external/vulkancts/modules/vulkan/fragment_ops/vktFragmentOperationsScissorMultiViewportTests.cpp - third_party/vulkan-cts - Git at Google

 /*------------------------------------------------------------------------
  * Vulkan Conformance Tests
  * ------------------------
  *
  * Copyright (c) 2016 The Khronos Group Inc.
  * Copyright (c) 2014 The Android Open Source Project
  *
  * 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 Scissor multi viewport tests
  *//*--------------------------------------------------------------------*/

 #include "vktFragmentOperationsScissorMultiViewportTests.hpp"
 #include "vktTestCaseUtil.hpp"
 #include "vktFragmentOperationsMakeUtil.hpp"

 #include "vkDefs.hpp"
 #include "vkRefUtil.hpp"
 #include "vkTypeUtil.hpp"
 #include "vkMemUtil.hpp"
 #include "vkPrograms.hpp"
 #include "vkImageUtil.hpp"
 #include "vkQueryUtil.hpp"
 #include "vkCmdUtil.hpp"
 #include "vkObjUtil.hpp"

 #include "tcuTestLog.hpp"
 #include "tcuVector.hpp"
 #include "tcuImageCompare.hpp"
 #include "tcuTextureUtil.hpp"

 #include "deUniquePtr.hpp"
 #include "deMath.h"

 namespace vkt
 {
 namespace FragmentOperations
 {
 using namespace vk;
 using de::UniquePtr;
 using de::MovePtr;
 using tcu::Vec4;
 using tcu::Vec2;
 using tcu::IVec2;
 using tcu::IVec4;

 namespace
 {

 enum Constants
 {
 	MIN_MAX_VIEWPORTS = 16,		//!< Minimum number of viewports for an implementation supporting multiViewport.
 };

 template<typename T>
 inline VkDeviceSize sizeInBytes(const std::vector<T>& vec)
 {
 	return vec.size() * sizeof(vec[0]);
 }

 VkImageCreateInfo makeImageCreateInfo (const VkFormat format, const IVec2& size, VkImageUsageFlags usage)
 {
 	const VkImageCreateInfo imageParams =
 	{
 		VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO,			// VkStructureType			sType;
 		DE_NULL,										// const void*				pNext;
 		(VkImageCreateFlags)0,							// VkImageCreateFlags		flags;
 		VK_IMAGE_TYPE_2D,								// VkImageType				imageType;
 		format,											// VkFormat					format;
 		makeExtent3D(size.x(), size.y(), 1),			// VkExtent3D				extent;
 		1u,												// deUint32					mipLevels;
 		1u,												// deUint32					arrayLayers;
 		VK_SAMPLE_COUNT_1_BIT,							// VkSampleCountFlagBits	samples;
 		VK_IMAGE_TILING_OPTIMAL,						// VkImageTiling			tiling;
 		usage,											// VkImageUsageFlags		usage;
 		VK_SHARING_MODE_EXCLUSIVE,						// VkSharingMode			sharingMode;
 		0u,												// deUint32					queueFamilyIndexCount;
 		DE_NULL,										// const deUint32*			pQueueFamilyIndices;
 		VK_IMAGE_LAYOUT_UNDEFINED,						// VkImageLayout			initialLayout;
 	};
 	return imageParams;
 }

 Move<VkPipeline> makeGraphicsPipeline (const DeviceInterface&		vk,
 									   const VkDevice				device,
 									   const VkPipelineLayout		pipelineLayout,
 									   const VkRenderPass			renderPass,
 									   const VkShaderModule			vertexModule,
 									   const VkShaderModule			geometryModule,
 									   const VkShaderModule			fragmentModule,
 									   const IVec2					renderSize,
 									   const int					numViewports,
 									   const std::vector<IVec4>		scissors)
 {
 	const VkViewport defaultViewport = makeViewport(renderSize);
 	const std::vector<VkViewport> viewports(numViewports, defaultViewport);

 	DE_ASSERT(numViewports == static_cast<int>(scissors.size()));

 	std::vector<VkRect2D> rectScissors;
 	rectScissors.reserve(numViewports);

 	for (std::vector<IVec4>::const_iterator it = scissors.begin(); it != scissors.end(); ++it)
 	{
 		const VkRect2D rect =
 		{
 			makeOffset2D(it->x(), it->y()),
 			makeExtent2D(static_cast<deUint32>(it->z()), static_cast<deUint32>(it->w())),
 		};
 		rectScissors.push_back(rect);
 	}

 	return vk::makeGraphicsPipeline(vk,									// const DeviceInterface&            vk
 									device,								// const VkDevice                    device
 									pipelineLayout,						// const VkPipelineLayout            pipelineLayout
 									vertexModule,						// const VkShaderModule              vertexShaderModule
 									DE_NULL,							// const VkShaderModule              tessellationControlModule
 									DE_NULL,							// const VkShaderModule              tessellationEvalModule
 									geometryModule,						// const VkShaderModule              geometryShaderModule
 									fragmentModule,						// const VkShaderModule              fragmentShaderModule
 									renderPass,							// const VkRenderPass                renderPass
 									viewports,							// const std::vector<VkViewport>&    viewports
 									rectScissors,						// const std::vector<VkRect2D>&      scissors
 									VK_PRIMITIVE_TOPOLOGY_POINT_LIST);	// const VkPrimitiveTopology         topology
 }

 std::vector<IVec4> generateScissors (const int numScissors, const IVec2& renderSize)
 {
 	// Scissor rects will be arranged in a grid-like fashion.

