff = " << diff1 << " nsec" << TestLog::EndMessage;
isLate = true;
}
else if ((pastPresentationTimings[pastPresentationInfoNdx].actualPresentTime > pastPresentationTimings[pastPresentationInfoNdx].earliestPresentTime) &&
(pastPresentationTimings[pastPresentationInfoNdx].presentMargin > (2 * MILLISECOND)))
{
const deUint64 actual = pastPresentationTimings[pastPresentationInfoNdx].actualPresentTime;
const deUint64 earliest = pastPresentationTimings[pastPresentationInfoNdx].earliestPresentTime;
const deUint64 diff = actual - earliest;
log << TestLog::Message << "Image PresentID " << pastPresentationTimings[pastPresentationInfoNdx].presentID << " can be presented " << diff << " nsec earlier." << TestLog::EndMessage;
log << TestLog::Message << "\t\t actualPresentTime = " << actual << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t -earliestPresentTime= " << earliest << " nsec" << TestLog::EndMessage;
log << TestLog::Message << "\t\t =========================================" << TestLog::EndMessage;
log << TestLog::Message << "\t\t diff = " << diff << " nsec" << TestLog::EndMessage;
isEarly = true;
}
}
}
// Preference is given to late presents over early presents:
if (isLate)
{
// Demonstrate how to slow down the frame rate if a frame is late,
// but don't go too slow (for test time reasons):
if (++m_refreshDurationMultiplier > 2)
m_refreshDurationMultiplier = 2;
else
log << TestLog::Message << "Increasing multiplier." << TestLog::EndMessage;
}
else if (isEarly)
{
// Demonstrate how to speed up the frame rate if a frame is early,
// but don't let the multiplier hit zero:
if (--m_refreshDurationMultiplier == 0)
m_refreshDurationMultiplier = 1;
else
log << TestLog::Message << "Decreasing multiplier." << TestLog::EndMessage;
}
m_targetIPD = m_rcDuration.refreshDuration * m_refreshDurationMultiplier;
}
// Submit command buffer
{
const vk::VkPipelineStageFlags dstStageMask = vk::VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT;
const vk::VkSubmitInfo submitInfo =
{
vk::VK_STRUCTURE_TYPE_SUBMIT_INFO,
DE_NULL,
1u,
&currentAcquireSemaphore,
&dstStageMask,
1u,
&m_commandBuffers[m_frameNdx % m_commandBuffers.size()],
1u,
&currentRenderSemaphore
};
VK_CHECK(m_vkd.queueSubmit(m_queue, 1u, &submitInfo, fence));
}
// Present frame
if (m_useDisplayTiming)
{
// This portion should do interesting bits
// Initially, mirror reference to move things along
vk::VkResult result;
vk::VkPresentTimeGOOGLE presentTime =
{
++m_nextPresentID,
m_prevDesiredPresentTime
};
// Record the current time, to record as the time of the vkQueuePresentKHR() call:
const deUint64 curtimeNano = deGetMicroseconds() * 1000;
m_queuePresentTimes[m_nextPresentID] = curtimeNano;
deUint64 desiredPresentTime = 0u;
if (m_prevDesiredPresentTime == 0)
{
// This must be the first present for this swapchain. Find out the
// current time, as the basis for desiredPresentTime:
if (curtimeNano != 0)
{
presentTime.desiredPresentTime = curtimeNano;
presentTime.desiredPresentTime += (m_targetIPD / 2);
}
else
{
// Since we didn't find out the current time, don't give a
// desiredPresentTime:
presentTime.desiredPresentTime = 0;
}
}
else
{
desiredPresentTime = m_prevDesiredPresentTime + m_targetIPD;
if ((presentTime.presentID == 80) && (m_swapchainConfig.presentMode != vk::VK_PRESENT_MODE_MAILBOX_KHR))
{
// Test if desiredPresentTime is 1 second earlier (i.e. before the previous image could have been presented)
presentTime.desiredPresentTime -= SECOND;
m_ExpectImage80Late = true;
}
}
m_prevDesiredPresentTime = desiredPresentTime;
const vk::VkPresentTimesInfoGOOGLE presentTimesInfo =
{
vk::VK_STRUCTURE_TYPE_PRESENT_TIMES_INFO_GOOGLE,
DE_NULL,
1u,
&presentTime
};
const vk::VkPresentInfoKHR presentInfo =
{
vk::VK_STRUCTURE_TYPE_PRESENT_INFO_KHR,
&presentTimesInfo,
1u,
&currentRenderSemaphore,
1u,
&*m_swapchain,
&imageIndex,
&result
};
VK_CHECK_WSI(m_vkd.queuePresentKHR(m_queue, &presentInfo));
VK_CHECK_WSI(result);
}
else
{
vk::VkResult result;
const vk::VkPresentInfoKHR presentInfo =
{
vk::VK_STRUCTURE_TYPE_PRESENT_INFO_KHR,
DE_NULL,
1u,
&currentRenderSemaphore,
1u,
&*m_swapchain,
&imageIndex,
&result
};
VK_CHECK_WSI(m_vkd.queuePresentKHR(m_queue, &presentInfo));
VK_CHECK_WSI(result);