 	const int numCols		= deCeilFloatToInt32(deFloatSqrt(static_cast<float>(numScissors)));
 	const int numRows		= deCeilFloatToInt32(static_cast<float>(numScissors) / static_cast<float>(numCols));
 	const int rectWidth		= renderSize.x() / numCols;
 	const int rectHeight	= renderSize.y() / numRows;

 	std::vector<IVec4> scissors;
 	scissors.reserve(numScissors);

 	int x = 0;
 	int y = 0;

 	for (int scissorNdx = 0; scissorNdx < numScissors; ++scissorNdx)
 	{
 		const bool nextRow = (scissorNdx != 0) && (scissorNdx % numCols == 0);
 		if (nextRow)
 		{
 			x  = 0;
 			y += rectHeight;
 		}

 		scissors.push_back(IVec4(x, y, rectWidth, rectHeight));

 		x += rectWidth;
 	}

 	return scissors;
 }

 std::vector<Vec4> generateColors (const int numColors)
 {
 	const Vec4 colors[] =
 	{
 		Vec4(0.18f, 0.42f, 0.17f, 1.0f),
 		Vec4(0.29f, 0.62f, 0.28f, 1.0f),
 		Vec4(0.59f, 0.84f, 0.44f, 1.0f),
 		Vec4(0.96f, 0.95f, 0.72f, 1.0f),
 		Vec4(0.94f, 0.55f, 0.39f, 1.0f),
 		Vec4(0.82f, 0.19f, 0.12f, 1.0f),
 		Vec4(0.46f, 0.15f, 0.26f, 1.0f),
 		Vec4(0.24f, 0.14f, 0.24f, 1.0f),
 		Vec4(0.49f, 0.31f, 0.26f, 1.0f),
 		Vec4(0.78f, 0.52f, 0.33f, 1.0f),
 		Vec4(0.94f, 0.82f, 0.31f, 1.0f),
 		Vec4(0.98f, 0.65f, 0.30f, 1.0f),
 		Vec4(0.22f, 0.65f, 0.53f, 1.0f),
 		Vec4(0.67f, 0.81f, 0.91f, 1.0f),
 		Vec4(0.43f, 0.44f, 0.75f, 1.0f),
 		Vec4(0.26f, 0.24f, 0.48f, 1.0f),
 	};

 	DE_ASSERT(numColors <= DE_LENGTH_OF_ARRAY(colors));

 	return std::vector<Vec4>(colors, colors + numColors);
 }

 //! Renders a colorful grid of rectangles.
 tcu::TextureLevel generateReferenceImage (const tcu::TextureFormat	format,
 										  const IVec2&				renderSize,
 										  const Vec4&				clearColor,
 										  const std::vector<IVec4>&	scissors,
 										  const std::vector<Vec4>&	scissorColors)
 {
 	DE_ASSERT(scissors.size() == scissorColors.size());

 	tcu::TextureLevel image(format, renderSize.x(), renderSize.y());
 	tcu::clear(image.getAccess(), clearColor);

 	for (std::size_t i = 0; i < scissors.size(); ++i)
 	{
 		tcu::clear(
 			tcu::getSubregion(image.getAccess(), scissors[i].x(), scissors[i].y(), scissors[i].z(), scissors[i].w()),
 			scissorColors[i]);
 	}

 	return image;
 }

 void initPrograms (SourceCollections& programCollection, const int numViewports)
 {
 	DE_UNREF(numViewports);

 	// Vertex shader
 	{
 		std::ostringstream src;
 		src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
 			<< "\n"
 			<< "layout(location = 0) in  vec4 in_color;\n"
 			<< "layout(location = 0) out vec4 out_color;\n"
 			<< "\n"
 			<< "void main(void)\n"
 			<< "{\n"
 			<< "    out_color = in_color;\n"
 			<< "}\n";

 		programCollection.glslSources.add("vert") << glu::VertexSource(src.str());
 	}

 	// Geometry shader
 	{
 		// Each input point generates a fullscreen quad.

 		std::ostringstream src;
 		src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
 			<< "\n"
 			<< "layout(points) in;\n"
 			<< "layout(triangle_strip, max_vertices=4) out;\n"
 			<< "\n"
 			<< "out gl_PerVertex {\n"
 			<< "    vec4 gl_Position;\n"
 			<< "};\n"
 			<< "\n"
 			<< "layout(location = 0) in  vec4 in_color[];\n"
 			<< "layout(location = 0) out vec4 out_color;\n"
 			<< "\n"
 			<< "void main(void)\n"
 			<< "{\n"
 			<< "    gl_ViewportIndex = gl_PrimitiveIDIn;\n"
 			<< "    gl_Position      = vec4(-1.0, -1.0, 0.0, 1.0);\n"
 			<< "    out_color        = in_color[0];\n"
 			<< "    EmitVertex();"
 			<< "\n"
 			<< "    gl_ViewportIndex = gl_PrimitiveIDIn;\n"
 			<< "    gl_Position      = vec4(-1.0, 1.0, 0.0, 1.0);\n"
 			<< "    out_color        = in_color[0];\n"
 			<< "    EmitVertex();"
 			<< "\n"
 			<< "    gl_ViewportIndex = gl_PrimitiveIDIn;\n"
 			<< "    gl_Position      = vec4(1.0, -1.0, 0.0, 1.0);\n"
 			<< "    out_color        = in_color[0];\n"
 			<< "    EmitVertex();"
 			<< "\n"
 			<< "    gl_ViewportIndex = gl_PrimitiveIDIn;\n"
 			<< "    gl_Position      = vec4(1.0, 1.0, 0.0, 1.0);\n"
 			<< "    out_color        = in_color[0];\n"
 			<< "    EmitVertex();"
 			<< "}\n";

 		programCollection.glslSources.add("geom") << glu::GeometrySource(src.str());
 	}

 	// Fragment shader
 	{
 		std::ostringstream src;
 		src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
 			<< "\n"
 			<< "layout(location = 0) in  vec4 in_color;\n"
 			<< "layout(location = 0) out vec4 out_color;\n"
 			<< "\n"
 			<< "void main(void)\n"
 			<< "{\n"
 			<< "    out_color = in_color;\n"
 			<< "}\n";

 		programCollection.glslSources.add("frag") << glu::FragmentSource(src.str());
 	}
 }

 class ScissorRenderer
 {
 public:
 	ScissorRenderer (Context&					context,
 					 const IVec2&				renderSize,
 					 const int					numViewports,
 					 const std::vector<IVec4>&	scissors,
 					 const VkFormat				colorFormat,
 					 const Vec4&				clearColor,
 					 const std::vector<Vec4>&	vertices)
 		: m_renderSize				(renderSize)
 		, m_colorFormat				(colorFormat)
 		, m_colorSubresourceRange	(makeImageSubresourceRange(VK_IMAGE_ASPECT_COLOR_BIT, 0u, 1u, 0u, 1u))
 		, m_clearColor				(clearColor)
 		, m_numViewports			(numViewports)
 		, m_vertexBufferSize		(sizeInBytes(vertices))
 	{
 		const DeviceInterface&		vk					= context.getDeviceInterface();
 		const VkDevice				device				= context.getDevice();
 		const deUint32				queueFamilyIndex	= context.getUniversalQueueFamilyIndex();
 		Allocator&					allocator			= context.getDefaultAllocator();

 		m_colorImage		= makeImage				(vk, device, makeImageCreateInfo(m_colorFormat, m_renderSize, VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT | VK_IMAGE_USAGE_TRANSFER_SRC_BIT));
 		m_colorImageAlloc	= bindImage				(vk, device, allocator, *m_colorImage, MemoryRequirement::Any);
 		m_colorAttachment	= makeImageView			(vk, device, *m_colorImage, VK_IMAGE_VIEW_TYPE_2D, m_colorFormat, m_colorSubresourceRange);

 		m_vertexBuffer		= makeBuffer			(vk, device, m_vertexBufferSize, VK_BUFFER_USAGE_VERTEX_BUFFER_BIT);
 		m_vertexBufferAlloc	= bindBuffer			(vk, device, allocator, *m_vertexBuffer, MemoryRequirement::HostVisible);

 		{
 			deMemcpy(m_vertexBufferAlloc->getHostPtr(), &vertices[0], static_cast<std::size_t>(m_vertexBufferSize));
 			flushAlloc(vk, device, *m_vertexBufferAlloc);
 		}

 		m_vertexModule		= createShaderModule	(vk, device, context.getBinaryCollection().get("vert"), 0u);
 		m_geometryModule	= createShaderModule	(vk, device, context.getBinaryCollection().get("geom"), 0u);
 		m_fragmentModule	= createShaderModule	(vk, device, context.getBinaryCollection().get("frag"), 0u);
 		m_renderPass		= makeRenderPass		(vk, device, m_colorFormat);
 		m_framebuffer		= makeFramebuffer		(vk, device, *m_renderPass, m_colorAttachment.get(),
 													 static_cast<deUint32>(m_renderSize.x()),  static_cast<deUint32>(m_renderSize.y()));
 		m_pipelineLayout	= makePipelineLayout	(vk, device);
 		m_pipeline			= makeGraphicsPipeline	(vk, device, *m_pipelineLayout, *m_renderPass, *m_vertexModule, *m_geometryModule, *m_fragmentModule,
 													 m_renderSize, m_numViewports, scissors);
 		m_cmdPool			= createCommandPool		(vk, device, VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT, queueFamilyIndex);
 		m_cmdBuffer			= allocateCommandBuffer	(vk, device, *m_cmdPool, VK_COMMAND_BUFFER_LEVEL_PRIMARY);
 	}

 	void draw (Context& context, const VkBuffer colorBuffer) const
 	{
 		const DeviceInterface&		vk			= context.getDeviceInterface();
 		const VkDevice				device		= context.getDevice();
 		const VkQueue				queue		= context.getUniversalQueue();

 		beginCommandBuffer(vk, *m_cmdBuffer);