}
{
m_freeAcquireSemaphore = m_acquireSemaphores[imageIndex];
m_acquireSemaphores[imageIndex] = currentAcquireSemaphore;
m_freeRenderSemaphore = m_renderSemaphores[imageIndex];
m_renderSemaphores[imageIndex] = currentRenderSemaphore;
}
}
tcu::TestStatus DisplayTimingTestInstance::iterate (void)
{
// Initialize swapchain specific resources
// Render test
try
{
if (m_frameNdx == 0)
{
if (m_outOfDateCount == 0)
m_context.getTestContext().getLog() << tcu::TestLog::Message << "Swapchain: " << m_swapchainConfig << tcu::TestLog::EndMessage;
initSwapchainResources();
}
render();
}
catch (const vk::Error& error)
{
if (error.getError() == vk::VK_ERROR_OUT_OF_DATE_KHR)
{
if (m_outOfDateCount < m_maxOutOfDateCount)
{
m_context.getTestContext().getLog() << TestLog::Message << "Frame " << m_frameNdx << ": Swapchain out of date. Recreating resources." << TestLog::EndMessage;
deinitSwapchainResources();
m_frameNdx = 0;
m_outOfDateCount++;
return tcu::TestStatus::incomplete();
}
else
{
m_context.getTestContext().getLog() << TestLog::Message << "Frame " << m_frameNdx << ": Swapchain out of date." << TestLog::EndMessage;
m_resultCollector.fail("Received too many VK_ERROR_OUT_OF_DATE_KHR errors. Received " + de::toString(m_outOfDateCount) + ", max " + de::toString(m_maxOutOfDateCount));
}
}
else
{
m_resultCollector.fail(error.what());
}
deinitSwapchainResources();
return tcu::TestStatus(m_resultCollector.getResult(), m_resultCollector.getMessage());
}
m_frameNdx++;
if (m_frameNdx >= m_frameCount)
{
deinitSwapchainResources();
return tcu::TestStatus(m_resultCollector.getResult(), m_resultCollector.getMessage());
}
else
return tcu::TestStatus::incomplete();
}
struct Programs
{
static void init (vk::SourceCollections& dst, TestConfig)
{
dst.glslSources.add("quad-vert") << glu::VertexSource(
"#version 450\n"
"out gl_PerVertex {\n"
"\tvec4 gl_Position;\n"
"};\n"
"highp float;\n"
"void main (void) {\n"
"\tgl_Position = vec4(((gl_VertexIndex + 2) / 3) % 2 == 0 ? -1.0 : 1.0,\n"
"\t ((gl_VertexIndex + 1) / 3) % 2 == 0 ? -1.0 : 1.0, 0.0, 1.0);\n"
"}\n");
dst.glslSources.add("quad-frag") << glu::FragmentSource(
"#version 310 es\n"
"layout(location = 0) out highp vec4 o_color;\n"
"layout(push_constant) uniform PushConstant {\n"
"\thighp uint frameNdx;\n"
"} pushConstants;\n"
"void main (void)\n"
"{\n"
"\thighp uint frameNdx = pushConstants.frameNdx;\n"
"\thighp uint x = frameNdx + uint(gl_FragCoord.x);\n"
"\thighp uint y = frameNdx + uint(gl_FragCoord.y);\n"
"\thighp uint r = 128u * bitfieldExtract(x, 0, 1)\n"
"\t + 64u * bitfieldExtract(y, 1, 1)\n"
"\t + 32u * bitfieldExtract(x, 3, 1);\n"
"\thighp uint g = 128u * bitfieldExtract(y, 0, 1)\n"
"\t + 64u * bitfieldExtract(x, 2, 1)\n"
"\t + 32u * bitfieldExtract(y, 3, 1);\n"
"\thighp uint b = 128u * bitfieldExtract(x, 1, 1)\n"
"\t + 64u * bitfieldExtract(y, 2, 1)\n"
"\t + 32u * bitfieldExtract(x, 4, 1);\n"
"\to_color = vec4(float(r) / 255.0, float(g) / 255.0, float(b) / 255.0, 1.0);\n"
"}\n");
}
};
} // anonymous
void createDisplayTimingTests (tcu::TestCaseGroup* testGroup, vk::wsi::Type wsiType)
{
const struct
{
vk::VkPresentModeKHR mode;
const char* name;
} presentModes[] =
{
{ vk::VK_PRESENT_MODE_FIFO_KHR, "fifo" },
{ vk::VK_PRESENT_MODE_FIFO_RELAXED_KHR, "fifo_relaxed" },
{ vk::VK_PRESENT_MODE_IMMEDIATE_KHR, "immediate" },
{ vk::VK_PRESENT_MODE_MAILBOX_KHR, "mailbox" },
};
for (size_t presentModeNdx = 0; presentModeNdx < DE_LENGTH_OF_ARRAY(presentModes); presentModeNdx++)
{
de::MovePtr<tcu::TestCaseGroup> presentModeGroup (new tcu::TestCaseGroup(testGroup->getTestContext(), presentModes[presentModeNdx].name, presentModes[presentModeNdx].name));
for (size_t ref = 0; ref < 2; ref++)
{
const bool isReference = (ref == 0);
const char* const name = isReference ? "reference" : "display_timing";
TestConfig config;
config.wsiType = wsiType;
config.useDisplayTiming = !isReference;
config.presentMode = presentModes[presentModeNdx].mode;
presentModeGroup->addChild(new vkt::InstanceFactory1<DisplayTimingTestInstance, TestConfig, Programs>(testGroup->getTestContext(), tcu::NODETYPE_SELF_VALIDATE, name, name, Programs(), config));
}
testGroup->addChild(presentModeGroup.release());
}
}
} // wsi
} // vkt