 		beginRenderPass(vk, *m_cmdBuffer, *m_renderPass, *m_framebuffer, makeRect2D(0, 0, m_renderSize.x(), m_renderSize.y()), m_clearColor);

 		vk.cmdBindPipeline(*m_cmdBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, *m_pipeline);
 		{
 			const VkDeviceSize vertexBufferOffset = 0ull;
 			vk.cmdBindVertexBuffers(*m_cmdBuffer, 0u, 1u, &m_vertexBuffer.get(), &vertexBufferOffset);
 		}
 		vk.cmdDraw(*m_cmdBuffer, static_cast<deUint32>(m_numViewports), 1u, 0u, 0u);	// one vertex per viewport
 		endRenderPass(vk, *m_cmdBuffer);

 		copyImageToBuffer(vk, *m_cmdBuffer, *m_colorImage, colorBuffer, m_renderSize);

 		endCommandBuffer(vk, *m_cmdBuffer);
 		submitCommandsAndWait(vk, device, queue, *m_cmdBuffer);
 	}

 private:
 	const IVec2						m_renderSize;
 	const VkFormat					m_colorFormat;
 	const VkImageSubresourceRange	m_colorSubresourceRange;
 	const Vec4						m_clearColor;
 	const int						m_numViewports;
 	const VkDeviceSize				m_vertexBufferSize;

 	Move<VkImage>					m_colorImage;
 	MovePtr<Allocation>				m_colorImageAlloc;
 	Move<VkImageView>				m_colorAttachment;
 	Move<VkBuffer>					m_vertexBuffer;
 	MovePtr<Allocation>				m_vertexBufferAlloc;
 	Move<VkShaderModule>			m_vertexModule;
 	Move<VkShaderModule>			m_geometryModule;
 	Move<VkShaderModule>			m_fragmentModule;
 	Move<VkRenderPass>				m_renderPass;
 	Move<VkFramebuffer>				m_framebuffer;
 	Move<VkPipelineLayout>			m_pipelineLayout;
 	Move<VkPipeline>				m_pipeline;
 	Move<VkCommandPool>				m_cmdPool;
 	Move<VkCommandBuffer>			m_cmdBuffer;

 	// "deleted"
 						ScissorRenderer	(const ScissorRenderer&);
 	ScissorRenderer&	operator=		(const ScissorRenderer&);
 };

 tcu::TestStatus test (Context& context, const int numViewports)
 {
 	const DeviceInterface&			vk					= context.getDeviceInterface();
 	const VkDevice					device				= context.getDevice();
 	Allocator&						allocator			= context.getDefaultAllocator();

 	const IVec2						renderSize			(128, 128);
 	const VkFormat					colorFormat			= VK_FORMAT_R8G8B8A8_UNORM;
 	const Vec4						clearColor			(0.5f, 0.5f, 0.5f, 1.0f);
 	const std::vector<Vec4>			vertexColors		= generateColors(numViewports);
 	const std::vector<IVec4>		scissors			= generateScissors(numViewports, renderSize);

 	const VkDeviceSize				colorBufferSize		= renderSize.x() * renderSize.y() * tcu::getPixelSize(mapVkFormat(colorFormat));
 	const Unique<VkBuffer>			colorBuffer			(makeBuffer(vk, device, colorBufferSize, VK_BUFFER_USAGE_TRANSFER_DST_BIT));
 	const UniquePtr<Allocation>		colorBufferAlloc	(bindBuffer(vk, device, allocator, *colorBuffer, MemoryRequirement::HostVisible));

 	zeroBuffer(vk, device, *colorBufferAlloc, colorBufferSize);

 	{
 		context.getTestContext().getLog()
 			<< tcu::TestLog::Message << "Rendering a colorful grid of " << numViewports << " rectangle(s)." << tcu::TestLog::EndMessage
 			<< tcu::TestLog::Message << "Not covered area will be filled with a gray color." << tcu::TestLog::EndMessage;
 	}

 	// Draw
 	{
 		const ScissorRenderer renderer (context, renderSize, numViewports, scissors, colorFormat, clearColor, vertexColors);
 		renderer.draw(context, *colorBuffer);
 	}

 	// Log image
 	{
 		invalidateAlloc(vk, device, *colorBufferAlloc);

 		const tcu::ConstPixelBufferAccess	resultImage		(mapVkFormat(colorFormat), renderSize.x(), renderSize.y(), 1u, colorBufferAlloc->getHostPtr());
 		const tcu::TextureLevel				referenceImage	= generateReferenceImage(mapVkFormat(colorFormat), renderSize, clearColor, scissors, vertexColors);

 		// Images should now match.
 		if (!tcu::floatThresholdCompare(context.getTestContext().getLog(), "color", "Image compare", referenceImage.getAccess(), resultImage, Vec4(0.02f), tcu::COMPARE_LOG_RESULT))
 			return tcu::TestStatus::fail("Rendered image is not correct");
 	}

 	return tcu::TestStatus::pass("OK");
 }

 void checkSupport (Context& context, const int)
 {
 	context.requireDeviceCoreFeature(DEVICE_CORE_FEATURE_GEOMETRY_SHADER);
 	context.requireDeviceCoreFeature(DEVICE_CORE_FEATURE_MULTI_VIEWPORT);

 	if (context.getDeviceProperties().limits.maxViewports < MIN_MAX_VIEWPORTS)
 		TCU_THROW(NotSupportedError, "Implementation doesn't support minimum required number of viewports");
 }

 } // anonymous

 tcu::TestCaseGroup* createScissorMultiViewportTests	(tcu::TestContext& testCtx)
 {
 	MovePtr<tcu::TestCaseGroup> group (new tcu::TestCaseGroup(testCtx, "multi_viewport", ""));

 	for (int numViewports = 1; numViewports <= MIN_MAX_VIEWPORTS; ++numViewports)
 		addFunctionCaseWithPrograms(group.get(), "scissor_" + de::toString(numViewports), "", checkSupport, initPrograms, test, numViewports);

 	return group.release();
 }

 } // FragmentOperations
 } // vkt
	/*------------------------------------------------------------------------
	* Vulkan Conformance Tests
	* ------------------------
	*
	* Copyright (c) 2016 The Khronos Group Inc.
	* Copyright (c) 2014 The Android Open Source Project
	*
	* 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 Scissor multi viewport tests
	//--------------------------------------------------------------------*/

	#include "vktFragmentOperationsScissorMultiViewportTests.hpp"
	#include "vktTestCaseUtil.hpp"
	#include "vktFragmentOperationsMakeUtil.hpp"

	#include "vkDefs.hpp"
	#include "vkRefUtil.hpp"
	#include "vkTypeUtil.hpp"
	#include "vkMemUtil.hpp"
	#include "vkPrograms.hpp"
	#include "vkImageUtil.hpp"
	#include "vkQueryUtil.hpp"
	#include "vkCmdUtil.hpp"
	#include "vkObjUtil.hpp"

	#include "tcuTestLog.hpp"
	#include "tcuVector.hpp"
	#include "tcuImageCompare.hpp"
	#include "tcuTextureUtil.hpp"

	#include "deUniquePtr.hpp"
	#include "deMath.h"

	namespace vkt
	{
	namespace FragmentOperations
	{
	using namespace vk;
	using de::UniquePtr;
	using de::MovePtr;
	using tcu::Vec4;
	using tcu::Vec2;
	using tcu::IVec2;
	using tcu::IVec4;

	namespace
	{

	enum Constants
	{
	MIN_MAX_VIEWPORTS = 16, //!< Minimum number of viewports for an implementation supporting multiViewport.
	};

	template<typename T>
	inline VkDeviceSize sizeInBytes(const std::vector<T>& vec)
	{
	return vec.size() * sizeof(vec[0]);
	}

	VkImageCreateInfo makeImageCreateInfo (const VkFormat format, const IVec2& size, VkImageUsageFlags usage)
	{
	const VkImageCreateInfo imageParams =
	{
	VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO, // VkStructureType sType;
	DE_NULL, // const void* pNext;
	(VkImageCreateFlags)0, // VkImageCreateFlags flags;
	VK_IMAGE_TYPE_2D, // VkImageType imageType;
	format, // VkFormat format;
	makeExtent3D(size.x(), size.y(), 1), // VkExtent3D extent;
	1u, // deUint32 mipLevels;
	1u, // deUint32 arrayLayers;
	VK_SAMPLE_COUNT_1_BIT, // VkSampleCountFlagBits samples;
	VK_IMAGE_TILING_OPTIMAL, // VkImageTiling tiling;
	usage, // VkImageUsageFlags usage;
	VK_SHARING_MODE_EXCLUSIVE, // VkSharingMode sharingMode;
	0u, // deUint32 queueFamilyIndexCount;
	DE_NULL, // const deUint32* pQueueFamilyIndices;
	VK_IMAGE_LAYOUT_UNDEFINED, // VkImageLayout initialLayout;
	};
	return imageParams;
	}

	Move<VkPipeline> makeGraphicsPipeline (const DeviceInterface& vk,
	const VkDevice device,
	const VkPipelineLayout pipelineLayout,
	const VkRenderPass renderPass,
	const VkShaderModule vertexModule,
	const VkShaderModule geometryModule,
	const VkShaderModule fragmentModule,
	const IVec2 renderSize,
	const int numViewports,
	const std::vector<IVec4> scissors)
	{
	const VkViewport defaultViewport = makeViewport(renderSize);
	const std::vector<VkViewport> viewports(numViewports, defaultViewport);

	DE_ASSERT(numViewports == static_cast<int>(scissors.size()));

	std::vector<VkRect2D> rectScissors;
	rectScissors.reserve(numViewports);

	for (std::vector<IVec4>::const_iterator it = scissors.begin(); it != scissors.end(); ++it)
	{
	const VkRect2D rect =
	{
	makeOffset2D(it->x(), it->y()),
	makeExtent2D(static_cast<deUint32>(it->z()), static_cast<deUint32>(it->w())),
	};
	rectScissors.push_back(rect);
	}

	return vk::makeGraphicsPipeline(vk, // const DeviceInterface& vk
	device, // const VkDevice device
	pipelineLayout, // const VkPipelineLayout pipelineLayout
	vertexModule, // const VkShaderModule vertexShaderModule
	DE_NULL, // const VkShaderModule tessellationControlModule
	DE_NULL, // const VkShaderModule tessellationEvalModule
	geometryModule, // const VkShaderModule geometryShaderModule
	fragmentModule, // const VkShaderModule fragmentShaderModule
	renderPass, // const VkRenderPass renderPass
	viewports, // const std::vector<VkViewport>& viewports
	rectScissors, // const std::vector<VkRect2D>& scissors
	VK_PRIMITIVE_TOPOLOGY_POINT_LIST); // const VkPrimitiveTopology topology
	}

	std::vector<IVec4> generateScissors (const int numScissors, const IVec2& renderSize)
	{
	// Scissor rects will be arranged in a grid-like fashion.

	const int numCols = deCeilFloatToInt32(deFloatSqrt(static_cast<float>(numScissors)));
	const int numRows = deCeilFloatToInt32(static_cast<float>(numScissors) / static_cast<float>(numCols));
	const int rectWidth = renderSize.x() / numCols;
	const int rectHeight = renderSize.y() / numRows;

	std::vector<IVec4> scissors;
	scissors.reserve(numScissors);

	int x = 0;
	int y = 0;

	for (int scissorNdx = 0; scissorNdx < numScissors; ++scissorNdx)
	{
	const bool nextRow = (scissorNdx != 0) && (scissorNdx % numCols == 0);
	if (nextRow)
	{
	x = 0;
	y += rectHeight;
	}

	scissors.push_back(IVec4(x, y, rectWidth, rectHeight));

	x += rectWidth;
	}

	return scissors;
	}

	std::vector<Vec4> generateColors (const int numColors)
	{
	const Vec4 colors[] =
	{
	Vec4(0.18f, 0.42f, 0.17f, 1.0f),
	Vec4(0.29f, 0.62f, 0.28f, 1.0f),
	Vec4(0.59f, 0.84f, 0.44f, 1.0f),
	Vec4(0.96f, 0.95f, 0.72f, 1.0f),
	Vec4(0.94f, 0.55f, 0.39f, 1.0f),
	Vec4(0.82f, 0.19f, 0.12f, 1.0f),
	Vec4(0.46f, 0.15f, 0.26f, 1.0f),
	Vec4(0.24f, 0.14f, 0.24f, 1.0f),
	Vec4(0.49f, 0.31f, 0.26f, 1.0f),
	Vec4(0.78f, 0.52f, 0.33f, 1.0f),
	Vec4(0.94f, 0.82f, 0.31f, 1.0f),
	Vec4(0.98f, 0.65f, 0.30f, 1.0f),
	Vec4(0.22f, 0.65f, 0.53f, 1.0f),
	Vec4(0.67f, 0.81f, 0.91f, 1.0f),
	Vec4(0.43f, 0.44f, 0.75f, 1.0f),
	Vec4(0.26f, 0.24f, 0.48f, 1.0f),
	};

	DE_ASSERT(numColors <= DE_LENGTH_OF_ARRAY(colors));

	return std::vector<Vec4>(colors, colors + numColors);
	}

	//! Renders a colorful grid of rectangles.
	tcu::TextureLevel generateReferenceImage (const tcu::TextureFormat format,
	const IVec2& renderSize,
	const Vec4& clearColor,
	const std::vector<IVec4>& scissors,
	const std::vector<Vec4>& scissorColors)
	{
	DE_ASSERT(scissors.size() == scissorColors.size());

	tcu::TextureLevel image(format, renderSize.x(), renderSize.y());
	tcu::clear(image.getAccess(), clearColor);

	for (std::size_t i = 0; i < scissors.size(); ++i)
	{
	tcu::clear(
	tcu::getSubregion(image.getAccess(), scissors[i].x(), scissors[i].y(), scissors[i].z(), scissors[i].w()),
	scissorColors[i]);
	}

	return image;
	}

	void initPrograms (SourceCollections& programCollection, const int numViewports)
	{
	DE_UNREF(numViewports);

	// Vertex shader
	{
	std::ostringstream src;
	src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
	<< "\n"
	<< "layout(location = 0) in vec4 in_color;\n"
	<< "layout(location = 0) out vec4 out_color;\n"
	<< "\n"
	<< "void main(void)\n"
	<< "{\n"
	<< " out_color = in_color;\n"
	<< "}\n";

	programCollection.glslSources.add("vert") << glu::VertexSource(src.str());
	}

	// Geometry shader
	{
	// Each input point generates a fullscreen quad.

	std::ostringstream src;
	src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
	<< "\n"
	<< "layout(points) in;\n"
	<< "layout(triangle_strip, max_vertices=4) out;\n"
	<< "\n"
	<< "out gl_PerVertex {\n"
	<< " vec4 gl_Position;\n"
	<< "};\n"
	<< "\n"
	<< "layout(location = 0) in vec4 in_color[];\n"
	<< "layout(location = 0) out vec4 out_color;\n"
	<< "\n"
	<< "void main(void)\n"
	<< "{\n"
	<< " gl_ViewportIndex = gl_PrimitiveIDIn;\n"
	<< " gl_Position = vec4(-1.0, -1.0, 0.0, 1.0);\n"
	<< " out_color = in_color[0];\n"
	<< " EmitVertex();"
	<< "\n"
	<< " gl_ViewportIndex = gl_PrimitiveIDIn;\n"
	<< " gl_Position = vec4(-1.0, 1.0, 0.0, 1.0);\n"
	<< " out_color = in_color[0];\n"
	<< " EmitVertex();"
	<< "\n"
	<< " gl_ViewportIndex = gl_PrimitiveIDIn;\n"
	<< " gl_Position = vec4(1.0, -1.0, 0.0, 1.0);\n"
	<< " out_color = in_color[0];\n"
	<< " EmitVertex();"
	<< "\n"
	<< " gl_ViewportIndex = gl_PrimitiveIDIn;\n"
	<< " gl_Position = vec4(1.0, 1.0, 0.0, 1.0);\n"
	<< " out_color = in_color[0];\n"
	<< " EmitVertex();"
	<< "}\n";

	programCollection.glslSources.add("geom") << glu::GeometrySource(src.str());
	}

	// Fragment shader
	{
	std::ostringstream src;
	src << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << "\n"
	<< "\n"
	<< "layout(location = 0) in vec4 in_color;\n"
	<< "layout(location = 0) out vec4 out_color;\n"
	<< "\n"
	<< "void main(void)\n"
	<< "{\n"
	<< " out_color = in_color;\n"
	<< "}\n";

	programCollection.glslSources.add("frag") << glu::FragmentSource(src.str());
	}
	}

	class ScissorRenderer
	{
	public:
	ScissorRenderer (Context& context,
	const IVec2& renderSize,
	const int numViewports,
	const std::vector<IVec4>& scissors,
	const VkFormat colorFormat,
	const Vec4& clearColor,
	const std::vector<Vec4>& vertices)
	: m_renderSize (renderSize)
	, m_colorFormat (colorFormat)
	, m_colorSubresourceRange (makeImageSubresourceRange(VK_IMAGE_ASPECT_COLOR_BIT, 0u, 1u, 0u, 1u))
	, m_clearColor (clearColor)
	, m_numViewports (numViewports)
	, m_vertexBufferSize (sizeInBytes(vertices))
	{
	const DeviceInterface& vk = context.getDeviceInterface();
	const VkDevice device = context.getDevice();
	const deUint32 queueFamilyIndex = context.getUniversalQueueFamilyIndex();
	Allocator& allocator = context.getDefaultAllocator();

	m_colorImage = makeImage (vk, device, makeImageCreateInfo(m_colorFormat, m_renderSize, VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT \| VK_IMAGE_USAGE_TRANSFER_SRC_BIT));
	m_colorImageAlloc = bindImage (vk, device, allocator, *m_colorImage, MemoryRequirement::Any);
	m_colorAttachment = makeImageView (vk, device, *m_colorImage, VK_IMAGE_VIEW_TYPE_2D, m_colorFormat, m_colorSubresourceRange);

	m_vertexBuffer = makeBuffer (vk, device, m_vertexBufferSize, VK_BUFFER_USAGE_VERTEX_BUFFER_BIT);
	m_vertexBufferAlloc = bindBuffer (vk, device, allocator, *m_vertexBuffer, MemoryRequirement::HostVisible);

	{
	deMemcpy(m_vertexBufferAlloc->getHostPtr(), &vertices[0], static_cast<std::size_t>(m_vertexBufferSize));
	flushAlloc(vk, device, *m_vertexBufferAlloc);
	}

	m_vertexModule = createShaderModule (vk, device, context.getBinaryCollection().get("vert"), 0u);
	m_geometryModule = createShaderModule (vk, device, context.getBinaryCollection().get("geom"), 0u);
	m_fragmentModule = createShaderModule (vk, device, context.getBinaryCollection().get("frag"), 0u);
	m_renderPass = makeRenderPass (vk, device, m_colorFormat);
	m_framebuffer = makeFramebuffer (vk, device, *m_renderPass, m_colorAttachment.get(),
	static_cast<deUint32>(m_renderSize.x()), static_cast<deUint32>(m_renderSize.y()));
	m_pipelineLayout = makePipelineLayout (vk, device);
	m_pipeline = makeGraphicsPipeline (vk, device, m_pipelineLayout, m_renderPass, m_vertexModule, m_geometryModule, *m_fragmentModule,
	m_renderSize, m_numViewports, scissors);
	m_cmdPool = createCommandPool (vk, device, VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT, queueFamilyIndex);
	m_cmdBuffer = allocateCommandBuffer (vk, device, *m_cmdPool, VK_COMMAND_BUFFER_LEVEL_PRIMARY);
	}

	void draw (Context& context, const VkBuffer colorBuffer) const
	{
	const DeviceInterface& vk = context.getDeviceInterface();
	const VkDevice device = context.getDevice();
	const VkQueue queue = context.getUniversalQueue();

	beginCommandBuffer(vk, *m_cmdBuffer);

	beginRenderPass(vk, m_cmdBuffer, m_renderPass, *m_framebuffer, makeRect2D(0, 0, m_renderSize.x(), m_renderSize.y()), m_clearColor);

	vk.cmdBindPipeline(m_cmdBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, m_pipeline);
	{
	const VkDeviceSize vertexBufferOffset = 0ull;
	vk.cmdBindVertexBuffers(*m_cmdBuffer, 0u, 1u, &m_vertexBuffer.get(), &vertexBufferOffset);
	}
	vk.cmdDraw(*m_cmdBuffer, static_cast<deUint32>(m_numViewports), 1u, 0u, 0u); // one vertex per viewport
	endRenderPass(vk, *m_cmdBuffer);

	copyImageToBuffer(vk, m_cmdBuffer, m_colorImage, colorBuffer, m_renderSize);

	endCommandBuffer(vk, *m_cmdBuffer);
	submitCommandsAndWait(vk, device, queue, *m_cmdBuffer);
	}

	private:
	const IVec2 m_renderSize;
	const VkFormat m_colorFormat;
	const VkImageSubresourceRange m_colorSubresourceRange;
	const Vec4 m_clearColor;
	const int m_numViewports;
	const VkDeviceSize m_vertexBufferSize;

	Move<VkImage> m_colorImage;
	MovePtr<Allocation> m_colorImageAlloc;
	Move<VkImageView> m_colorAttachment;
	Move<VkBuffer> m_vertexBuffer;
	MovePtr<Allocation> m_vertexBufferAlloc;
	Move<VkShaderModule> m_vertexModule;
	Move<VkShaderModule> m_geometryModule;
	Move<VkShaderModule> m_fragmentModule;
	Move<VkRenderPass> m_renderPass;
	Move<VkFramebuffer> m_framebuffer;
	Move<VkPipelineLayout> m_pipelineLayout;
	Move<VkPipeline> m_pipeline;
	Move<VkCommandPool> m_cmdPool;
	Move<VkCommandBuffer> m_cmdBuffer;

	// "deleted"
	ScissorRenderer (const ScissorRenderer&);
	ScissorRenderer& operator= (const ScissorRenderer&);
	};

	tcu::TestStatus test (Context& context, const int numViewports)
	{
	const DeviceInterface& vk = context.getDeviceInterface();
	const VkDevice device = context.getDevice();
	Allocator& allocator = context.getDefaultAllocator();

	const IVec2 renderSize (128, 128);
	const VkFormat colorFormat = VK_FORMAT_R8G8B8A8_UNORM;
	const Vec4 clearColor (0.5f, 0.5f, 0.5f, 1.0f);
	const std::vector<Vec4> vertexColors = generateColors(numViewports);
	const std::vector<IVec4> scissors = generateScissors(numViewports, renderSize);

	const VkDeviceSize colorBufferSize = renderSize.x() * renderSize.y() * tcu::getPixelSize(mapVkFormat(colorFormat));
	const Unique<VkBuffer> colorBuffer (makeBuffer(vk, device, colorBufferSize, VK_BUFFER_USAGE_TRANSFER_DST_BIT));
	const UniquePtr<Allocation> colorBufferAlloc (bindBuffer(vk, device, allocator, *colorBuffer, MemoryRequirement::HostVisible));

	zeroBuffer(vk, device, *colorBufferAlloc, colorBufferSize);

	{
	context.getTestContext().getLog()
	<< tcu::TestLog::Message << "Rendering a colorful grid of " << numViewports << " rectangle(s)." << tcu::TestLog::EndMessage
	<< tcu::TestLog::Message << "Not covered area will be filled with a gray color." << tcu::TestLog::EndMessage;
	}

	// Draw
	{
	const ScissorRenderer renderer (context, renderSize, numViewports, scissors, colorFormat, clearColor, vertexColors);
	renderer.draw(context, *colorBuffer);
	}

	// Log image
	{
	invalidateAlloc(vk, device, *colorBufferAlloc);

	const tcu::ConstPixelBufferAccess resultImage (mapVkFormat(colorFormat), renderSize.x(), renderSize.y(), 1u, colorBufferAlloc->getHostPtr());
	const tcu::TextureLevel referenceImage = generateReferenceImage(mapVkFormat(colorFormat), renderSize, clearColor, scissors, vertexColors);

	// Images should now match.
	if (!tcu::floatThresholdCompare(context.getTestContext().getLog(), "color", "Image compare", referenceImage.getAccess(), resultImage, Vec4(0.02f), tcu::COMPARE_LOG_RESULT))
	return tcu::TestStatus::fail("Rendered image is not correct");
	}

	return tcu::TestStatus::pass("OK");
	}

	void checkSupport (Context& context, const int)
	{
	context.requireDeviceCoreFeature(DEVICE_CORE_FEATURE_GEOMETRY_SHADER);
	context.requireDeviceCoreFeature(DEVICE_CORE_FEATURE_MULTI_VIEWPORT);

	if (context.getDeviceProperties().limits.maxViewports < MIN_MAX_VIEWPORTS)
	TCU_THROW(NotSupportedError, "Implementation doesn't support minimum required number of viewports");
	}

	} // anonymous

	tcu::TestCaseGroup* createScissorMultiViewportTests (tcu::TestContext& testCtx)
	{
	MovePtr<tcu::TestCaseGroup> group (new tcu::TestCaseGroup(testCtx, "multi_viewport", ""));

	for (int numViewports = 1; numViewports <= MIN_MAX_VIEWPORTS; ++numViewports)
	addFunctionCaseWithPrograms(group.get(), "scissor_" + de::toString(numViewports), "", checkSupport, initPrograms, test, numViewports);

	return group.release();
	}

	} // FragmentOperations
	} // vkt